What is the proper workup of a patient with hypertension?

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What is the proper workup of a patient with hypertension?
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Radhika Katakam, MD
Kirsten Brukamp, MD
Raymond R. Townsend, MD

How extensive a workup does a patient with high blood pressure need?

On one hand, we would not want to start therapy on the basis of a single elevated reading, as blood pressure fluctuates considerably during the day, and even experienced physicians often make errors in taking blood pressure that tend to falsely elevate the patient’s readings. Similarly, we would not want to miss the diagnosis of a potentially curable cause of hypertension or of a condition that increases a patient’s risk of cardiovascular disease. But considering that nearly one-third of adults in the United States have hypertension and that another one-fourth have prehypertension (formerly called high-normal blood pressure),1 if we were to launch an intensive workup for every patient with high blood pressure, the cost and effort would be enormous.

Fortunately, for most patients, it is enough to measure blood pressure accurately and repeatedly, perform a focused history and physical examination, and obtain the results of a few basic laboratory tests and an electrocardiogram, with additional tests in special cases.

In this review we address four fundamental questions in the evaluation of patients with a high blood pressure reading, and how to answer them.

ANSWERING FOUR QUESTIONS

The goal of the hypertension evaluation is to answer four questions:

  • Does the patient have sustained hypertension? And if so—
  • Is the hypertension primary or secondary?
  • Does the patient have other cardiovascular risk factors?
  • Does he or she have evidence of target organ damage?

DOES THE PATIENT HAVE SUSTAINED HYPERTENSION?

It is important to measure blood pressure accurately, for several reasons. A diagnosis of hypertension has a measurable impact on the patient’s quality of life.2 Furthermore, we want to avoid undertaking a full evaluation of hypertension if the patient doesn’t actually have high blood pressure, ie, systolic blood pressure greater than 140 mm Hg or diastolic pressure greater than 90 mm Hg. However, many people have blood pressures in the prehypertensive range (ie, 120–139 mm Hg systolic; 80–89 mm Hg diastolic). Many people in this latter group can expect to develop hypertension in time, as the prevalence of hypertension increases steadily with age unless effective preventive measures are implemented, such as losing weight, exercising regularly, and avoiding excessive consumption of sodium and alcohol.

The steps involved in taking blood pressure are simple (Table 1)3,4 but often are not followed in busy clinical practices, and the job is frequently relegated to the least-well-trained staff in the office. The most common errors (failure to have the patient sit quietly for 5 minutes before a reading is taken, lack of arm or foot support, using too small a cuff relative to the size of the arm, deflating the cuff too rapidly) tend to falsely elevate the readings, leading to an overestimate of blood pressure. To reduce the variability commonly noted in staff-obtained manual blood pressure, some office practices use an automated system such as the BpTRU.5

The best position to use is sitting, as the Framingham Heart Study and most randomized clinical trials that established the value of treating hypertension used this position for diagnosis and follow-up.6

Proper patient positioning, the correct cuff size, calibrated equipment, and good inflation and deflation technique will yield the best assessment of blood pressure levels. But even if your technique is perfect, blood pressure is a dynamic vital sign, so it is necessary to repeat the measurement, average the values for any particular day, and keep in mind that the pressure is higher (or lower) on some days than on others, so that the running average is more important than individual readings. This leads to two final points about blood pressure measurement:

  • Take it right, at least two times on any occasion
  • Take it on at least two (preferably three) separate days.

Following up on blood pressure

After measuring the blood pressure, it is necessary to plan for follow-up readings, guided by both the blood pressure levels (Table 2) and your clinical judgment.

If the systolic and diastolic blood pressures fall into different categories, you should follow the recommendations for the shorter follow-up time.

 

 

IS THE HYPERTENSION PRIMARY OR SECONDARY?

Most patients with hypertension have primary (“essential”) hypertension and are likely to remain hypertensive for life. However, some have secondary hypertension, ie, high blood pressure due to an identifiable cause. Some of these conditions (and the hypertension that they cause) can be cured. For example, pheochromocytoma can be cured if found and removed. Other causes of secondary hypertension, such as parenchymal renal disease, are infrequently cured, and the goal is usually to control the blood pressure with drugs.

The sudden onset of severe hypertension in a patient previously known to have had normal blood pressure raises the suspicion of a secondary form of hypertension, as does the onset of hypertension in a young person (< 25 years) or an older person (> 55 years). However, these ages are arbitrary; with the increasing body mass index in young people, essential hypertension is now more commonly diagnosed in the third decade. And since systolic pressure increases throughout life, we can expect many older patients to develop essential hypertension.7 Indeed, current guidelines are urging us to pay more attention to systolic pressure than in the past.

WHAT IS THE PATIENT’S CARDIOVASCULAR RISK?

The relationship between blood pressure and risk of cardiovascular disease is linear, continuous, and independent of (though additive to) other risk factors.1 For people 40 to 70 years old, each increment of either 20 mm Hg in systolic blood pressure or 10 mm Hg in diastolic blood pressure doubles the risk of cardiovascular disease across the entire range from 115/75 to 185/115 mm Hg.1 If the patient smokes or has elevated cholesterol, other cardiovascular risk factors, or the metabolic syndrome, the risk is even higher.8

The usual goal of antihypertensive treatment is systolic pressure less than 140 mm Hg and diastolic pressure less than 90 mm Hg. However, the target is lower—less than 130/80 mm Hg—for those with diabetes9 or target organ damage such as heart failure or renal disease.1,10 Thus, it is important to try to detect these conditions in the evaluation of the hypertensive patient.

Another reason it is important is that reducing such risk sometimes calls for using (or avoiding) antihypertensive drugs that are likely to alter these factors. For example, the use of beta-blockers in patients with a low level of high-density lipoprotein cholesterol (HDL-C) can lower HDL-C further.11

DOES THE PATIENT HAVE TARGET ORGAN DAMAGE?

Target organ damage is very important to detect because it changes the goal of treatment from primary prevention of adverse target organ outcomes into the more challenging realm of secondary prevention. For example, if a patient has had a stroke, his or her chance of having another stroke in the next 5 years is about 20%. This is much higher than the risk in an average hypertensive patient without such a history. For such patients, the current guidelines1 recommend the combination of a diuretic and an angiotensin-converting enzyme inhibitor, a combination shown to reduce the risk of a second stroke.12 Thus, we need to discover whether the patient had a stroke in the first place.

HISTORY

The history (Table 3) helps elucidate whether hypertension is primary or secondary, the degree of cardiovascular risk, and whether target organ damage is present. One should try to ascertain:

  • The duration (if known) and severity of the hypertension
  • The degree of blood pressure fluctuation
  • Concomitant medical conditions, especially cardiovascular or renal problems
  • Dietary habits
  • Alcohol consumption
  • Tobacco use
  • Level of physical activity
  • A family history of hypertension, renal disease, cardiovascular problems, or diabetes mellitus
  • Past medications, with particular attention to their side effects and their efficacy in controlling blood pressure
  • Current medications, including over-the-counter preparations. One reason: non-steroidal anti-inflammatory drugs other than aspirin can decrease the efficacy of antihypertensive drugs, presumably through mechanisms that inhibit the effects of vasodilatory and natriuretic prostaglandins and potentiate those of angiotensin II.13
 

 

PHYSICAL EXAMINATION

The physical examination, like the history, give clues about secondary hypertension, cardiovascular risk, and target organ damage (Table 4).

The physical examination starts with measurement of height, weight, waist circumference, and blood pressure—in both arms and the leg if coarctation of the aorta is suspected. Measurements with the patient supine, sitting, and standing are usually taken at the first visit, though such an approach is more suited to a hypertension specialty clinic than a primary care setting, in which time constraints usually limit the blood pressure readings to two or three seated values. Most prospective data on the benefits of hypertension treatment are based on a seated blood pressure, so we favor that measurement for follow-up.

Special attention in the physical examination is directed to:

The retina (to assess the vascular impact of the high blood pressure). Look for arteriolar narrowing (grade 1), arteriovenous compression (grade 2), hemorrhages or exudates (grade 3), and papilledema.2 Such findings not only relate to severity (higher grade = more severe blood pressure) but also predict future cardiovascular disease.14

The blood vessels. Bruits in the neck may indicate carotid stenosis, bruits in the abdomen may indicate renovascular disease, and femoral bruits are a sign of general atherosclerosis. Bruits also signal vascular stenosis and irregularity and may be a clue to vascular damage or future loss of target organ function. However, bruits may simply result from vascular tortuosity, particularly with significant flow in the vessel.

Also check the femoral pulses: poor or delayed femoral pulses are a sign of aortic coarctation. The radial artery is about as far away from the heart as the femoral artery; consequently, when palpating both sites simultaneously the pulse should arrive at about the same moment. In aortic coarctation, a palpable delay in the arrival of the femoral pulse may occur, and an interscapular murmur may be heard during auscultation of the back. In these instances, a low leg blood pressure (usually measured by placing a thigh-sized adult cuff on the patient’s thigh and listening over the popliteal area with the patient prone) may confirm the presence of aortic obstruction. When taking a leg blood pressure, the large cuff and the amount of pressure necessary to occlude the artery may be uncomfortable, and one should warn the patient about the discomfort before taking the measurement.

Poor or absent pedal pulses are a sign of peripheral arterial disease.

The heart (to detect gallops, enlargement, or both). Palpation may reveal a displaced apical impulse, which can indicate left ventricular enlargement. A sustained apical impulse may indicate left ventricular hypertrophy. Listen for a fourth heart sound (S4), one of the earliest physical findings of hypertension when physical findings are present. An S4 indicates that the left atrium is working hard to overcome the stiffness of the left ventricle. An S3 indicates an impairment in left ventricular function and is usually a harbinger of underlying heart disease. In some cases, lung rales can also be heard, though the combination of an S3 gallop and rales is an unusual office presentation in the early management of the hypertensive patient.

The lungs. Listen for rales (see above).

The lower extremities should be examined for peripheral arterial pulsations and edema. The loss of pedal pulses is a common finding, particularly in smokers, and is a clue to increased cardiovascular risk.

Strength, gait, and cognition. Perform a brief neurologic examination for evidence of remote stroke. We usually observe our patients’ gait as they enter or leave the examination room, test their bilateral grip strength, and assess their judgment, speech, and memory during the history and physical examination.

A great deal of research has linked high blood pressure to future loss of cognitive function,15 and it is useful to know that impairment is present before beginning treatment, since some patients will complain of memory loss after starting antihypertensive drug treatment.

LABORATORY EVALUATION

Routine tests

The routine evaluation of hypertensive patients should include, at a minimum:

  • A hemoglobin or hematocrit measurement
  • Urinalysis with microscopic examination
  • Serum electrolyte concentrations
  • Serum creatinine concentrations
  • Serum glucose concentration
  • A fasting lipid profile
  • A 12-lead electrocardiogram (Table 5).

Nonroutine tests

In some cases, other studies may be appropriate, depending on the clinical situation, eg:

  • Serum uric acid in those with a history of gout, since some antihypertensive drugs (eg, diuretics) may increase serum uric acid and predispose to further episodes of gout
  • Serum calcium in those with a personal or family history of kidney stones, to detect subtle parathyroid excess
  • Thyroid-stimulating hormone or other thyroid studies if the history suggests thyroid excess, or if a thyroid nodule is discovered
  • Limited echocardiography, which is more sensitive than electrocardiography for detecting left ventricular hypertrophy.

We sometimes use echocardiography if the patient is overweight but seems motivated to lose weight. In these cases we might not start drug therapy right away, choosing rather to wait and see if the patient can lose some weight (which might lower the blood pressure and make drug therapy unnecessary)—but only if the echocardiogram shows that he or she does not have left ventricular hypertrophy.

We also use echocardiography in patients with white-coat hypertension (see below), in whom office pressures are consistently high but whom we have elected to either not treat or not alter treatment. In these cases the echocardiogram serves as a “second opinion” about the merits of not altering therapy and supports this decision when the left ventricular wall thicknesses are normal (and remain so during long-term follow-up). In cases of suspected white-coat hypertension, home or ambulatory blood pressure monitoring is valuable to establish or exclude this diagnosis.1

Urinary albumin excretion. Microalbuminuria is an early manifestation of diabetic nephropathy and hypertension. Although routine urine screening for microalbuminuria is typically done in the management of diabetes, it is still not considered a standard of care, though the growing literature on its role as a cardiovascular risk predictor16–18 and its value as a therapeutic target in diabetes19,20 make it an attractive aid in the overall assessment of patients with hypertension.

Plasma renin activity and serum aldosterone concentrations are useful in screening for aldosterone excess, but are usually reserved as follow-up tests in patients with either hypokalemia or failure to achieve blood pressure control on a three-drug regimen in which at least one drug is a diuretic.1,21

Of note, primary aldosteronism is not as rare as previously thought. In a study of patients referred to hypertension centers, 11% had primary aldosteronism according to prospective diagnostic criteria, almost 5% had curable aldosterone-producing adenomas, and 6% had idiopathic hyperaldosteronism.22

 

 

If secondary hypertension is suspected

Sometimes the history, examination, or initial testing leads one to suspect that a secondary form of hypertension may be present. Table 6 lists some of the common ways to pursue such suspicions. Readers are referred to several excellent reviews of secondary hypertension for further details.23–25

A search for secondary forms of hypertension is usually considered in patients with moderate or severe hypertension that does not respond to antihypertensive agents. Another situation is in hypertensive patients younger than 25 years, since curable forms of hypertension are more common in this age group. In older patients, the prevalence of secondary hypertension is lower and does not justify the costs and effort of routine elaborate workups unless there is evidence from the history, physical examination, or routine laboratory work for suspecting its presence. An exception to this rule is the need to exclude atherosclerotic renovascular hypertension in an elderly patient. This cause of secondary hypertension is common in the elderly and may be amenable to therapeutic intervention.26

WHEN TO CONSIDER HOME OR AMBULATORY MONITORING

Most patients with hypertension do not need ambulatory blood pressure monitoring, but in selected cases (Table 7), it may help in clinical management. However, Medicare and Medicaid pay for it only for the specific indication of white-coat hypertension. Readers are referred to a recent excellent review for further information.27

Suspected white-coat hypertension

Blood pressure can be influenced by an environment such as an office or hospital clinic. This has led to the development of ambulatory blood pressure monitors and more use of self-measurement of blood pressure in the home. Blood pressure readings with these techniques are generally lower than those measured in an office or hospital clinic. These methods make it possible to screen for white-coat hypertension. In 10% to 20% of people with hypertensive readings, the blood pressure may be elevated persistently only in the presence of a physician.28 When measured elsewhere, including at work, the blood pressure is not elevated in those with the white-coat effect. Although this response may become less prominent with repeated measurements, it occasionally persists in the office setting, sometimes for years in our experience.

Suspected nocturnal hypertension (’nondipping’ status)

Ambulatory blood pressure is also helpful to screen for nocturnal hypertension. Evidence is accumulating to suggest that hypertensive patients whose pressure remains relatively high at night (“nondippers,” ie, those with less than a 10% reduction at night compared with daytime blood pressure readings) are at greater risk of cardiovascular morbidity than “dippers” (those whose blood pressure is at least 10% lower at night than during the day).29

An early morning surge

Ambulatory monitoring can also detect morning surges in systolic blood pressure,30 a marker of cerebrovascular risk. Generally, these patients have an increase of more than 55 mm Hg in systolic pressure between their sleeping and early-hour waking values, and we may wish to start or alter treatment specifically to address these high morning systolic values.31

‘PIPESTEM’ VESSELS AND PSEUDOHYPERTENSION

Occasionally, one encounters patients with vessels that are stiff and difficult to compress. If the pressure required to compress the brachial artery and stop audible blood flow with a standard blood pressure cuff is greater than the actual blood pressure within the artery as measured invasively, the condition is called pseudohypertension. The stiffness is thought to be due to calcification of the arterial wall.

A way to check for this condition is to inflate the cuff to at least 30 mm Hg above the palpable systolic pressure and then try to “roll” the brachial or radial artery underneath your fingertips, a procedure known as Osler’s maneuver.32 If you feel something that resembles a stiff tube reminiscent of the stem of a tobacco smoker’s pipe (healthy arteries are not palpable when empty), the patient may have pseudohypertension. However, the specificity of Osler’s maneuver has been questioned, particularly in hospitalized elderly patients.33

Pseudohypertension is important because the patients in whom it occurs, usually the elderly or the chronically ill (with diabetes or chronic kidney disease), are prone to orthostatic or postural hypotension, which may be aggravated by increasing their antihypertensive treatment on the basis of a cuff pressure that is actually much higher than the real blood pressure.33

References
  1. Chobanian AV, Bakris GL, Black HR, et al. Seventh report of the Joint National Committee on Prevention, Detection, Evaluation, and Treatment of High Blood Pressure. Hypertension 2003; 42:12061252.
  2. Wenger NK. Quality of life issues in hypertension: consequences of diagnosis and considerations in management. Am Heart J 1988; 116:628632.
  3. McFadden CB, Townsend RR. Blood pressure measurement: common pitfalls and how to avoid them. Consultant 2003; 43:161165.
  4. Pickering TG, Hall JE, Appel LJ, et al. Recommendations for blood pressure measurement in humans and experimental animals: part 1: blood pressure measurement in humans: a statement for professionals from the Subcommittee of Professional and Public Education of the American Heart Association Council on High Blood Pressure Research. Circulation 2005; 111:697716.
  5. Myers MG. Automated blood pressure measurement in routine clinical practice. Blood Press Monit 2006; 11:5962.
  6. Mosenkis A, Townsend RR. Sitting on the evidence: what is the proper patient position for the office measurement of blood pressure? J Clin Hypertens (Greenwich) 2005; 7:365366.
  7. Vasan RS, Beiser A, Seshadri S, et al. Residual lifetime risk for developing hypertension in middle-aged women and men: The Framingham Heart Study. JAMA 2002; 287:10031010.
  8. Grundy SM, Cleeman JI, Merz CN, et al. Implications of recent clinical trials for the National Cholesterol Education Program Adult Treatment Panel III Guidelines. J Am Coll Cardiol 2004; 44:720732.
  9. American Diabetes Association. Treatment of hypertension in adults with diabetes. Diabetes Care 2002; 25:199201.
  10. Rosendorff C, Black HR, Cannon CP, et al. Treatment of hypertension in the prevention and management of ischemic heart disease: a scientific statement from the American Heart Association Council for High Blood Pressure Research and the Councils on Clinical Cardiology and Epidemiology and Prevention. Circulation 2007; 115:27612788.
  11. Papadakis JA, Mikhailidis DP, Vrentzos GE, Kalikaki A, Kazakou I, Ganotakis ES. Effect of antihypertensive treatment on plasma fibrinogen and serum HDL levels in patients with essential hypertension. Clin Appl Thromb Hemost 2005; 11:139146.
  12. PROGRESS Collaborative Group. Randomised trial of a perindopril-based blood-pressure-lowering regimen among 6,105 individuals with previous stroke or transient ischaemic attack. Lancet 2001; 358:10331041.
  13. Fierro-Carrion GA, Ram CV. Nonsteroidal anti-inflammatory drugs (NSAIDs) and blood pressure. Am J Cardiol 1997; 80:775776.
  14. Wong TY, McIntosh R. Hypertensive retinopathy signs as risk indicators of cardiovascular morbidity and mortality. Br Med Bull 2005; 73–74:5770.
  15. Forette F, Boller F. Hypertension and the risk of dementia in the elderly. Am J Med 1991; 90:14S19S.
  16. Schrader J, Luders S, Kulschewski A, et al. Microalbuminuria and tubular proteinuria as risk predictors of cardiovascular morbidity and mortality in essential hypertension: final results of a prospective long-term study (MARPLE Study). J Hypertens 2006; 24:541548.
  17. Luque M, de Rivas B, Alvarez B, Garcia G, Fernandez C, Martell N. Influence of target organ lesion detection (assessment of microalbuminuria and echocardiogram) in cardiovascular risk stratification and treatment of untreated hypertensive patients. J Hum Hypertens 2006; 20:187192.
  18. Pontremoli R, Leoncini G, Viazzi F, et al. Role of microalbuminuria in the assessment of cardiovascular risk in essential hypertension. J Am Soc Nephrol 2005; 16 suppl 1:S39S41.
  19. Erdmann E. Microalbuminuria as a marker of cardiovascular risk in patients with type 2 diabetes. Int J Cardiol 2006; 107:147153.
  20. Bakris GL, Sowers JR. Microalbuminuria in diabetes: focus on cardiovascular and renal risk reduction. Curr Diab Rep 2002; 2:258262.
  21. Gallay BJ, Ahmad S, Xu L, Toivola B, Davidson RC. Screening for primary aldosteronism without discontinuing hypertensive medications: plasma aldosteronerenin ratio. Am J Kidney Dis 2001; 37:699705.
  22. Rossi GP, Bernini G, Caliumi C, et al. A prospective study of the prevalence of primary aldosteronism in 1,125 hypertensive patients. J Am Coll Cardiol 2006; 48:22932300.
  23. Onusko E. Diagnosing secondary hypertension. Am Fam Physician 2003; 67:6774.
  24. Aurell M. Screening for secondary hypertension. Curr Hypertens Rep 1999; 1:461.
  25. Garovic VD, Kane GC, Schwartz GL. Renovascular hypertension: balancing the controversies in diagnosis and treatment. Cleve Clin J Med 2005; 72:11351137.
  26. Textor SC. Renovascular hypertension in 2007: where are we now? Curr Cardiol Rep 2007; 9:453461.
  27. Pickering TG, Shimbo D, Haas D. Ambulatory blood-pressure monitoring. N Engl J Med 2006; 354:23682374.
  28. Angeli F, Verdecchia P, Gattobigio R, Sardone M, Reboldi G. White-coat hypertension in adults. Blood Press Monit 2005; 10:301305.
  29. Cicconetti P, Morelli S, De Serra C, et al. Left ventricular mass in dippers and nondippers with newly diagnosed hypertension. Angiology 2003; 54:661669.
  30. Kario K, Pickering TG, Umeda Y, et al. Morning surge in blood pressure as a predictor of silent and clinical cerebrovascular disease in elderly hypertensives: a prospective study. Circulation 2003; 107:14011406.
  31. Katakam R, Townsend RR. Morning surges in blood pressure. J Clin Hypertens 2006; 8:450451.
  32. Messerli FH. Osler’s maneuver, pseudohypertension, and true hypertension in the elderly. Am J Med 1986; 80:906910.
  33. Belmin J, Visintin JM, Salvatore R, Sebban C, Moulias R. Osler’s maneuver: absence of usefulness for the detection of pseudohypertension in an elderly population. Am J Med 1995; 98:4249.
  34. Messerli FH, Ventura HO, Amodeo C. Osler’s maneuver and pseudohypertension. N Engl J Med 1985; 312:15481551.
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Radhika Katakam, MD
Instructor in Medicine, Henry Ford, Health System, Detroit, MI

Kirsten Brukamp, MD
University of Pennsylvania, Philadelphia

Raymond R. Townsend, MD
Renal Electrolyte and Hypertension Division, University of Pennsylvania, Philadelphia

Address: Raymond R. Townsend, MD, Department of Medicine, 122 Founders Building, University of Pennsylvania, 3400 Spruce Street, Philadelphia, PA 19104; e-mail [email protected]

Dr. Townsend has disclosed that he has received grant support from Novartis and the National Institutes of Health; consultant fees from GlaxoSmithKline, NiCox, and Pfizer; and honoraria from BMS and Merck.

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Cleveland Clinic Journal of Medicine - 75(9)
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Nephrology
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Author(s)
Radhika Katakam, MD
Kirsten Brukamp, MD
Raymond R. Townsend, MD
Author(s)
Radhika Katakam, MD
Kirsten Brukamp, MD
Raymond R. Townsend, MD
Author and Disclosure Information

Radhika Katakam, MD
Instructor in Medicine, Henry Ford, Health System, Detroit, MI

Kirsten Brukamp, MD
University of Pennsylvania, Philadelphia

Raymond R. Townsend, MD
Renal Electrolyte and Hypertension Division, University of Pennsylvania, Philadelphia

Address: Raymond R. Townsend, MD, Department of Medicine, 122 Founders Building, University of Pennsylvania, 3400 Spruce Street, Philadelphia, PA 19104; e-mail [email protected]

Dr. Townsend has disclosed that he has received grant support from Novartis and the National Institutes of Health; consultant fees from GlaxoSmithKline, NiCox, and Pfizer; and honoraria from BMS and Merck.

Author and Disclosure Information

Radhika Katakam, MD
Instructor in Medicine, Henry Ford, Health System, Detroit, MI

Kirsten Brukamp, MD
University of Pennsylvania, Philadelphia

Raymond R. Townsend, MD
Renal Electrolyte and Hypertension Division, University of Pennsylvania, Philadelphia

Address: Raymond R. Townsend, MD, Department of Medicine, 122 Founders Building, University of Pennsylvania, 3400 Spruce Street, Philadelphia, PA 19104; e-mail [email protected]

Dr. Townsend has disclosed that he has received grant support from Novartis and the National Institutes of Health; consultant fees from GlaxoSmithKline, NiCox, and Pfizer; and honoraria from BMS and Merck.

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How extensive a workup does a patient with high blood pressure need?

On one hand, we would not want to start therapy on the basis of a single elevated reading, as blood pressure fluctuates considerably during the day, and even experienced physicians often make errors in taking blood pressure that tend to falsely elevate the patient’s readings. Similarly, we would not want to miss the diagnosis of a potentially curable cause of hypertension or of a condition that increases a patient’s risk of cardiovascular disease. But considering that nearly one-third of adults in the United States have hypertension and that another one-fourth have prehypertension (formerly called high-normal blood pressure),1 if we were to launch an intensive workup for every patient with high blood pressure, the cost and effort would be enormous.

Fortunately, for most patients, it is enough to measure blood pressure accurately and repeatedly, perform a focused history and physical examination, and obtain the results of a few basic laboratory tests and an electrocardiogram, with additional tests in special cases.

In this review we address four fundamental questions in the evaluation of patients with a high blood pressure reading, and how to answer them.

ANSWERING FOUR QUESTIONS

The goal of the hypertension evaluation is to answer four questions:

  • Does the patient have sustained hypertension? And if so—
  • Is the hypertension primary or secondary?
  • Does the patient have other cardiovascular risk factors?
  • Does he or she have evidence of target organ damage?

DOES THE PATIENT HAVE SUSTAINED HYPERTENSION?

It is important to measure blood pressure accurately, for several reasons. A diagnosis of hypertension has a measurable impact on the patient’s quality of life.2 Furthermore, we want to avoid undertaking a full evaluation of hypertension if the patient doesn’t actually have high blood pressure, ie, systolic blood pressure greater than 140 mm Hg or diastolic pressure greater than 90 mm Hg. However, many people have blood pressures in the prehypertensive range (ie, 120–139 mm Hg systolic; 80–89 mm Hg diastolic). Many people in this latter group can expect to develop hypertension in time, as the prevalence of hypertension increases steadily with age unless effective preventive measures are implemented, such as losing weight, exercising regularly, and avoiding excessive consumption of sodium and alcohol.

The steps involved in taking blood pressure are simple (Table 1)3,4 but often are not followed in busy clinical practices, and the job is frequently relegated to the least-well-trained staff in the office. The most common errors (failure to have the patient sit quietly for 5 minutes before a reading is taken, lack of arm or foot support, using too small a cuff relative to the size of the arm, deflating the cuff too rapidly) tend to falsely elevate the readings, leading to an overestimate of blood pressure. To reduce the variability commonly noted in staff-obtained manual blood pressure, some office practices use an automated system such as the BpTRU.5

The best position to use is sitting, as the Framingham Heart Study and most randomized clinical trials that established the value of treating hypertension used this position for diagnosis and follow-up.6

Proper patient positioning, the correct cuff size, calibrated equipment, and good inflation and deflation technique will yield the best assessment of blood pressure levels. But even if your technique is perfect, blood pressure is a dynamic vital sign, so it is necessary to repeat the measurement, average the values for any particular day, and keep in mind that the pressure is higher (or lower) on some days than on others, so that the running average is more important than individual readings. This leads to two final points about blood pressure measurement:

  • Take it right, at least two times on any occasion
  • Take it on at least two (preferably three) separate days.

Following up on blood pressure

After measuring the blood pressure, it is necessary to plan for follow-up readings, guided by both the blood pressure levels (Table 2) and your clinical judgment.

If the systolic and diastolic blood pressures fall into different categories, you should follow the recommendations for the shorter follow-up time.

 

 

IS THE HYPERTENSION PRIMARY OR SECONDARY?

Most patients with hypertension have primary (“essential”) hypertension and are likely to remain hypertensive for life. However, some have secondary hypertension, ie, high blood pressure due to an identifiable cause. Some of these conditions (and the hypertension that they cause) can be cured. For example, pheochromocytoma can be cured if found and removed. Other causes of secondary hypertension, such as parenchymal renal disease, are infrequently cured, and the goal is usually to control the blood pressure with drugs.

The sudden onset of severe hypertension in a patient previously known to have had normal blood pressure raises the suspicion of a secondary form of hypertension, as does the onset of hypertension in a young person (< 25 years) or an older person (> 55 years). However, these ages are arbitrary; with the increasing body mass index in young people, essential hypertension is now more commonly diagnosed in the third decade. And since systolic pressure increases throughout life, we can expect many older patients to develop essential hypertension.7 Indeed, current guidelines are urging us to pay more attention to systolic pressure than in the past.

WHAT IS THE PATIENT’S CARDIOVASCULAR RISK?

The relationship between blood pressure and risk of cardiovascular disease is linear, continuous, and independent of (though additive to) other risk factors.1 For people 40 to 70 years old, each increment of either 20 mm Hg in systolic blood pressure or 10 mm Hg in diastolic blood pressure doubles the risk of cardiovascular disease across the entire range from 115/75 to 185/115 mm Hg.1 If the patient smokes or has elevated cholesterol, other cardiovascular risk factors, or the metabolic syndrome, the risk is even higher.8

The usual goal of antihypertensive treatment is systolic pressure less than 140 mm Hg and diastolic pressure less than 90 mm Hg. However, the target is lower—less than 130/80 mm Hg—for those with diabetes9 or target organ damage such as heart failure or renal disease.1,10 Thus, it is important to try to detect these conditions in the evaluation of the hypertensive patient.

Another reason it is important is that reducing such risk sometimes calls for using (or avoiding) antihypertensive drugs that are likely to alter these factors. For example, the use of beta-blockers in patients with a low level of high-density lipoprotein cholesterol (HDL-C) can lower HDL-C further.11

DOES THE PATIENT HAVE TARGET ORGAN DAMAGE?

Target organ damage is very important to detect because it changes the goal of treatment from primary prevention of adverse target organ outcomes into the more challenging realm of secondary prevention. For example, if a patient has had a stroke, his or her chance of having another stroke in the next 5 years is about 20%. This is much higher than the risk in an average hypertensive patient without such a history. For such patients, the current guidelines1 recommend the combination of a diuretic and an angiotensin-converting enzyme inhibitor, a combination shown to reduce the risk of a second stroke.12 Thus, we need to discover whether the patient had a stroke in the first place.

HISTORY

The history (Table 3) helps elucidate whether hypertension is primary or secondary, the degree of cardiovascular risk, and whether target organ damage is present. One should try to ascertain:

  • The duration (if known) and severity of the hypertension
  • The degree of blood pressure fluctuation
  • Concomitant medical conditions, especially cardiovascular or renal problems
  • Dietary habits
  • Alcohol consumption
  • Tobacco use
  • Level of physical activity
  • A family history of hypertension, renal disease, cardiovascular problems, or diabetes mellitus
  • Past medications, with particular attention to their side effects and their efficacy in controlling blood pressure
  • Current medications, including over-the-counter preparations. One reason: non-steroidal anti-inflammatory drugs other than aspirin can decrease the efficacy of antihypertensive drugs, presumably through mechanisms that inhibit the effects of vasodilatory and natriuretic prostaglandins and potentiate those of angiotensin II.13
 

 

PHYSICAL EXAMINATION

The physical examination, like the history, give clues about secondary hypertension, cardiovascular risk, and target organ damage (Table 4).

The physical examination starts with measurement of height, weight, waist circumference, and blood pressure—in both arms and the leg if coarctation of the aorta is suspected. Measurements with the patient supine, sitting, and standing are usually taken at the first visit, though such an approach is more suited to a hypertension specialty clinic than a primary care setting, in which time constraints usually limit the blood pressure readings to two or three seated values. Most prospective data on the benefits of hypertension treatment are based on a seated blood pressure, so we favor that measurement for follow-up.

Special attention in the physical examination is directed to:

The retina (to assess the vascular impact of the high blood pressure). Look for arteriolar narrowing (grade 1), arteriovenous compression (grade 2), hemorrhages or exudates (grade 3), and papilledema.2 Such findings not only relate to severity (higher grade = more severe blood pressure) but also predict future cardiovascular disease.14

The blood vessels. Bruits in the neck may indicate carotid stenosis, bruits in the abdomen may indicate renovascular disease, and femoral bruits are a sign of general atherosclerosis. Bruits also signal vascular stenosis and irregularity and may be a clue to vascular damage or future loss of target organ function. However, bruits may simply result from vascular tortuosity, particularly with significant flow in the vessel.

Also check the femoral pulses: poor or delayed femoral pulses are a sign of aortic coarctation. The radial artery is about as far away from the heart as the femoral artery; consequently, when palpating both sites simultaneously the pulse should arrive at about the same moment. In aortic coarctation, a palpable delay in the arrival of the femoral pulse may occur, and an interscapular murmur may be heard during auscultation of the back. In these instances, a low leg blood pressure (usually measured by placing a thigh-sized adult cuff on the patient’s thigh and listening over the popliteal area with the patient prone) may confirm the presence of aortic obstruction. When taking a leg blood pressure, the large cuff and the amount of pressure necessary to occlude the artery may be uncomfortable, and one should warn the patient about the discomfort before taking the measurement.

Poor or absent pedal pulses are a sign of peripheral arterial disease.

The heart (to detect gallops, enlargement, or both). Palpation may reveal a displaced apical impulse, which can indicate left ventricular enlargement. A sustained apical impulse may indicate left ventricular hypertrophy. Listen for a fourth heart sound (S4), one of the earliest physical findings of hypertension when physical findings are present. An S4 indicates that the left atrium is working hard to overcome the stiffness of the left ventricle. An S3 indicates an impairment in left ventricular function and is usually a harbinger of underlying heart disease. In some cases, lung rales can also be heard, though the combination of an S3 gallop and rales is an unusual office presentation in the early management of the hypertensive patient.

The lungs. Listen for rales (see above).

The lower extremities should be examined for peripheral arterial pulsations and edema. The loss of pedal pulses is a common finding, particularly in smokers, and is a clue to increased cardiovascular risk.

Strength, gait, and cognition. Perform a brief neurologic examination for evidence of remote stroke. We usually observe our patients’ gait as they enter or leave the examination room, test their bilateral grip strength, and assess their judgment, speech, and memory during the history and physical examination.

A great deal of research has linked high blood pressure to future loss of cognitive function,15 and it is useful to know that impairment is present before beginning treatment, since some patients will complain of memory loss after starting antihypertensive drug treatment.

LABORATORY EVALUATION

Routine tests

The routine evaluation of hypertensive patients should include, at a minimum:

  • A hemoglobin or hematocrit measurement
  • Urinalysis with microscopic examination
  • Serum electrolyte concentrations
  • Serum creatinine concentrations
  • Serum glucose concentration
  • A fasting lipid profile
  • A 12-lead electrocardiogram (Table 5).

Nonroutine tests

In some cases, other studies may be appropriate, depending on the clinical situation, eg:

  • Serum uric acid in those with a history of gout, since some antihypertensive drugs (eg, diuretics) may increase serum uric acid and predispose to further episodes of gout
  • Serum calcium in those with a personal or family history of kidney stones, to detect subtle parathyroid excess
  • Thyroid-stimulating hormone or other thyroid studies if the history suggests thyroid excess, or if a thyroid nodule is discovered
  • Limited echocardiography, which is more sensitive than electrocardiography for detecting left ventricular hypertrophy.

We sometimes use echocardiography if the patient is overweight but seems motivated to lose weight. In these cases we might not start drug therapy right away, choosing rather to wait and see if the patient can lose some weight (which might lower the blood pressure and make drug therapy unnecessary)—but only if the echocardiogram shows that he or she does not have left ventricular hypertrophy.

We also use echocardiography in patients with white-coat hypertension (see below), in whom office pressures are consistently high but whom we have elected to either not treat or not alter treatment. In these cases the echocardiogram serves as a “second opinion” about the merits of not altering therapy and supports this decision when the left ventricular wall thicknesses are normal (and remain so during long-term follow-up). In cases of suspected white-coat hypertension, home or ambulatory blood pressure monitoring is valuable to establish or exclude this diagnosis.1

Urinary albumin excretion. Microalbuminuria is an early manifestation of diabetic nephropathy and hypertension. Although routine urine screening for microalbuminuria is typically done in the management of diabetes, it is still not considered a standard of care, though the growing literature on its role as a cardiovascular risk predictor16–18 and its value as a therapeutic target in diabetes19,20 make it an attractive aid in the overall assessment of patients with hypertension.

Plasma renin activity and serum aldosterone concentrations are useful in screening for aldosterone excess, but are usually reserved as follow-up tests in patients with either hypokalemia or failure to achieve blood pressure control on a three-drug regimen in which at least one drug is a diuretic.1,21

Of note, primary aldosteronism is not as rare as previously thought. In a study of patients referred to hypertension centers, 11% had primary aldosteronism according to prospective diagnostic criteria, almost 5% had curable aldosterone-producing adenomas, and 6% had idiopathic hyperaldosteronism.22

 

 

If secondary hypertension is suspected

Sometimes the history, examination, or initial testing leads one to suspect that a secondary form of hypertension may be present. Table 6 lists some of the common ways to pursue such suspicions. Readers are referred to several excellent reviews of secondary hypertension for further details.23–25

A search for secondary forms of hypertension is usually considered in patients with moderate or severe hypertension that does not respond to antihypertensive agents. Another situation is in hypertensive patients younger than 25 years, since curable forms of hypertension are more common in this age group. In older patients, the prevalence of secondary hypertension is lower and does not justify the costs and effort of routine elaborate workups unless there is evidence from the history, physical examination, or routine laboratory work for suspecting its presence. An exception to this rule is the need to exclude atherosclerotic renovascular hypertension in an elderly patient. This cause of secondary hypertension is common in the elderly and may be amenable to therapeutic intervention.26

WHEN TO CONSIDER HOME OR AMBULATORY MONITORING

Most patients with hypertension do not need ambulatory blood pressure monitoring, but in selected cases (Table 7), it may help in clinical management. However, Medicare and Medicaid pay for it only for the specific indication of white-coat hypertension. Readers are referred to a recent excellent review for further information.27

Suspected white-coat hypertension

Blood pressure can be influenced by an environment such as an office or hospital clinic. This has led to the development of ambulatory blood pressure monitors and more use of self-measurement of blood pressure in the home. Blood pressure readings with these techniques are generally lower than those measured in an office or hospital clinic. These methods make it possible to screen for white-coat hypertension. In 10% to 20% of people with hypertensive readings, the blood pressure may be elevated persistently only in the presence of a physician.28 When measured elsewhere, including at work, the blood pressure is not elevated in those with the white-coat effect. Although this response may become less prominent with repeated measurements, it occasionally persists in the office setting, sometimes for years in our experience.

Suspected nocturnal hypertension (’nondipping’ status)

Ambulatory blood pressure is also helpful to screen for nocturnal hypertension. Evidence is accumulating to suggest that hypertensive patients whose pressure remains relatively high at night (“nondippers,” ie, those with less than a 10% reduction at night compared with daytime blood pressure readings) are at greater risk of cardiovascular morbidity than “dippers” (those whose blood pressure is at least 10% lower at night than during the day).29

An early morning surge

Ambulatory monitoring can also detect morning surges in systolic blood pressure,30 a marker of cerebrovascular risk. Generally, these patients have an increase of more than 55 mm Hg in systolic pressure between their sleeping and early-hour waking values, and we may wish to start or alter treatment specifically to address these high morning systolic values.31

‘PIPESTEM’ VESSELS AND PSEUDOHYPERTENSION

Occasionally, one encounters patients with vessels that are stiff and difficult to compress. If the pressure required to compress the brachial artery and stop audible blood flow with a standard blood pressure cuff is greater than the actual blood pressure within the artery as measured invasively, the condition is called pseudohypertension. The stiffness is thought to be due to calcification of the arterial wall.

A way to check for this condition is to inflate the cuff to at least 30 mm Hg above the palpable systolic pressure and then try to “roll” the brachial or radial artery underneath your fingertips, a procedure known as Osler’s maneuver.32 If you feel something that resembles a stiff tube reminiscent of the stem of a tobacco smoker’s pipe (healthy arteries are not palpable when empty), the patient may have pseudohypertension. However, the specificity of Osler’s maneuver has been questioned, particularly in hospitalized elderly patients.33

Pseudohypertension is important because the patients in whom it occurs, usually the elderly or the chronically ill (with diabetes or chronic kidney disease), are prone to orthostatic or postural hypotension, which may be aggravated by increasing their antihypertensive treatment on the basis of a cuff pressure that is actually much higher than the real blood pressure.33

How extensive a workup does a patient with high blood pressure need?

On one hand, we would not want to start therapy on the basis of a single elevated reading, as blood pressure fluctuates considerably during the day, and even experienced physicians often make errors in taking blood pressure that tend to falsely elevate the patient’s readings. Similarly, we would not want to miss the diagnosis of a potentially curable cause of hypertension or of a condition that increases a patient’s risk of cardiovascular disease. But considering that nearly one-third of adults in the United States have hypertension and that another one-fourth have prehypertension (formerly called high-normal blood pressure),1 if we were to launch an intensive workup for every patient with high blood pressure, the cost and effort would be enormous.

Fortunately, for most patients, it is enough to measure blood pressure accurately and repeatedly, perform a focused history and physical examination, and obtain the results of a few basic laboratory tests and an electrocardiogram, with additional tests in special cases.

In this review we address four fundamental questions in the evaluation of patients with a high blood pressure reading, and how to answer them.

ANSWERING FOUR QUESTIONS

The goal of the hypertension evaluation is to answer four questions:

  • Does the patient have sustained hypertension? And if so—
  • Is the hypertension primary or secondary?
  • Does the patient have other cardiovascular risk factors?
  • Does he or she have evidence of target organ damage?

DOES THE PATIENT HAVE SUSTAINED HYPERTENSION?

It is important to measure blood pressure accurately, for several reasons. A diagnosis of hypertension has a measurable impact on the patient’s quality of life.2 Furthermore, we want to avoid undertaking a full evaluation of hypertension if the patient doesn’t actually have high blood pressure, ie, systolic blood pressure greater than 140 mm Hg or diastolic pressure greater than 90 mm Hg. However, many people have blood pressures in the prehypertensive range (ie, 120–139 mm Hg systolic; 80–89 mm Hg diastolic). Many people in this latter group can expect to develop hypertension in time, as the prevalence of hypertension increases steadily with age unless effective preventive measures are implemented, such as losing weight, exercising regularly, and avoiding excessive consumption of sodium and alcohol.

The steps involved in taking blood pressure are simple (Table 1)3,4 but often are not followed in busy clinical practices, and the job is frequently relegated to the least-well-trained staff in the office. The most common errors (failure to have the patient sit quietly for 5 minutes before a reading is taken, lack of arm or foot support, using too small a cuff relative to the size of the arm, deflating the cuff too rapidly) tend to falsely elevate the readings, leading to an overestimate of blood pressure. To reduce the variability commonly noted in staff-obtained manual blood pressure, some office practices use an automated system such as the BpTRU.5

The best position to use is sitting, as the Framingham Heart Study and most randomized clinical trials that established the value of treating hypertension used this position for diagnosis and follow-up.6

Proper patient positioning, the correct cuff size, calibrated equipment, and good inflation and deflation technique will yield the best assessment of blood pressure levels. But even if your technique is perfect, blood pressure is a dynamic vital sign, so it is necessary to repeat the measurement, average the values for any particular day, and keep in mind that the pressure is higher (or lower) on some days than on others, so that the running average is more important than individual readings. This leads to two final points about blood pressure measurement:

  • Take it right, at least two times on any occasion
  • Take it on at least two (preferably three) separate days.

Following up on blood pressure

After measuring the blood pressure, it is necessary to plan for follow-up readings, guided by both the blood pressure levels (Table 2) and your clinical judgment.

If the systolic and diastolic blood pressures fall into different categories, you should follow the recommendations for the shorter follow-up time.

 

 

IS THE HYPERTENSION PRIMARY OR SECONDARY?

Most patients with hypertension have primary (“essential”) hypertension and are likely to remain hypertensive for life. However, some have secondary hypertension, ie, high blood pressure due to an identifiable cause. Some of these conditions (and the hypertension that they cause) can be cured. For example, pheochromocytoma can be cured if found and removed. Other causes of secondary hypertension, such as parenchymal renal disease, are infrequently cured, and the goal is usually to control the blood pressure with drugs.

The sudden onset of severe hypertension in a patient previously known to have had normal blood pressure raises the suspicion of a secondary form of hypertension, as does the onset of hypertension in a young person (< 25 years) or an older person (> 55 years). However, these ages are arbitrary; with the increasing body mass index in young people, essential hypertension is now more commonly diagnosed in the third decade. And since systolic pressure increases throughout life, we can expect many older patients to develop essential hypertension.7 Indeed, current guidelines are urging us to pay more attention to systolic pressure than in the past.

WHAT IS THE PATIENT’S CARDIOVASCULAR RISK?

The relationship between blood pressure and risk of cardiovascular disease is linear, continuous, and independent of (though additive to) other risk factors.1 For people 40 to 70 years old, each increment of either 20 mm Hg in systolic blood pressure or 10 mm Hg in diastolic blood pressure doubles the risk of cardiovascular disease across the entire range from 115/75 to 185/115 mm Hg.1 If the patient smokes or has elevated cholesterol, other cardiovascular risk factors, or the metabolic syndrome, the risk is even higher.8

The usual goal of antihypertensive treatment is systolic pressure less than 140 mm Hg and diastolic pressure less than 90 mm Hg. However, the target is lower—less than 130/80 mm Hg—for those with diabetes9 or target organ damage such as heart failure or renal disease.1,10 Thus, it is important to try to detect these conditions in the evaluation of the hypertensive patient.

Another reason it is important is that reducing such risk sometimes calls for using (or avoiding) antihypertensive drugs that are likely to alter these factors. For example, the use of beta-blockers in patients with a low level of high-density lipoprotein cholesterol (HDL-C) can lower HDL-C further.11

DOES THE PATIENT HAVE TARGET ORGAN DAMAGE?

Target organ damage is very important to detect because it changes the goal of treatment from primary prevention of adverse target organ outcomes into the more challenging realm of secondary prevention. For example, if a patient has had a stroke, his or her chance of having another stroke in the next 5 years is about 20%. This is much higher than the risk in an average hypertensive patient without such a history. For such patients, the current guidelines1 recommend the combination of a diuretic and an angiotensin-converting enzyme inhibitor, a combination shown to reduce the risk of a second stroke.12 Thus, we need to discover whether the patient had a stroke in the first place.

HISTORY

The history (Table 3) helps elucidate whether hypertension is primary or secondary, the degree of cardiovascular risk, and whether target organ damage is present. One should try to ascertain:

  • The duration (if known) and severity of the hypertension
  • The degree of blood pressure fluctuation
  • Concomitant medical conditions, especially cardiovascular or renal problems
  • Dietary habits
  • Alcohol consumption
  • Tobacco use
  • Level of physical activity
  • A family history of hypertension, renal disease, cardiovascular problems, or diabetes mellitus
  • Past medications, with particular attention to their side effects and their efficacy in controlling blood pressure
  • Current medications, including over-the-counter preparations. One reason: non-steroidal anti-inflammatory drugs other than aspirin can decrease the efficacy of antihypertensive drugs, presumably through mechanisms that inhibit the effects of vasodilatory and natriuretic prostaglandins and potentiate those of angiotensin II.13
 

 

PHYSICAL EXAMINATION

The physical examination, like the history, give clues about secondary hypertension, cardiovascular risk, and target organ damage (Table 4).

The physical examination starts with measurement of height, weight, waist circumference, and blood pressure—in both arms and the leg if coarctation of the aorta is suspected. Measurements with the patient supine, sitting, and standing are usually taken at the first visit, though such an approach is more suited to a hypertension specialty clinic than a primary care setting, in which time constraints usually limit the blood pressure readings to two or three seated values. Most prospective data on the benefits of hypertension treatment are based on a seated blood pressure, so we favor that measurement for follow-up.

Special attention in the physical examination is directed to:

The retina (to assess the vascular impact of the high blood pressure). Look for arteriolar narrowing (grade 1), arteriovenous compression (grade 2), hemorrhages or exudates (grade 3), and papilledema.2 Such findings not only relate to severity (higher grade = more severe blood pressure) but also predict future cardiovascular disease.14

The blood vessels. Bruits in the neck may indicate carotid stenosis, bruits in the abdomen may indicate renovascular disease, and femoral bruits are a sign of general atherosclerosis. Bruits also signal vascular stenosis and irregularity and may be a clue to vascular damage or future loss of target organ function. However, bruits may simply result from vascular tortuosity, particularly with significant flow in the vessel.

Also check the femoral pulses: poor or delayed femoral pulses are a sign of aortic coarctation. The radial artery is about as far away from the heart as the femoral artery; consequently, when palpating both sites simultaneously the pulse should arrive at about the same moment. In aortic coarctation, a palpable delay in the arrival of the femoral pulse may occur, and an interscapular murmur may be heard during auscultation of the back. In these instances, a low leg blood pressure (usually measured by placing a thigh-sized adult cuff on the patient’s thigh and listening over the popliteal area with the patient prone) may confirm the presence of aortic obstruction. When taking a leg blood pressure, the large cuff and the amount of pressure necessary to occlude the artery may be uncomfortable, and one should warn the patient about the discomfort before taking the measurement.

Poor or absent pedal pulses are a sign of peripheral arterial disease.

The heart (to detect gallops, enlargement, or both). Palpation may reveal a displaced apical impulse, which can indicate left ventricular enlargement. A sustained apical impulse may indicate left ventricular hypertrophy. Listen for a fourth heart sound (S4), one of the earliest physical findings of hypertension when physical findings are present. An S4 indicates that the left atrium is working hard to overcome the stiffness of the left ventricle. An S3 indicates an impairment in left ventricular function and is usually a harbinger of underlying heart disease. In some cases, lung rales can also be heard, though the combination of an S3 gallop and rales is an unusual office presentation in the early management of the hypertensive patient.

The lungs. Listen for rales (see above).

The lower extremities should be examined for peripheral arterial pulsations and edema. The loss of pedal pulses is a common finding, particularly in smokers, and is a clue to increased cardiovascular risk.

Strength, gait, and cognition. Perform a brief neurologic examination for evidence of remote stroke. We usually observe our patients’ gait as they enter or leave the examination room, test their bilateral grip strength, and assess their judgment, speech, and memory during the history and physical examination.

A great deal of research has linked high blood pressure to future loss of cognitive function,15 and it is useful to know that impairment is present before beginning treatment, since some patients will complain of memory loss after starting antihypertensive drug treatment.

LABORATORY EVALUATION

Routine tests

The routine evaluation of hypertensive patients should include, at a minimum:

  • A hemoglobin or hematocrit measurement
  • Urinalysis with microscopic examination
  • Serum electrolyte concentrations
  • Serum creatinine concentrations
  • Serum glucose concentration
  • A fasting lipid profile
  • A 12-lead electrocardiogram (Table 5).

Nonroutine tests

In some cases, other studies may be appropriate, depending on the clinical situation, eg:

  • Serum uric acid in those with a history of gout, since some antihypertensive drugs (eg, diuretics) may increase serum uric acid and predispose to further episodes of gout
  • Serum calcium in those with a personal or family history of kidney stones, to detect subtle parathyroid excess
  • Thyroid-stimulating hormone or other thyroid studies if the history suggests thyroid excess, or if a thyroid nodule is discovered
  • Limited echocardiography, which is more sensitive than electrocardiography for detecting left ventricular hypertrophy.

We sometimes use echocardiography if the patient is overweight but seems motivated to lose weight. In these cases we might not start drug therapy right away, choosing rather to wait and see if the patient can lose some weight (which might lower the blood pressure and make drug therapy unnecessary)—but only if the echocardiogram shows that he or she does not have left ventricular hypertrophy.

We also use echocardiography in patients with white-coat hypertension (see below), in whom office pressures are consistently high but whom we have elected to either not treat or not alter treatment. In these cases the echocardiogram serves as a “second opinion” about the merits of not altering therapy and supports this decision when the left ventricular wall thicknesses are normal (and remain so during long-term follow-up). In cases of suspected white-coat hypertension, home or ambulatory blood pressure monitoring is valuable to establish or exclude this diagnosis.1

Urinary albumin excretion. Microalbuminuria is an early manifestation of diabetic nephropathy and hypertension. Although routine urine screening for microalbuminuria is typically done in the management of diabetes, it is still not considered a standard of care, though the growing literature on its role as a cardiovascular risk predictor16–18 and its value as a therapeutic target in diabetes19,20 make it an attractive aid in the overall assessment of patients with hypertension.

Plasma renin activity and serum aldosterone concentrations are useful in screening for aldosterone excess, but are usually reserved as follow-up tests in patients with either hypokalemia or failure to achieve blood pressure control on a three-drug regimen in which at least one drug is a diuretic.1,21

Of note, primary aldosteronism is not as rare as previously thought. In a study of patients referred to hypertension centers, 11% had primary aldosteronism according to prospective diagnostic criteria, almost 5% had curable aldosterone-producing adenomas, and 6% had idiopathic hyperaldosteronism.22

 

 

If secondary hypertension is suspected

Sometimes the history, examination, or initial testing leads one to suspect that a secondary form of hypertension may be present. Table 6 lists some of the common ways to pursue such suspicions. Readers are referred to several excellent reviews of secondary hypertension for further details.23–25

A search for secondary forms of hypertension is usually considered in patients with moderate or severe hypertension that does not respond to antihypertensive agents. Another situation is in hypertensive patients younger than 25 years, since curable forms of hypertension are more common in this age group. In older patients, the prevalence of secondary hypertension is lower and does not justify the costs and effort of routine elaborate workups unless there is evidence from the history, physical examination, or routine laboratory work for suspecting its presence. An exception to this rule is the need to exclude atherosclerotic renovascular hypertension in an elderly patient. This cause of secondary hypertension is common in the elderly and may be amenable to therapeutic intervention.26

WHEN TO CONSIDER HOME OR AMBULATORY MONITORING

Most patients with hypertension do not need ambulatory blood pressure monitoring, but in selected cases (Table 7), it may help in clinical management. However, Medicare and Medicaid pay for it only for the specific indication of white-coat hypertension. Readers are referred to a recent excellent review for further information.27

Suspected white-coat hypertension

Blood pressure can be influenced by an environment such as an office or hospital clinic. This has led to the development of ambulatory blood pressure monitors and more use of self-measurement of blood pressure in the home. Blood pressure readings with these techniques are generally lower than those measured in an office or hospital clinic. These methods make it possible to screen for white-coat hypertension. In 10% to 20% of people with hypertensive readings, the blood pressure may be elevated persistently only in the presence of a physician.28 When measured elsewhere, including at work, the blood pressure is not elevated in those with the white-coat effect. Although this response may become less prominent with repeated measurements, it occasionally persists in the office setting, sometimes for years in our experience.

Suspected nocturnal hypertension (’nondipping’ status)

Ambulatory blood pressure is also helpful to screen for nocturnal hypertension. Evidence is accumulating to suggest that hypertensive patients whose pressure remains relatively high at night (“nondippers,” ie, those with less than a 10% reduction at night compared with daytime blood pressure readings) are at greater risk of cardiovascular morbidity than “dippers” (those whose blood pressure is at least 10% lower at night than during the day).29

An early morning surge

Ambulatory monitoring can also detect morning surges in systolic blood pressure,30 a marker of cerebrovascular risk. Generally, these patients have an increase of more than 55 mm Hg in systolic pressure between their sleeping and early-hour waking values, and we may wish to start or alter treatment specifically to address these high morning systolic values.31

‘PIPESTEM’ VESSELS AND PSEUDOHYPERTENSION

Occasionally, one encounters patients with vessels that are stiff and difficult to compress. If the pressure required to compress the brachial artery and stop audible blood flow with a standard blood pressure cuff is greater than the actual blood pressure within the artery as measured invasively, the condition is called pseudohypertension. The stiffness is thought to be due to calcification of the arterial wall.

A way to check for this condition is to inflate the cuff to at least 30 mm Hg above the palpable systolic pressure and then try to “roll” the brachial or radial artery underneath your fingertips, a procedure known as Osler’s maneuver.32 If you feel something that resembles a stiff tube reminiscent of the stem of a tobacco smoker’s pipe (healthy arteries are not palpable when empty), the patient may have pseudohypertension. However, the specificity of Osler’s maneuver has been questioned, particularly in hospitalized elderly patients.33

Pseudohypertension is important because the patients in whom it occurs, usually the elderly or the chronically ill (with diabetes or chronic kidney disease), are prone to orthostatic or postural hypotension, which may be aggravated by increasing their antihypertensive treatment on the basis of a cuff pressure that is actually much higher than the real blood pressure.33

References
  1. Chobanian AV, Bakris GL, Black HR, et al. Seventh report of the Joint National Committee on Prevention, Detection, Evaluation, and Treatment of High Blood Pressure. Hypertension 2003; 42:12061252.
  2. Wenger NK. Quality of life issues in hypertension: consequences of diagnosis and considerations in management. Am Heart J 1988; 116:628632.
  3. McFadden CB, Townsend RR. Blood pressure measurement: common pitfalls and how to avoid them. Consultant 2003; 43:161165.
  4. Pickering TG, Hall JE, Appel LJ, et al. Recommendations for blood pressure measurement in humans and experimental animals: part 1: blood pressure measurement in humans: a statement for professionals from the Subcommittee of Professional and Public Education of the American Heart Association Council on High Blood Pressure Research. Circulation 2005; 111:697716.
  5. Myers MG. Automated blood pressure measurement in routine clinical practice. Blood Press Monit 2006; 11:5962.
  6. Mosenkis A, Townsend RR. Sitting on the evidence: what is the proper patient position for the office measurement of blood pressure? J Clin Hypertens (Greenwich) 2005; 7:365366.
  7. Vasan RS, Beiser A, Seshadri S, et al. Residual lifetime risk for developing hypertension in middle-aged women and men: The Framingham Heart Study. JAMA 2002; 287:10031010.
  8. Grundy SM, Cleeman JI, Merz CN, et al. Implications of recent clinical trials for the National Cholesterol Education Program Adult Treatment Panel III Guidelines. J Am Coll Cardiol 2004; 44:720732.
  9. American Diabetes Association. Treatment of hypertension in adults with diabetes. Diabetes Care 2002; 25:199201.
  10. Rosendorff C, Black HR, Cannon CP, et al. Treatment of hypertension in the prevention and management of ischemic heart disease: a scientific statement from the American Heart Association Council for High Blood Pressure Research and the Councils on Clinical Cardiology and Epidemiology and Prevention. Circulation 2007; 115:27612788.
  11. Papadakis JA, Mikhailidis DP, Vrentzos GE, Kalikaki A, Kazakou I, Ganotakis ES. Effect of antihypertensive treatment on plasma fibrinogen and serum HDL levels in patients with essential hypertension. Clin Appl Thromb Hemost 2005; 11:139146.
  12. PROGRESS Collaborative Group. Randomised trial of a perindopril-based blood-pressure-lowering regimen among 6,105 individuals with previous stroke or transient ischaemic attack. Lancet 2001; 358:10331041.
  13. Fierro-Carrion GA, Ram CV. Nonsteroidal anti-inflammatory drugs (NSAIDs) and blood pressure. Am J Cardiol 1997; 80:775776.
  14. Wong TY, McIntosh R. Hypertensive retinopathy signs as risk indicators of cardiovascular morbidity and mortality. Br Med Bull 2005; 73–74:5770.
  15. Forette F, Boller F. Hypertension and the risk of dementia in the elderly. Am J Med 1991; 90:14S19S.
  16. Schrader J, Luders S, Kulschewski A, et al. Microalbuminuria and tubular proteinuria as risk predictors of cardiovascular morbidity and mortality in essential hypertension: final results of a prospective long-term study (MARPLE Study). J Hypertens 2006; 24:541548.
  17. Luque M, de Rivas B, Alvarez B, Garcia G, Fernandez C, Martell N. Influence of target organ lesion detection (assessment of microalbuminuria and echocardiogram) in cardiovascular risk stratification and treatment of untreated hypertensive patients. J Hum Hypertens 2006; 20:187192.
  18. Pontremoli R, Leoncini G, Viazzi F, et al. Role of microalbuminuria in the assessment of cardiovascular risk in essential hypertension. J Am Soc Nephrol 2005; 16 suppl 1:S39S41.
  19. Erdmann E. Microalbuminuria as a marker of cardiovascular risk in patients with type 2 diabetes. Int J Cardiol 2006; 107:147153.
  20. Bakris GL, Sowers JR. Microalbuminuria in diabetes: focus on cardiovascular and renal risk reduction. Curr Diab Rep 2002; 2:258262.
  21. Gallay BJ, Ahmad S, Xu L, Toivola B, Davidson RC. Screening for primary aldosteronism without discontinuing hypertensive medications: plasma aldosteronerenin ratio. Am J Kidney Dis 2001; 37:699705.
  22. Rossi GP, Bernini G, Caliumi C, et al. A prospective study of the prevalence of primary aldosteronism in 1,125 hypertensive patients. J Am Coll Cardiol 2006; 48:22932300.
  23. Onusko E. Diagnosing secondary hypertension. Am Fam Physician 2003; 67:6774.
  24. Aurell M. Screening for secondary hypertension. Curr Hypertens Rep 1999; 1:461.
  25. Garovic VD, Kane GC, Schwartz GL. Renovascular hypertension: balancing the controversies in diagnosis and treatment. Cleve Clin J Med 2005; 72:11351137.
  26. Textor SC. Renovascular hypertension in 2007: where are we now? Curr Cardiol Rep 2007; 9:453461.
  27. Pickering TG, Shimbo D, Haas D. Ambulatory blood-pressure monitoring. N Engl J Med 2006; 354:23682374.
  28. Angeli F, Verdecchia P, Gattobigio R, Sardone M, Reboldi G. White-coat hypertension in adults. Blood Press Monit 2005; 10:301305.
  29. Cicconetti P, Morelli S, De Serra C, et al. Left ventricular mass in dippers and nondippers with newly diagnosed hypertension. Angiology 2003; 54:661669.
  30. Kario K, Pickering TG, Umeda Y, et al. Morning surge in blood pressure as a predictor of silent and clinical cerebrovascular disease in elderly hypertensives: a prospective study. Circulation 2003; 107:14011406.
  31. Katakam R, Townsend RR. Morning surges in blood pressure. J Clin Hypertens 2006; 8:450451.
  32. Messerli FH. Osler’s maneuver, pseudohypertension, and true hypertension in the elderly. Am J Med 1986; 80:906910.
  33. Belmin J, Visintin JM, Salvatore R, Sebban C, Moulias R. Osler’s maneuver: absence of usefulness for the detection of pseudohypertension in an elderly population. Am J Med 1995; 98:4249.
  34. Messerli FH, Ventura HO, Amodeo C. Osler’s maneuver and pseudohypertension. N Engl J Med 1985; 312:15481551.
References
  1. Chobanian AV, Bakris GL, Black HR, et al. Seventh report of the Joint National Committee on Prevention, Detection, Evaluation, and Treatment of High Blood Pressure. Hypertension 2003; 42:12061252.
  2. Wenger NK. Quality of life issues in hypertension: consequences of diagnosis and considerations in management. Am Heart J 1988; 116:628632.
  3. McFadden CB, Townsend RR. Blood pressure measurement: common pitfalls and how to avoid them. Consultant 2003; 43:161165.
  4. Pickering TG, Hall JE, Appel LJ, et al. Recommendations for blood pressure measurement in humans and experimental animals: part 1: blood pressure measurement in humans: a statement for professionals from the Subcommittee of Professional and Public Education of the American Heart Association Council on High Blood Pressure Research. Circulation 2005; 111:697716.
  5. Myers MG. Automated blood pressure measurement in routine clinical practice. Blood Press Monit 2006; 11:5962.
  6. Mosenkis A, Townsend RR. Sitting on the evidence: what is the proper patient position for the office measurement of blood pressure? J Clin Hypertens (Greenwich) 2005; 7:365366.
  7. Vasan RS, Beiser A, Seshadri S, et al. Residual lifetime risk for developing hypertension in middle-aged women and men: The Framingham Heart Study. JAMA 2002; 287:10031010.
  8. Grundy SM, Cleeman JI, Merz CN, et al. Implications of recent clinical trials for the National Cholesterol Education Program Adult Treatment Panel III Guidelines. J Am Coll Cardiol 2004; 44:720732.
  9. American Diabetes Association. Treatment of hypertension in adults with diabetes. Diabetes Care 2002; 25:199201.
  10. Rosendorff C, Black HR, Cannon CP, et al. Treatment of hypertension in the prevention and management of ischemic heart disease: a scientific statement from the American Heart Association Council for High Blood Pressure Research and the Councils on Clinical Cardiology and Epidemiology and Prevention. Circulation 2007; 115:27612788.
  11. Papadakis JA, Mikhailidis DP, Vrentzos GE, Kalikaki A, Kazakou I, Ganotakis ES. Effect of antihypertensive treatment on plasma fibrinogen and serum HDL levels in patients with essential hypertension. Clin Appl Thromb Hemost 2005; 11:139146.
  12. PROGRESS Collaborative Group. Randomised trial of a perindopril-based blood-pressure-lowering regimen among 6,105 individuals with previous stroke or transient ischaemic attack. Lancet 2001; 358:10331041.
  13. Fierro-Carrion GA, Ram CV. Nonsteroidal anti-inflammatory drugs (NSAIDs) and blood pressure. Am J Cardiol 1997; 80:775776.
  14. Wong TY, McIntosh R. Hypertensive retinopathy signs as risk indicators of cardiovascular morbidity and mortality. Br Med Bull 2005; 73–74:5770.
  15. Forette F, Boller F. Hypertension and the risk of dementia in the elderly. Am J Med 1991; 90:14S19S.
  16. Schrader J, Luders S, Kulschewski A, et al. Microalbuminuria and tubular proteinuria as risk predictors of cardiovascular morbidity and mortality in essential hypertension: final results of a prospective long-term study (MARPLE Study). J Hypertens 2006; 24:541548.
  17. Luque M, de Rivas B, Alvarez B, Garcia G, Fernandez C, Martell N. Influence of target organ lesion detection (assessment of microalbuminuria and echocardiogram) in cardiovascular risk stratification and treatment of untreated hypertensive patients. J Hum Hypertens 2006; 20:187192.
  18. Pontremoli R, Leoncini G, Viazzi F, et al. Role of microalbuminuria in the assessment of cardiovascular risk in essential hypertension. J Am Soc Nephrol 2005; 16 suppl 1:S39S41.
  19. Erdmann E. Microalbuminuria as a marker of cardiovascular risk in patients with type 2 diabetes. Int J Cardiol 2006; 107:147153.
  20. Bakris GL, Sowers JR. Microalbuminuria in diabetes: focus on cardiovascular and renal risk reduction. Curr Diab Rep 2002; 2:258262.
  21. Gallay BJ, Ahmad S, Xu L, Toivola B, Davidson RC. Screening for primary aldosteronism without discontinuing hypertensive medications: plasma aldosteronerenin ratio. Am J Kidney Dis 2001; 37:699705.
  22. Rossi GP, Bernini G, Caliumi C, et al. A prospective study of the prevalence of primary aldosteronism in 1,125 hypertensive patients. J Am Coll Cardiol 2006; 48:22932300.
  23. Onusko E. Diagnosing secondary hypertension. Am Fam Physician 2003; 67:6774.
  24. Aurell M. Screening for secondary hypertension. Curr Hypertens Rep 1999; 1:461.
  25. Garovic VD, Kane GC, Schwartz GL. Renovascular hypertension: balancing the controversies in diagnosis and treatment. Cleve Clin J Med 2005; 72:11351137.
  26. Textor SC. Renovascular hypertension in 2007: where are we now? Curr Cardiol Rep 2007; 9:453461.
  27. Pickering TG, Shimbo D, Haas D. Ambulatory blood-pressure monitoring. N Engl J Med 2006; 354:23682374.
  28. Angeli F, Verdecchia P, Gattobigio R, Sardone M, Reboldi G. White-coat hypertension in adults. Blood Press Monit 2005; 10:301305.
  29. Cicconetti P, Morelli S, De Serra C, et al. Left ventricular mass in dippers and nondippers with newly diagnosed hypertension. Angiology 2003; 54:661669.
  30. Kario K, Pickering TG, Umeda Y, et al. Morning surge in blood pressure as a predictor of silent and clinical cerebrovascular disease in elderly hypertensives: a prospective study. Circulation 2003; 107:14011406.
  31. Katakam R, Townsend RR. Morning surges in blood pressure. J Clin Hypertens 2006; 8:450451.
  32. Messerli FH. Osler’s maneuver, pseudohypertension, and true hypertension in the elderly. Am J Med 1986; 80:906910.
  33. Belmin J, Visintin JM, Salvatore R, Sebban C, Moulias R. Osler’s maneuver: absence of usefulness for the detection of pseudohypertension in an elderly population. Am J Med 1995; 98:4249.
  34. Messerli FH, Ventura HO, Amodeo C. Osler’s maneuver and pseudohypertension. N Engl J Med 1985; 312:15481551.
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KEY POINTS

  • To confirm the diagnosis of hypertension, multiple readings should be taken at various times.
  • Proper technique is important in measuring blood pressure, including using the correct cuff size, having the patient sit quietly for 5 minutes before taking the pressure, and supporting the arm at the level of the heart.
  • If white-coat hypertension is suspected, one can consider ambulatory or home blood pressure measurements to confirm that the hypertension is sustained.
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Perioperative statins: More than lipid-lowering?

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Perioperative statins: More than lipid-lowering?
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Leonard S. Feldman, MD
Daniel J. Brotman, MD, SFHM, FACP

Soon, the checklist for internists seeing patients about to undergo surgery may include prescribing one of the lipid-lowering hydroxymethylglutaryl-CoA reductase inhibitors, also called statins.

Statins? Not long ago, we were debating whether patients who take statins should stop taking them before surgery, based on the manufacturers’ recommendations.1 The discussion, however, has changed to whether patients who have never received a statin should be started on one before surgery to provide immediate prophylaxis against cardiac morbidity, and how much harm long-term statin users face if these drugs are withheld perioperatively.

The evidence is still very preliminary and based mostly on studies in animals and retrospective studies in people. However, an expanding body of indirect evidence suggests that these drugs are beneficial in this situation.

In this review, we discuss the mechanisms by which statins may protect the heart in the short term, drawing on data from animal and human studies of acute myocardial infarction, and we review the current (albeit limited) data from the perioperative setting.

FEW INTERVENTIONS DECREASE RISK

Each year, approximately 50,000 patients suffer a perioperative cardiovascular event; the incidence of myocardial infarction during or after noncardiac surgery is 2% to 3%.2 The primary goal of preoperative cardiovascular risk assessment is to predict and avert these events.

But short of canceling surgery, few interventions have been found to reduce a patient’s risk. For example, a landmark study in 2004 cast doubt on the efficacy of preoperative coronary revascularization.3 Similarly, although early studies of beta-blockers were promising4,5 and although most internists prescribe these drugs before surgery, more recent studies have cast doubt on their efficacy, particularly in patients at low risk undergoing intermediate-risk (rather than vascular) surgery.6–8

This changing clinical landscape has prompted a search for new strategies for perioperative risk-reduction. Several recent studies have placed statins in the spotlight.

POTENTIAL MECHANISMS OF SHORT-TERM BENEFIT

Statins have been proven to save lives when used long-term, but how could this class of drugs, designed to prevent the accumulation of arterial plaques by lowering low-density lipoprotein cholesterol (LDL-C) levels, have any short-term impact on operative outcomes? Although LDL-C reduction is the principal mechanism of action of statins, not all of the benefit can be ascribed to this mechanism.9 The answer may lie in their “pleiotropic” effects—ie, actions other than LDL-C reduction.

The more immediate pleiotropic effects of statins in the proinflammatory and prothrombotic environment of the perioperative period are thought to include improved endothelial function (both antithrombotic function and vasomotor function in response to ischemic stress), enhanced stability of atherosclerotic plaques, decreased oxidative stress, and decreased vascular inflammation.10–12

EVIDENCE FROM ANIMAL STUDIES

Experiments in animals suggest that statins, given shortly before or after a cardiovascular event, confer benefit before any changes in LDL-C are measurable.

Lefer et al13 found that simvastatin (Zocor), given 18 hours before an ischemic episode in rats, blunted the inflammatory response in cardiac reperfusion injury. Not only was reperfusion injury significantly less in the hearts of the rats that received simvastatin than in the saline control group, but the simvastatin-treated hearts also expressed fewer neutrophil adhesion molecules such as P-selectin, and they had more basal release of nitric oxide, the potent endothelial-derived vasodilator with antithrombotic, anti-inflammatory, and antiproliferative effects.14 These results suggest that statins may improve endothelial function acutely, particularly during ischemic stress.

Osborne et al15 fed rabbits a cholesterol-rich diet plus either lovastatin (Mevacor) or placebo. After 2 weeks, the rabbits underwent either surgery to induce a myocardial infarction or a sham procedure. Regardless of the pretreatment, biopsies of the aorta did not reveal any atherosclerosis; yet the lovastatin-treated rabbits sustained less myocardial ischemic damage and they had more endothelium-mediated vasodilatation.

Statin therapy also may improve cerebral ischemia outcomes in animal models.14,16

Sironi et al16 induced strokes in rats by occluding the middle cerebral artery. The rats received either simvastatin or vehicle for 3 days before the stroke or immediately afterwards. Even though simvastatin did not have enough time to affect the total cholesterol level, rats treated with simvastatin had smaller infarcts (as measured by magnetic resonance imaging) and produced more nitric oxide.

Comment. Taken together, these studies offer tantalizing evidence that statins have short-term, beneficial nonlipid effects and may reduce not only the likelihood of an ischemic event, but—should one occur—the degree of tissue damage that ensues.

 

 

EFFECTS OF STATINS IN ACUTE CORONARY SYNDROME

The National Registry of Myocardial Infarction17 is a prospective, observational database of all patients with acute myocardial infarction admitted to 1,230 participating hospitals throughout the United States. In an analysis from this cohort, patients were divided into four groups: those receiving statins before and after admission, those receiving statins only before admission, those receiving statins only after admission, and those who never received statins.

Compared with those who never received statins, fewer patients who received them both before and after admission died while in the hospital (unadjusted odds ratio 0.23, 95% confidence interval [CI] 0.22–0.25), and the odds ratio for those who received statins for the first time was 0.31 (95% CI 0.29–0.33). Patients who stopped receiving a statin on admission were more likely to die than were patients who never received statins (odds ratio 1.09, 95% CI 1.03–1.15). These trends held true even when adjustments were made for potential confounding factors.

Comment. Unmeasured confounding factors (such as the inability to take pills due to altered mental status or the different practice styles of the providers who chose to discontinue statins) might have affected the results. Nevertheless, these results suggest that the protective effects of statins stop almost immediately when these drugs are discontinued, and that there may even be an adverse “rebound” effect when patients who have been taking these drugs for a long time stop taking them temporarily.

The Platelet Receptor Inhibition in Ischemic Syndrome Management trial,18 in a subgroup analysis, had nearly identical findings. In the main part of this trial, patients with coronary artery disease and chest pain at rest or accelerating pain in the last 24 hours were randomized to receive tirofiban (Aggrastat) or heparin. Complete data on statin use were available for 1,616 (50%) of the 3,232 patients in this trial, and the rate of the primary end point (death, myocardial infarction, or recurrent ischemia) was analyzed on the basis of statin therapy in this subgroup.

The rate of the combined end point was significantly lower at 48 hours for those who had been receiving statins and continued receiving them (2.6%) than in those who never received statins (5.9%) or in those whose statins were discontinued (10.5%). Statins were more helpful if they were started before hospitalization than if they were started at the time of hospitalization.

Comment. Together, these data lead to the conclusion that, when admitted for either acute myocardial infarction or acute coronary syndrome, patients already receiving statins should not have them stopped, and those who had not been receiving statins should receive them immediately. The safety of these medications in the acute setting appears excellent: in the Myocardial Ischemia Reduction With Acute Cholesterol Lowering (MIRACL)12 and the Pravastatin or Atorvastatin Evaluation and Infection Therapy (PROVE-IT)11 trials, fewer than 5% of statin-treated patients had transient elevations in transaminase levels, and no cases of rhabdomyolysis were reported.

PERIOPERATIVE STATIN STUDIES

The data on perioperative statin use are mostly observational and retrospective and fall into essentially four surgical categories: coronary artery bypass grafting (CABG), carotid endarterectomy,19,20 noncardiac vascular surgery, and major noncardiac surgery. Two meta-analyses have also evaluated the data.21,22 The only randomized controlled trial (performed by Durazzo et al23) was small and was carried out at a single center in vascular surgery patients, and the event rate was low.

Current recommendations from the National Cholesterol Education Program (NCEP)24 say that patients who need CABG, have peripheral arterial disease, have an abdominal aortic aneurysm, or have cerebrovascular disease should already be on a statin to achieve an LDL-C goal level of less than 100 mg/dL, with an optional goal of less than 70 mg/dL, independent of surgery.

Since not all patients who should be on statins are actually on them, questions arise:

  • Is it important (and safe) to start statin treatment preoperatively?
  • Will patients with cardiovascular risk factors but without known cardiovascular disease benefit from statins perioperatively?

Noncardiac vascular surgery

Multiple retrospective studies have evaluated the effect of statins in patients undergoing major noncardiac vascular surgery.25–32

Kertai et al25 evaluated 570 patients in Holland who underwent elective open surgery for infrarenal abdominal aortic aneurysms between 1991 and 2001, looking for an association between statin use and the incidence of perioperative death from myocardial infarction. Only 162 of the 570 patients had been on long-term statin therapy before the surgery. The use of statins was only one of many known baseline characteristics that were significantly different between the two groups, including age, body mass index, known coronary artery disease, and use of angiotensin-converting enzyme inhibitors and beta-blockers. In univariate analysis, statins appeared to be protective: 6 (3.7%) of the patients in the statin group died of a myocardial infarction, compared with 45 (11%) of those in the nostatin group. A multivariate analysis yielded similar findings, with an odds ratio of 0.24 (95% CI 0.11–0.54).

Ward et al27 performed a very similar retrospective study, with similar findings. In 446 patients who underwent surgery for infrarenal abdominal aortic aneurysm, statin therapy was associated with a significantly lower incidence of the combined end point of death, myocardial infarction, stroke, and major peripheral vascular complications, with an adjusted odds ratio of 0.36 (95% CI 0.14–0.93).

Poldermans et al26 noted similar findings in a case-control study of noncardiac vascular surgery patients. Statin users had a much lower perioperative risk of death than did nonusers, with an adjusted odds ratio of 0.22 (95% CI 0.10–0.47).

O’Neil-Callahan et al,28 in a cohort study, found that statin users had fewer perioperative cardiac complications, with an adjusted odds ratio of 0.49 (95% CI 0.28–0.84, P = .009).

 

 

Dogma of withdrawing statins before major surgery is challenged

Le Manach et al33 reviewed the outcomes for all patients of a single hospital in Paris who underwent nonemergency infrarenal aortic procedures between January 2001 and December 2004. In January 2004, the hospital instituted guidelines to ensure that patients on statins continue taking them up to the evening before surgery and that statins be restarted on the first postoperative day (via nasogastric tube if necessary). Before 2004, there had been no specific guidelines, and patients on statins did not receive them for a median of 4 days postoperatively. Types of procedures were similar during the two time periods, as were the rates of beta-blocker use, preoperative revascularization, venous thromboembolism prophylaxis, and perioperative blood pressure control. After surgery, topononin I levels were measured in all patients as surveillance for cardiac events, and were defined as elevated when greater than 0.2 ng/mL.

Compared with patients not on statins at all, those treated with statins continuously throughout the perioperative period (after January 2004) had a lower rate of elevated troponin (relative risk 0.38). In contrast, those who had their statins transiently discontinued perioperatively (prior to 2004) had troponin elevations more often than those who had never been treated (relative risk 2.1). This suggested an over fivefold risk reduction (P < .001) conferred by not discontinuing statins in the immediate postoperative period. This finding was maintained after multivariate adjustment: statin withdrawal was associated with a 2.9-fold (95% CI 1.6–5.5) increase in the risk of cardiac enzyme elevations postoperatively. No fewer deaths were noted, but the study was not powered to detect a mortality difference.

Comment. Although secular trends cannot be entirely discounted as contributing to these findings, the prompt increase in cardiac events after just 4 days of statin withdrawal adds to the growing body of evidence suggesting that statin discontinuation can have harmful acute effects. It also brings up the question: Can starting statins benefit patients in the same time period?

Should statins be started before vascular surgery?

Schouten et al32 evaluated the effects of newly started or continued statin treatment in patients undergoing major elective vascular surgery. Patients were screened before surgery and started on statins if they were not already receiving them and their total cholesterol levels were elevated; new users received the medication for about 40 days before surgery. Of the 981 screened patients, 44 (5%) were newly started on statins and 182 (19%) were continued on their therapy. Perioperative death or myocardial infarction occurred in 22 (8.8%) of the statin users and 111 (14.7%) of the nonusers, a statistically significant difference. Temporary discontinuation (median 1 day) of statins in this study due to the inability to take an oral medication did not appear to affect the likelihood of a myocardial infarction.

Durazzo et al23 performed a single-center, randomized, prospective, placebo-controlled, double-blind clinical trial of atorvastatin (Lipitor) 20 mg daily vs placebo in 100 patients undergoing noncardiac arterial vascular surgery. Patients were excluded if they had previously used medications to treat dyslipidemia, recently had a cardiovascular event, or had contraindications to statin treatment such as a baseline creatinine level greater than 2.0 mg/dL or severe hepatic disease. The intervention group received atorvastatin starting at least 2 weeks before surgery for a total of 45 days. Patients were then continued or started on a statin after surgery if their LDL-C level was greater than 100 mg/dL. Beta-blocker use was recommended “on the basis of current guidelines.”

One month after surgery, the LDL-C level was statistically significantly lower in the atorvastatin group. Since most patients did not continue or start statin therapy after the 45-day treatment period, the LDL-C levels were not statistically different at 3 and 6 months after surgery.

At 6 months, the rate of the primary end point (death from cardiovascular causes, nonfatal acute myocardial infarction, ischemic stroke, or unstable angina) was 26.0% in the placebo group and 8.0% in the atorvastatin group, a statistically significant difference. Three patients in the atorvastatin group had cardiac events in the first 10 days after surgery, compared with 11 patients in the placebo group. Thirteen of the 17 total cardiac events took place within 10 days after surgery.

One of the atorvastatin patients developed rhabdomyolysis and elevated aminotransferase levels.

Major noncardiac surgery

Lindenauer et al2 performed a retrospective cohort study of surgical patients who were at least 18 years old and survived beyond the second hospital day. Patients were divided into a group receiving any form of lipid-lowering treatment (of whom more than 90% were taking statins) and a group that had never never received a lipid-lowering drug or only started one on the third day of the hospitalization or later. The period of study was from January 1, 2000, to December 31, 2001.

In all, 780,591 patients from 329 hospitals throughout the United States were included, of whom only 77,082 (9.9%) received lipid-lowering therapy. Eight percent of the patients underwent vascular surgery. Not surprisingly, the treated patients were more likely to have a history of hypertension, diabetes, ischemic heart disease, or hyperlipidemia. They also were more likely to have a vascular procedure performed, to have two or more cardiac risk factors (high-risk surgery, ischemic heart disease, congestive heart failure, cerebrovascular disease, renal insufficiency, or diabetes mellitus), and to be treated with beta-blockers and angiotensin-converting enzyme inhibitors, but they were less likely to have high-risk and emergency surgery performed.

The primary end point, perioperative death, occurred in 2.13% of the treated patients and 3.05% of the nontreated group. Compared with the rate in a propensity-matched cohort, the odds ratio adjusted for unbalanced covariates was 0.62 (95% CI 0.58–0.67) in favor of lipid treatment. Stratification by cardiac risk index revealed a number needed to treat of 186 for those with no risk factors, 60 for those with two risk factors, and 30 for those with four or more risk factors.

Unfortunately, this analysis was not able to take into account whether and for how long patients were receiving lipid-lowering therapy before hospitalization. It therefore does not answer the questions of whether starting lipid-lowering therapy before surgery is beneficial or whether stopping it is harmful. It also does not shed light on whether perioperative lipid-lowering increases the risk of rhabdomyolysis or liver disease.

 

 

Carotid endarterectomy

Two recent retrospective cohort studies evaluated the outcomes in patients undergoing carotid endarterectomy.19,20

Kennedy et al19 found that patients on a statin at the time of admission who had symptomatic carotid disease had lower rates of inhospital death (adjusted odds ratio 0.24, 95% CI 0.06–0.91) and ischemic stroke or death (adjusted odds ratio 0.55, 95% CI 0.31–0.97). However, cardiac outcomes among these symptomatic patients were not significantly improved (odds ratio 0.82, 95% CI 0.45–1.50), nor was there benefit for asymptomatic patients, raising the possibility that the positive findings were due to chance or that patients at lower baseline risk for vascular events may have less benefit.

McGirt et al20 performed a similar study; they did not, however, distinguish whether patients had symptomatic vs asymptomatic carotid disease. The 30-day risk of perioperative stroke was lower in patients treated with a statin, with an odds ratio of 0.41 (95% CI 0.18–0.93); the odds ratio for death was 0.21 (95% CI 0.05–0.96). Cardiac outcomes were not significantly affected.

Coronary artery bypass graft surgery

According to the NCEP recommendations, nearly all patients undergoing CABG should already be on a statin before surgery since they all have known coronary artery disease. Multiple observational studies have offered confirmatory evidence that statins are beneficial in this setting.34–38

Liakopoulos et al39 evaluated whether the anti-inflammatory effects of statins may, in part, account for their beneficial effect in the perioperative period. The authors prospectively matched 18 patients who were taking statins and were referred for elective CABG with 18 patients who were not prescribed statins previously. The only major measured baseline characteristic that differed between the two groups was a statistically significantly lower LDL-C level in the statin group. The operative characteristics did not differ, and cytokine levels at baseline were similar.

Tumor necrosis factor alpha levels increased significantly in the control group but did not change significantly in the statin group. Interleukin 8 increased in both groups by a similar amount. Interleukin 6 (the major inducer of C-reactive protein) increased from baseline in both groups but did not increase nearly as much in the statin group as in the control group; the intergroup difference was statistically significant. The anti-inflammatory cytokine interleukin 10 increased minimally from baseline in the control group, while the statin group’s levels increased significantly above baseline and those of the control group.

Christenson40 also found that inflammatory markers were improved with pre-CABG statin treatment in a small randomized trial in which patients received simvastatin 20 mg 4 weeks prior to CABG surgery vs no statin. Interestingly, far fewer statin-treated patients developed thrombocytosis (platelet count > 400 × 109/L) than did control patients (3% vs 81%, P < .0001).

RISKS OF PERIOPERATIVE STATINS

The risks associated with statin therapy in general appear low, but specific perioperative risks have not been well studied.

Baigent et al,41 in a meta-analysis of randomized trials of nonperioperative statin therapy, found that rhabdomyolysis occurred in 9 (0.023%) of 39,884 patients receiving statins vs 6 (0.015%) of the 39,817 controls, with a number needed to harm of 12,500. Moreover, the rates of nonvascular death and cancer did not increase. It is plausible that the risk is somewhat greater in the perioperative setting but is likely not enough to outweigh the potential benefits, especially since the risk of ischemic vascular events is particularly high then.

Some of the perioperative studies cited above specifically addressed potential risks. For example, in the study by Schouten et al,32 mild creatine kinase elevations were more common in the statin-treated group, but the incidence of moderate and severe creatine kinase elevations did not differ significantly. No case of rhabdomyolysis occurred, and length of surgery was the only predictor of myopathy. MIRACL and PROVE-IT revealed similar safety profiles; aminotransferase levels normalized when statins were stopped, and no cases of rhabdomyolysis occurred.11,12 In the vascular surgery study by Durazzo et al,23 1 (2%) of the 50 atorvastatin-treated patients developed both rhabdomyolysis and elevated aminotransferase levels that prompted discontinuation of the statin.

Overall, the observational studies do not indicate that statin continuation or treatment is harmful in perioperative patients. However, these studies did not specifically evaluate patients with acute insults from surgery such as sepsis, renal failure, or hepatitis. It is unknown what effect statin therapy would have in those patients and whether statins should be selectively discontinued in patients who develop major hepatic, musculoskeletal, or renal complications after surgery.

 

 

OUR RECOMMENDATIONS

Before CABG or vascular surgery

Given the NCEP recommendations, existing primary and secondary prevention studies, observational studies of CABG and noncardiac vascular surgery patients, and the one randomized trial of vascular surgery patients, data support the use of statins in nearly all patients undergoing cardiac or vascular surgery. We advocate starting statins in the perioperative period to take advantage of their rapid-acting pleiotropic effects, and continuing them long-term to take advantage of their lipid-lowering effects. This recommendation is in line with the recently released American College of Cardiology/American Heart Association (ACC/AHA) 2007 perioperative guidelines that state “for patients undergoing vascular surgery with or without clinical risk factors, statin use is reasonable.”42

Although the ideal time to start statins is not certain, the study by Durazzo et al23 suggests that they should be started at least 2 weeks before surgery if possible. Moreover, patients already taking statins should definitely not have their statins discontinued if at all possible.

Before major nonvascular surgery

For patients undergoing major nonvascular (intermediate-risk) surgery, physicians should first ascertain if the patient has an indication for statin therapy based on current nonsurgical lipid level recommendations. However, even if there is no clear indication for statin therapy based on NCEP guidelines, we endorse the recently released ACC/AHA perioperative guidelines that state that statin therapy can be considered in patients with a risk factor who are undergoing intermediate-risk procedures. Moreover, we wholeheartedly support the ACC/AHA’s strongest recommendation that patients who are already receiving statins and are undergoing noncardiac surgery should not have their statins discontinued.

When to discontinue statins?

The risk of harm overall appears to be minimal and certainly less than the likelihood of benefit. It is reasonable to observe patients postoperatively for adverse clinical events that may increase the risk of perioperative statin treatment, such as acute renal failure, hepatic failure, or sepsis, but whether statins should be stopped in patients with these complications remains unknown; we advocate individualizing the decision.

More studies needed

We need more data on whether moderate-risk patients undergoing moderate-risk surgery benefit from perioperative statin therapy, when therapy should be started, whether therapy should be started on the day of surgery if it was not started earlier, which statin and what doses are optimal, how long therapy should be continued, and what degree of risk is associated with perioperative statin therapy.

Fortunately, important data should be forthcoming in the next few years: the Dutch Echocardiographic Cardiac Risk Evaluation Applying Stress Echocardiography (DECREASE-IV) study43 is a 4-year two-by-two factorial placebo-controlled study evaluating the use of fluvastatin (Lescol) and bisoprolol (Zebeta, a beta-blocker) separately and together in patients who are older than 40 years, are undergoing elective noncardiac surgery, have an estimated risk of cardiovascular death of more than 1%, have not used statins previously, and do not have elevated cholesterol.

References
  1. Grant PJ, Kedia N. Should statins be discontinued preoperatively? IMPACT consults. Proceedings of the 2nd Annual Cleveland Clinic Perioperative Medicine Summit. Cleve Clin J Med 2006; 73 Electronic suppl 1:S9S10.
  2. Lindenauer PK, Pekow P, Wang K, Gutierrez B, Benjamin EM. Lipid-lowering therapy and in-hospital mortality following major noncardiac surgery. JAMA 2004; 291:20922099.
  3. McFalls EO, Ward HB, Moritz TE, et al. Coronary-artery revascularization before elective major vascular surgery. N Engl J Med 2004; 351:27952804.
  4. Mangano DT, Layug EL, Wallace A, Tateo I. Effect of atenolol on mortality and cardiovascular morbidity after noncardiac surgery. Multicenter Study of Perioperative Ischemia Research Group. N Engl J Med 1996; 335:17131720.
  5. Poldermans D, Boersma E, Bax JJ, et al. The effect of bisoprolol on perioperative mortality and myocardial infarction in high-risk patients undergoing vascular surgery. Dutch Echocardiographic Cardiac Risk Evaluation Applying Stress Echocardiography Study Group. N Engl J Med 1999; 341:17891794.
  6. Brady AR, Gibbs JS, Greenhalgh RM, Powell JT, Sydes MR. Perioperative beta-blockade (POBBLE) for patients undergoing infrarenal vascular surgery: results of a randomized double-blind controlled trial. J Vasc Surg 2005; 41:602609.
  7. Juul AB, Wetterslev J, Gluud C, et al. Effect of perioperative beta blockade in patients with diabetes undergoing major non-cardiac surgery: randomised placebo controlled, blinded multicentre trial. BMJ 2006; 332:1482.
  8. Yang H, Raymer K, Butler R, Parlow J, Roberts R. The effects of perioperative beta-blockade: results of the Metoprolol after Vascular Surgery (MaVS) study, a randomized controlled trial. Am Heart J 2006; 152:983990.
  9. Ridker PM, Cannon CP, Morrow D, et al. C-reactive protein levels and outcomes after statin therapy. N Engl J Med 2005; 352:2028.
  10. Ito MK, Talbert RL, Tsimikas S. Statin-associated pleiotropy: possible beneficial effects beyond cholesterol reduction. Pharmacotherapy 2006; 26:85S97S.
  11. Cannon CP, Braunwald E, McCabe CH, et al. Intensive versus moderate lipid lowering with statins after acute coronary syndromes. N Engl J Med 2004; 350:14951504.
  12. Schwartz GG, Olsson AG, Ezekowitz MD, et al. Effects of atorvastatin on early recurrent ischemic events in acute coronary syndromes: the MIRACL study: a randomized controlled trial. JAMA 2001; 285:17111718.
  13. Lefer AM, Campbell B, Shin YK, Scalia R, Hayward R, Lefer DJ. Simvastatin preserves the ischemic-reperfused myocardium in normocholesterolemic rat hearts. Circulation 1999; 100:178184.
  14. Endres M, Laufs U, Liao JK, Moskowitz MA. Targeting eNOS for stroke protection. Trends Neurosci 2004; 27:283289.
  15. Osborne JA, Lento PH, Siegfried MR, Stahl GL, Fusman B, Lefer AM. Cardiovascular effects of acute hypercholesterolemia in rabbits. Reversal with lovastatin treatment. J Clin Invest 1989; 83:465473.
  16. Sironi L, Cimino M, Guerrini U, et al. Treatment with statins after induction of focal ischemia in rats reduces the extent of brain damage. Arterioscler Thromb Vasc Biol 2003; 23:322327.
  17. Fonarow GC, Wright RS, Spencer FA, et al. Effect of statin use within the first 24 hours of admission for acute myocardial infarction on early morbidity and mortality. Am J Cardiol 2005; 96:611616.
  18. Heeschen C, Hamm CW, Laufs U, Snapinn S, Bohm M, White HD. Withdrawal of statins increases event rates in patients with acute coronary syndromes. Circulation 2002; 105:14461452.
  19. Kennedy J, Quan H, Buchan AM, Ghali WA, Feasby TE. Statins are associated with better outcomes after carotid endarterectomy in symptomatic patients. Stroke 2005; 36:20722076.
  20. McGirt MJ, Perler BA, Brooke BS, et al. 3-hydroxy-3-methylglutaryl coenzyme A reductase inhibitors reduce the risk of perioperative stroke and mortality after carotid endarterectomy. J Vasc Surg 2005; 42:829836.
  21. Hindler K, Shaw AD, Samuels J, Fulton S, Collard CD, Riedel B. Improved postoperative outcomes associated with preoperative statin therapy. Anesthesiology 2006; 105:12601272.
  22. Kapoor AS, Kanji H, Buckingham J, Devereaux PJ, McAlister FA. Strength of evidence for perioperative use of statins to reduce cardiovascular risk: systematic review of controlled studies. BMJ 2006; 333:1149.
  23. Durazzo AE, Machado FS, Ikeoka DT, et al. Reduction in cardiovascular events after vascular surgery with atorvastatin: a randomized trial. J Vasc Surg 2004; 39:967975.
  24. Grundy SM, Cleeman JI, Merz CN, et al. Implications of recent clinical trials for the National Cholesterol Education Program Adult Treatment Panel III guidelines. Circulation 2004; 110:227239.
  25. Kertai MD, Boersma E, Westerhout CM, et al. A combination of statins and beta-blockers is independently associated with a reduction in the incidence of perioperative mortality and nonfatal myocardial infarction in patients undergoing abdominal aortic aneurysm surgery. Eur J Vasc Endovasc Surg 2004; 28:343352.
  26. Poldermans D, Bax JJ, Kertai MD, et al. Statins are associated with a reduced incidence of perioperative mortality in patients undergoing major noncardiac vascular surgery. Circulation 2003; 107:18481851.
  27. Ward RP, Leeper NJ, Kirkpatrick JN, Lang RM, Sorrentino MJ, Williams KA. The effect of preoperative statin therapy on cardiovascular outcomes in patients undergoing infrainguinal vascular surgery. Int J Cardiol 2005; 104:264268.
  28. O’Neil-Callahan K, Katsimaglis G, Tepper MR, et al. Statins decrease perioperative cardiac complications in patients undergoing non-cardiac vascular surgery: the Statins for Risk Reduction in Surgery (StaRRS) study. J Am Coll Cardiol 2005; 45:336342.
  29. Abbruzzese TA, Havens J, Belkin M, et al. Statin therapy is associated with improved patency of autogenous infrainguinal bypass grafts. J Vasc Surg 2004; 39:11781185.
  30. Boersma E, Poldermans D, Bax JJ, et al. Predictors of cardiac events after major vascular surgery: role of clinical characteristics, dobutamine echocardiography, and beta-blocker therapy. JAMA 2001; 285:18651873.
  31. Landesberg G, Mosseri M, Wolf YG, et al. Preoperative thallium scanning, selective coronary revascularization, and long-term survival after major vascular surgery. Circulation 2003; 108:177183.
  32. Schouten O, Kertai MD, Bax JJ, et al. Safety of perioperative statin use in high-risk patients undergoing major vascular surgery. Am J Cardiol 2005; 95:658660.
  33. Le Manach Y, Godet G, Coriat P, et al. The impact of postoperative discontinuation or continuation of chronic statin therapy on cardiac outcome after major vascular surgery. Anesth Analg 2007; 104:13261333.
  34. Ali IS, Buth KJ. Preoperative statin use and outcomes following cardiac surgery. Int J Cardiol 2005; 103:1218.
  35. Clark LL, Ikonomidis JS, Crawford FA, et al. Preoperative statin treatment is associated with reduced postoperative mortality and morbidity in patients undergoing cardiac surgery: an 8-year retrospective cohort study. J Thorac Cardiovasc Surg 2006; 131:679685.
  36. Pan W, Pintar T, Anton J, Lee VV, Vaughn WK, Collard CD. Statins are associated with a reduced incidence of perioperative mortality after coronary artery bypass graft surgery. Circulation 2004; 110(suppl 2):II45II49.
  37. Pascual DA, Arribas JM, Tornel PL, et al. Preoperative statin therapy and troponin T predict early complications of coronary artery surgery. Ann Thorac Surg 2006; 81:7883.
  38. Dotani MI, Elnicki DM, Jain AC, Gibson CM. Effect of preoperative statin therapy and cardiac outcomes after coronary artery bypass grafting. Am J Cardiol 2000; 86:11281130.
  39. Liakopoulos OJ, Dorge H, Schmitto JD, Nagorsnik U, Grabedunkel J, Schoendube FA. Effects of preoperative statin therapy on cytokines after cardiac surgery. Thorac Cardiovasc Surg 2006; 54:250254.
  40. Christenson JT. Preoperative lipid-control with simvastatin reduces the risk of postoperative thrombocytosis and thrombotic complications following CABG. Eur J Cardiothorac Surg 1999; 15:394399.
  41. Baigent C, Keech A, Kearney PM, et al. Efficacy and safety of cholesterol-lowering treatment: prospective meta-analysis of data from 90,056 participants in 14 randomised trials of statins. Lancet 2005; 366:12671278.
  42. Fleisher LA, Beckman JA, Brown KA, et al. ACC/AHA 2007 Guidelines on Perioperative Cardiovascular Evaluation and Care for Noncardiac Surgery. A Report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines (Writing Committee to Revise the 2002 Guidelines on Perioperative Cardiovascular Evaluation for Noncardiac Surgery). Circulation 2007; 116:e418e499.
  43. Schouten O, Poldermans D, Visser L, et al. Fluvastatin and bisoprolol for the reduction of perioperative cardiac mortality and morbidity in high-risk patients undergoing non-cardiac surgery: rationale and design of the DECREASE-IV study. Am Heart J 2004; 148:10471052.
  44. Amar D, Zhang H, Heerdt PM, Park B, Fleisher M, Thaler HT. Statin use is associated with a reduction in atrial fibrillation after noncardiac thoracic surgery independent of C-reactive protein. Chest 2005; 128:34213427.
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Address: Daniel J. Brotman, MD, Hospitalist Program, Department of Medicine, Johns Hopkins Hospital, Park 307, 600 North Wolfe Street, Baltimore, MD 21287; e-mail [email protected]

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Address: Daniel J. Brotman, MD, Hospitalist Program, Department of Medicine, Johns Hopkins Hospital, Park 307, 600 North Wolfe Street, Baltimore, MD 21287; e-mail [email protected]

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Hospitalist Program, Department of Medicine, Assistant Professor of Internal Medicine and Pediatrics, Johns Hopkins Hospital, Baltimore, MD

Daniel J. Brotman, MD
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Address: Daniel J. Brotman, MD, Hospitalist Program, Department of Medicine, Johns Hopkins Hospital, Park 307, 600 North Wolfe Street, Baltimore, MD 21287; e-mail [email protected]

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Soon, the checklist for internists seeing patients about to undergo surgery may include prescribing one of the lipid-lowering hydroxymethylglutaryl-CoA reductase inhibitors, also called statins.

Statins? Not long ago, we were debating whether patients who take statins should stop taking them before surgery, based on the manufacturers’ recommendations.1 The discussion, however, has changed to whether patients who have never received a statin should be started on one before surgery to provide immediate prophylaxis against cardiac morbidity, and how much harm long-term statin users face if these drugs are withheld perioperatively.

The evidence is still very preliminary and based mostly on studies in animals and retrospective studies in people. However, an expanding body of indirect evidence suggests that these drugs are beneficial in this situation.

In this review, we discuss the mechanisms by which statins may protect the heart in the short term, drawing on data from animal and human studies of acute myocardial infarction, and we review the current (albeit limited) data from the perioperative setting.

FEW INTERVENTIONS DECREASE RISK

Each year, approximately 50,000 patients suffer a perioperative cardiovascular event; the incidence of myocardial infarction during or after noncardiac surgery is 2% to 3%.2 The primary goal of preoperative cardiovascular risk assessment is to predict and avert these events.

But short of canceling surgery, few interventions have been found to reduce a patient’s risk. For example, a landmark study in 2004 cast doubt on the efficacy of preoperative coronary revascularization.3 Similarly, although early studies of beta-blockers were promising4,5 and although most internists prescribe these drugs before surgery, more recent studies have cast doubt on their efficacy, particularly in patients at low risk undergoing intermediate-risk (rather than vascular) surgery.6–8

This changing clinical landscape has prompted a search for new strategies for perioperative risk-reduction. Several recent studies have placed statins in the spotlight.

POTENTIAL MECHANISMS OF SHORT-TERM BENEFIT

Statins have been proven to save lives when used long-term, but how could this class of drugs, designed to prevent the accumulation of arterial plaques by lowering low-density lipoprotein cholesterol (LDL-C) levels, have any short-term impact on operative outcomes? Although LDL-C reduction is the principal mechanism of action of statins, not all of the benefit can be ascribed to this mechanism.9 The answer may lie in their “pleiotropic” effects—ie, actions other than LDL-C reduction.

The more immediate pleiotropic effects of statins in the proinflammatory and prothrombotic environment of the perioperative period are thought to include improved endothelial function (both antithrombotic function and vasomotor function in response to ischemic stress), enhanced stability of atherosclerotic plaques, decreased oxidative stress, and decreased vascular inflammation.10–12

EVIDENCE FROM ANIMAL STUDIES

Experiments in animals suggest that statins, given shortly before or after a cardiovascular event, confer benefit before any changes in LDL-C are measurable.

Lefer et al13 found that simvastatin (Zocor), given 18 hours before an ischemic episode in rats, blunted the inflammatory response in cardiac reperfusion injury. Not only was reperfusion injury significantly less in the hearts of the rats that received simvastatin than in the saline control group, but the simvastatin-treated hearts also expressed fewer neutrophil adhesion molecules such as P-selectin, and they had more basal release of nitric oxide, the potent endothelial-derived vasodilator with antithrombotic, anti-inflammatory, and antiproliferative effects.14 These results suggest that statins may improve endothelial function acutely, particularly during ischemic stress.

Osborne et al15 fed rabbits a cholesterol-rich diet plus either lovastatin (Mevacor) or placebo. After 2 weeks, the rabbits underwent either surgery to induce a myocardial infarction or a sham procedure. Regardless of the pretreatment, biopsies of the aorta did not reveal any atherosclerosis; yet the lovastatin-treated rabbits sustained less myocardial ischemic damage and they had more endothelium-mediated vasodilatation.

Statin therapy also may improve cerebral ischemia outcomes in animal models.14,16

Sironi et al16 induced strokes in rats by occluding the middle cerebral artery. The rats received either simvastatin or vehicle for 3 days before the stroke or immediately afterwards. Even though simvastatin did not have enough time to affect the total cholesterol level, rats treated with simvastatin had smaller infarcts (as measured by magnetic resonance imaging) and produced more nitric oxide.

Comment. Taken together, these studies offer tantalizing evidence that statins have short-term, beneficial nonlipid effects and may reduce not only the likelihood of an ischemic event, but—should one occur—the degree of tissue damage that ensues.

 

 

EFFECTS OF STATINS IN ACUTE CORONARY SYNDROME

The National Registry of Myocardial Infarction17 is a prospective, observational database of all patients with acute myocardial infarction admitted to 1,230 participating hospitals throughout the United States. In an analysis from this cohort, patients were divided into four groups: those receiving statins before and after admission, those receiving statins only before admission, those receiving statins only after admission, and those who never received statins.

Compared with those who never received statins, fewer patients who received them both before and after admission died while in the hospital (unadjusted odds ratio 0.23, 95% confidence interval [CI] 0.22–0.25), and the odds ratio for those who received statins for the first time was 0.31 (95% CI 0.29–0.33). Patients who stopped receiving a statin on admission were more likely to die than were patients who never received statins (odds ratio 1.09, 95% CI 1.03–1.15). These trends held true even when adjustments were made for potential confounding factors.

Comment. Unmeasured confounding factors (such as the inability to take pills due to altered mental status or the different practice styles of the providers who chose to discontinue statins) might have affected the results. Nevertheless, these results suggest that the protective effects of statins stop almost immediately when these drugs are discontinued, and that there may even be an adverse “rebound” effect when patients who have been taking these drugs for a long time stop taking them temporarily.

The Platelet Receptor Inhibition in Ischemic Syndrome Management trial,18 in a subgroup analysis, had nearly identical findings. In the main part of this trial, patients with coronary artery disease and chest pain at rest or accelerating pain in the last 24 hours were randomized to receive tirofiban (Aggrastat) or heparin. Complete data on statin use were available for 1,616 (50%) of the 3,232 patients in this trial, and the rate of the primary end point (death, myocardial infarction, or recurrent ischemia) was analyzed on the basis of statin therapy in this subgroup.

The rate of the combined end point was significantly lower at 48 hours for those who had been receiving statins and continued receiving them (2.6%) than in those who never received statins (5.9%) or in those whose statins were discontinued (10.5%). Statins were more helpful if they were started before hospitalization than if they were started at the time of hospitalization.

Comment. Together, these data lead to the conclusion that, when admitted for either acute myocardial infarction or acute coronary syndrome, patients already receiving statins should not have them stopped, and those who had not been receiving statins should receive them immediately. The safety of these medications in the acute setting appears excellent: in the Myocardial Ischemia Reduction With Acute Cholesterol Lowering (MIRACL)12 and the Pravastatin or Atorvastatin Evaluation and Infection Therapy (PROVE-IT)11 trials, fewer than 5% of statin-treated patients had transient elevations in transaminase levels, and no cases of rhabdomyolysis were reported.

PERIOPERATIVE STATIN STUDIES

The data on perioperative statin use are mostly observational and retrospective and fall into essentially four surgical categories: coronary artery bypass grafting (CABG), carotid endarterectomy,19,20 noncardiac vascular surgery, and major noncardiac surgery. Two meta-analyses have also evaluated the data.21,22 The only randomized controlled trial (performed by Durazzo et al23) was small and was carried out at a single center in vascular surgery patients, and the event rate was low.

Current recommendations from the National Cholesterol Education Program (NCEP)24 say that patients who need CABG, have peripheral arterial disease, have an abdominal aortic aneurysm, or have cerebrovascular disease should already be on a statin to achieve an LDL-C goal level of less than 100 mg/dL, with an optional goal of less than 70 mg/dL, independent of surgery.

Since not all patients who should be on statins are actually on them, questions arise:

  • Is it important (and safe) to start statin treatment preoperatively?
  • Will patients with cardiovascular risk factors but without known cardiovascular disease benefit from statins perioperatively?

Noncardiac vascular surgery

Multiple retrospective studies have evaluated the effect of statins in patients undergoing major noncardiac vascular surgery.25–32

Kertai et al25 evaluated 570 patients in Holland who underwent elective open surgery for infrarenal abdominal aortic aneurysms between 1991 and 2001, looking for an association between statin use and the incidence of perioperative death from myocardial infarction. Only 162 of the 570 patients had been on long-term statin therapy before the surgery. The use of statins was only one of many known baseline characteristics that were significantly different between the two groups, including age, body mass index, known coronary artery disease, and use of angiotensin-converting enzyme inhibitors and beta-blockers. In univariate analysis, statins appeared to be protective: 6 (3.7%) of the patients in the statin group died of a myocardial infarction, compared with 45 (11%) of those in the nostatin group. A multivariate analysis yielded similar findings, with an odds ratio of 0.24 (95% CI 0.11–0.54).

Ward et al27 performed a very similar retrospective study, with similar findings. In 446 patients who underwent surgery for infrarenal abdominal aortic aneurysm, statin therapy was associated with a significantly lower incidence of the combined end point of death, myocardial infarction, stroke, and major peripheral vascular complications, with an adjusted odds ratio of 0.36 (95% CI 0.14–0.93).

Poldermans et al26 noted similar findings in a case-control study of noncardiac vascular surgery patients. Statin users had a much lower perioperative risk of death than did nonusers, with an adjusted odds ratio of 0.22 (95% CI 0.10–0.47).

O’Neil-Callahan et al,28 in a cohort study, found that statin users had fewer perioperative cardiac complications, with an adjusted odds ratio of 0.49 (95% CI 0.28–0.84, P = .009).

 

 

Dogma of withdrawing statins before major surgery is challenged

Le Manach et al33 reviewed the outcomes for all patients of a single hospital in Paris who underwent nonemergency infrarenal aortic procedures between January 2001 and December 2004. In January 2004, the hospital instituted guidelines to ensure that patients on statins continue taking them up to the evening before surgery and that statins be restarted on the first postoperative day (via nasogastric tube if necessary). Before 2004, there had been no specific guidelines, and patients on statins did not receive them for a median of 4 days postoperatively. Types of procedures were similar during the two time periods, as were the rates of beta-blocker use, preoperative revascularization, venous thromboembolism prophylaxis, and perioperative blood pressure control. After surgery, topononin I levels were measured in all patients as surveillance for cardiac events, and were defined as elevated when greater than 0.2 ng/mL.

Compared with patients not on statins at all, those treated with statins continuously throughout the perioperative period (after January 2004) had a lower rate of elevated troponin (relative risk 0.38). In contrast, those who had their statins transiently discontinued perioperatively (prior to 2004) had troponin elevations more often than those who had never been treated (relative risk 2.1). This suggested an over fivefold risk reduction (P < .001) conferred by not discontinuing statins in the immediate postoperative period. This finding was maintained after multivariate adjustment: statin withdrawal was associated with a 2.9-fold (95% CI 1.6–5.5) increase in the risk of cardiac enzyme elevations postoperatively. No fewer deaths were noted, but the study was not powered to detect a mortality difference.

Comment. Although secular trends cannot be entirely discounted as contributing to these findings, the prompt increase in cardiac events after just 4 days of statin withdrawal adds to the growing body of evidence suggesting that statin discontinuation can have harmful acute effects. It also brings up the question: Can starting statins benefit patients in the same time period?

Should statins be started before vascular surgery?

Schouten et al32 evaluated the effects of newly started or continued statin treatment in patients undergoing major elective vascular surgery. Patients were screened before surgery and started on statins if they were not already receiving them and their total cholesterol levels were elevated; new users received the medication for about 40 days before surgery. Of the 981 screened patients, 44 (5%) were newly started on statins and 182 (19%) were continued on their therapy. Perioperative death or myocardial infarction occurred in 22 (8.8%) of the statin users and 111 (14.7%) of the nonusers, a statistically significant difference. Temporary discontinuation (median 1 day) of statins in this study due to the inability to take an oral medication did not appear to affect the likelihood of a myocardial infarction.

Durazzo et al23 performed a single-center, randomized, prospective, placebo-controlled, double-blind clinical trial of atorvastatin (Lipitor) 20 mg daily vs placebo in 100 patients undergoing noncardiac arterial vascular surgery. Patients were excluded if they had previously used medications to treat dyslipidemia, recently had a cardiovascular event, or had contraindications to statin treatment such as a baseline creatinine level greater than 2.0 mg/dL or severe hepatic disease. The intervention group received atorvastatin starting at least 2 weeks before surgery for a total of 45 days. Patients were then continued or started on a statin after surgery if their LDL-C level was greater than 100 mg/dL. Beta-blocker use was recommended “on the basis of current guidelines.”

One month after surgery, the LDL-C level was statistically significantly lower in the atorvastatin group. Since most patients did not continue or start statin therapy after the 45-day treatment period, the LDL-C levels were not statistically different at 3 and 6 months after surgery.

At 6 months, the rate of the primary end point (death from cardiovascular causes, nonfatal acute myocardial infarction, ischemic stroke, or unstable angina) was 26.0% in the placebo group and 8.0% in the atorvastatin group, a statistically significant difference. Three patients in the atorvastatin group had cardiac events in the first 10 days after surgery, compared with 11 patients in the placebo group. Thirteen of the 17 total cardiac events took place within 10 days after surgery.

One of the atorvastatin patients developed rhabdomyolysis and elevated aminotransferase levels.

Major noncardiac surgery

Lindenauer et al2 performed a retrospective cohort study of surgical patients who were at least 18 years old and survived beyond the second hospital day. Patients were divided into a group receiving any form of lipid-lowering treatment (of whom more than 90% were taking statins) and a group that had never never received a lipid-lowering drug or only started one on the third day of the hospitalization or later. The period of study was from January 1, 2000, to December 31, 2001.

In all, 780,591 patients from 329 hospitals throughout the United States were included, of whom only 77,082 (9.9%) received lipid-lowering therapy. Eight percent of the patients underwent vascular surgery. Not surprisingly, the treated patients were more likely to have a history of hypertension, diabetes, ischemic heart disease, or hyperlipidemia. They also were more likely to have a vascular procedure performed, to have two or more cardiac risk factors (high-risk surgery, ischemic heart disease, congestive heart failure, cerebrovascular disease, renal insufficiency, or diabetes mellitus), and to be treated with beta-blockers and angiotensin-converting enzyme inhibitors, but they were less likely to have high-risk and emergency surgery performed.

The primary end point, perioperative death, occurred in 2.13% of the treated patients and 3.05% of the nontreated group. Compared with the rate in a propensity-matched cohort, the odds ratio adjusted for unbalanced covariates was 0.62 (95% CI 0.58–0.67) in favor of lipid treatment. Stratification by cardiac risk index revealed a number needed to treat of 186 for those with no risk factors, 60 for those with two risk factors, and 30 for those with four or more risk factors.

Unfortunately, this analysis was not able to take into account whether and for how long patients were receiving lipid-lowering therapy before hospitalization. It therefore does not answer the questions of whether starting lipid-lowering therapy before surgery is beneficial or whether stopping it is harmful. It also does not shed light on whether perioperative lipid-lowering increases the risk of rhabdomyolysis or liver disease.

 

 

Carotid endarterectomy

Two recent retrospective cohort studies evaluated the outcomes in patients undergoing carotid endarterectomy.19,20

Kennedy et al19 found that patients on a statin at the time of admission who had symptomatic carotid disease had lower rates of inhospital death (adjusted odds ratio 0.24, 95% CI 0.06–0.91) and ischemic stroke or death (adjusted odds ratio 0.55, 95% CI 0.31–0.97). However, cardiac outcomes among these symptomatic patients were not significantly improved (odds ratio 0.82, 95% CI 0.45–1.50), nor was there benefit for asymptomatic patients, raising the possibility that the positive findings were due to chance or that patients at lower baseline risk for vascular events may have less benefit.

McGirt et al20 performed a similar study; they did not, however, distinguish whether patients had symptomatic vs asymptomatic carotid disease. The 30-day risk of perioperative stroke was lower in patients treated with a statin, with an odds ratio of 0.41 (95% CI 0.18–0.93); the odds ratio for death was 0.21 (95% CI 0.05–0.96). Cardiac outcomes were not significantly affected.

Coronary artery bypass graft surgery

According to the NCEP recommendations, nearly all patients undergoing CABG should already be on a statin before surgery since they all have known coronary artery disease. Multiple observational studies have offered confirmatory evidence that statins are beneficial in this setting.34–38

Liakopoulos et al39 evaluated whether the anti-inflammatory effects of statins may, in part, account for their beneficial effect in the perioperative period. The authors prospectively matched 18 patients who were taking statins and were referred for elective CABG with 18 patients who were not prescribed statins previously. The only major measured baseline characteristic that differed between the two groups was a statistically significantly lower LDL-C level in the statin group. The operative characteristics did not differ, and cytokine levels at baseline were similar.

Tumor necrosis factor alpha levels increased significantly in the control group but did not change significantly in the statin group. Interleukin 8 increased in both groups by a similar amount. Interleukin 6 (the major inducer of C-reactive protein) increased from baseline in both groups but did not increase nearly as much in the statin group as in the control group; the intergroup difference was statistically significant. The anti-inflammatory cytokine interleukin 10 increased minimally from baseline in the control group, while the statin group’s levels increased significantly above baseline and those of the control group.

Christenson40 also found that inflammatory markers were improved with pre-CABG statin treatment in a small randomized trial in which patients received simvastatin 20 mg 4 weeks prior to CABG surgery vs no statin. Interestingly, far fewer statin-treated patients developed thrombocytosis (platelet count > 400 × 109/L) than did control patients (3% vs 81%, P < .0001).

RISKS OF PERIOPERATIVE STATINS

The risks associated with statin therapy in general appear low, but specific perioperative risks have not been well studied.

Baigent et al,41 in a meta-analysis of randomized trials of nonperioperative statin therapy, found that rhabdomyolysis occurred in 9 (0.023%) of 39,884 patients receiving statins vs 6 (0.015%) of the 39,817 controls, with a number needed to harm of 12,500. Moreover, the rates of nonvascular death and cancer did not increase. It is plausible that the risk is somewhat greater in the perioperative setting but is likely not enough to outweigh the potential benefits, especially since the risk of ischemic vascular events is particularly high then.

Some of the perioperative studies cited above specifically addressed potential risks. For example, in the study by Schouten et al,32 mild creatine kinase elevations were more common in the statin-treated group, but the incidence of moderate and severe creatine kinase elevations did not differ significantly. No case of rhabdomyolysis occurred, and length of surgery was the only predictor of myopathy. MIRACL and PROVE-IT revealed similar safety profiles; aminotransferase levels normalized when statins were stopped, and no cases of rhabdomyolysis occurred.11,12 In the vascular surgery study by Durazzo et al,23 1 (2%) of the 50 atorvastatin-treated patients developed both rhabdomyolysis and elevated aminotransferase levels that prompted discontinuation of the statin.

Overall, the observational studies do not indicate that statin continuation or treatment is harmful in perioperative patients. However, these studies did not specifically evaluate patients with acute insults from surgery such as sepsis, renal failure, or hepatitis. It is unknown what effect statin therapy would have in those patients and whether statins should be selectively discontinued in patients who develop major hepatic, musculoskeletal, or renal complications after surgery.

 

 

OUR RECOMMENDATIONS

Before CABG or vascular surgery

Given the NCEP recommendations, existing primary and secondary prevention studies, observational studies of CABG and noncardiac vascular surgery patients, and the one randomized trial of vascular surgery patients, data support the use of statins in nearly all patients undergoing cardiac or vascular surgery. We advocate starting statins in the perioperative period to take advantage of their rapid-acting pleiotropic effects, and continuing them long-term to take advantage of their lipid-lowering effects. This recommendation is in line with the recently released American College of Cardiology/American Heart Association (ACC/AHA) 2007 perioperative guidelines that state “for patients undergoing vascular surgery with or without clinical risk factors, statin use is reasonable.”42

Although the ideal time to start statins is not certain, the study by Durazzo et al23 suggests that they should be started at least 2 weeks before surgery if possible. Moreover, patients already taking statins should definitely not have their statins discontinued if at all possible.

Before major nonvascular surgery

For patients undergoing major nonvascular (intermediate-risk) surgery, physicians should first ascertain if the patient has an indication for statin therapy based on current nonsurgical lipid level recommendations. However, even if there is no clear indication for statin therapy based on NCEP guidelines, we endorse the recently released ACC/AHA perioperative guidelines that state that statin therapy can be considered in patients with a risk factor who are undergoing intermediate-risk procedures. Moreover, we wholeheartedly support the ACC/AHA’s strongest recommendation that patients who are already receiving statins and are undergoing noncardiac surgery should not have their statins discontinued.

When to discontinue statins?

The risk of harm overall appears to be minimal and certainly less than the likelihood of benefit. It is reasonable to observe patients postoperatively for adverse clinical events that may increase the risk of perioperative statin treatment, such as acute renal failure, hepatic failure, or sepsis, but whether statins should be stopped in patients with these complications remains unknown; we advocate individualizing the decision.

More studies needed

We need more data on whether moderate-risk patients undergoing moderate-risk surgery benefit from perioperative statin therapy, when therapy should be started, whether therapy should be started on the day of surgery if it was not started earlier, which statin and what doses are optimal, how long therapy should be continued, and what degree of risk is associated with perioperative statin therapy.

Fortunately, important data should be forthcoming in the next few years: the Dutch Echocardiographic Cardiac Risk Evaluation Applying Stress Echocardiography (DECREASE-IV) study43 is a 4-year two-by-two factorial placebo-controlled study evaluating the use of fluvastatin (Lescol) and bisoprolol (Zebeta, a beta-blocker) separately and together in patients who are older than 40 years, are undergoing elective noncardiac surgery, have an estimated risk of cardiovascular death of more than 1%, have not used statins previously, and do not have elevated cholesterol.

Soon, the checklist for internists seeing patients about to undergo surgery may include prescribing one of the lipid-lowering hydroxymethylglutaryl-CoA reductase inhibitors, also called statins.

Statins? Not long ago, we were debating whether patients who take statins should stop taking them before surgery, based on the manufacturers’ recommendations.1 The discussion, however, has changed to whether patients who have never received a statin should be started on one before surgery to provide immediate prophylaxis against cardiac morbidity, and how much harm long-term statin users face if these drugs are withheld perioperatively.

The evidence is still very preliminary and based mostly on studies in animals and retrospective studies in people. However, an expanding body of indirect evidence suggests that these drugs are beneficial in this situation.

In this review, we discuss the mechanisms by which statins may protect the heart in the short term, drawing on data from animal and human studies of acute myocardial infarction, and we review the current (albeit limited) data from the perioperative setting.

FEW INTERVENTIONS DECREASE RISK

Each year, approximately 50,000 patients suffer a perioperative cardiovascular event; the incidence of myocardial infarction during or after noncardiac surgery is 2% to 3%.2 The primary goal of preoperative cardiovascular risk assessment is to predict and avert these events.

But short of canceling surgery, few interventions have been found to reduce a patient’s risk. For example, a landmark study in 2004 cast doubt on the efficacy of preoperative coronary revascularization.3 Similarly, although early studies of beta-blockers were promising4,5 and although most internists prescribe these drugs before surgery, more recent studies have cast doubt on their efficacy, particularly in patients at low risk undergoing intermediate-risk (rather than vascular) surgery.6–8

This changing clinical landscape has prompted a search for new strategies for perioperative risk-reduction. Several recent studies have placed statins in the spotlight.

POTENTIAL MECHANISMS OF SHORT-TERM BENEFIT

Statins have been proven to save lives when used long-term, but how could this class of drugs, designed to prevent the accumulation of arterial plaques by lowering low-density lipoprotein cholesterol (LDL-C) levels, have any short-term impact on operative outcomes? Although LDL-C reduction is the principal mechanism of action of statins, not all of the benefit can be ascribed to this mechanism.9 The answer may lie in their “pleiotropic” effects—ie, actions other than LDL-C reduction.

The more immediate pleiotropic effects of statins in the proinflammatory and prothrombotic environment of the perioperative period are thought to include improved endothelial function (both antithrombotic function and vasomotor function in response to ischemic stress), enhanced stability of atherosclerotic plaques, decreased oxidative stress, and decreased vascular inflammation.10–12

EVIDENCE FROM ANIMAL STUDIES

Experiments in animals suggest that statins, given shortly before or after a cardiovascular event, confer benefit before any changes in LDL-C are measurable.

Lefer et al13 found that simvastatin (Zocor), given 18 hours before an ischemic episode in rats, blunted the inflammatory response in cardiac reperfusion injury. Not only was reperfusion injury significantly less in the hearts of the rats that received simvastatin than in the saline control group, but the simvastatin-treated hearts also expressed fewer neutrophil adhesion molecules such as P-selectin, and they had more basal release of nitric oxide, the potent endothelial-derived vasodilator with antithrombotic, anti-inflammatory, and antiproliferative effects.14 These results suggest that statins may improve endothelial function acutely, particularly during ischemic stress.

Osborne et al15 fed rabbits a cholesterol-rich diet plus either lovastatin (Mevacor) or placebo. After 2 weeks, the rabbits underwent either surgery to induce a myocardial infarction or a sham procedure. Regardless of the pretreatment, biopsies of the aorta did not reveal any atherosclerosis; yet the lovastatin-treated rabbits sustained less myocardial ischemic damage and they had more endothelium-mediated vasodilatation.

Statin therapy also may improve cerebral ischemia outcomes in animal models.14,16

Sironi et al16 induced strokes in rats by occluding the middle cerebral artery. The rats received either simvastatin or vehicle for 3 days before the stroke or immediately afterwards. Even though simvastatin did not have enough time to affect the total cholesterol level, rats treated with simvastatin had smaller infarcts (as measured by magnetic resonance imaging) and produced more nitric oxide.

Comment. Taken together, these studies offer tantalizing evidence that statins have short-term, beneficial nonlipid effects and may reduce not only the likelihood of an ischemic event, but—should one occur—the degree of tissue damage that ensues.

 

 

EFFECTS OF STATINS IN ACUTE CORONARY SYNDROME

The National Registry of Myocardial Infarction17 is a prospective, observational database of all patients with acute myocardial infarction admitted to 1,230 participating hospitals throughout the United States. In an analysis from this cohort, patients were divided into four groups: those receiving statins before and after admission, those receiving statins only before admission, those receiving statins only after admission, and those who never received statins.

Compared with those who never received statins, fewer patients who received them both before and after admission died while in the hospital (unadjusted odds ratio 0.23, 95% confidence interval [CI] 0.22–0.25), and the odds ratio for those who received statins for the first time was 0.31 (95% CI 0.29–0.33). Patients who stopped receiving a statin on admission were more likely to die than were patients who never received statins (odds ratio 1.09, 95% CI 1.03–1.15). These trends held true even when adjustments were made for potential confounding factors.

Comment. Unmeasured confounding factors (such as the inability to take pills due to altered mental status or the different practice styles of the providers who chose to discontinue statins) might have affected the results. Nevertheless, these results suggest that the protective effects of statins stop almost immediately when these drugs are discontinued, and that there may even be an adverse “rebound” effect when patients who have been taking these drugs for a long time stop taking them temporarily.

The Platelet Receptor Inhibition in Ischemic Syndrome Management trial,18 in a subgroup analysis, had nearly identical findings. In the main part of this trial, patients with coronary artery disease and chest pain at rest or accelerating pain in the last 24 hours were randomized to receive tirofiban (Aggrastat) or heparin. Complete data on statin use were available for 1,616 (50%) of the 3,232 patients in this trial, and the rate of the primary end point (death, myocardial infarction, or recurrent ischemia) was analyzed on the basis of statin therapy in this subgroup.

The rate of the combined end point was significantly lower at 48 hours for those who had been receiving statins and continued receiving them (2.6%) than in those who never received statins (5.9%) or in those whose statins were discontinued (10.5%). Statins were more helpful if they were started before hospitalization than if they were started at the time of hospitalization.

Comment. Together, these data lead to the conclusion that, when admitted for either acute myocardial infarction or acute coronary syndrome, patients already receiving statins should not have them stopped, and those who had not been receiving statins should receive them immediately. The safety of these medications in the acute setting appears excellent: in the Myocardial Ischemia Reduction With Acute Cholesterol Lowering (MIRACL)12 and the Pravastatin or Atorvastatin Evaluation and Infection Therapy (PROVE-IT)11 trials, fewer than 5% of statin-treated patients had transient elevations in transaminase levels, and no cases of rhabdomyolysis were reported.

PERIOPERATIVE STATIN STUDIES

The data on perioperative statin use are mostly observational and retrospective and fall into essentially four surgical categories: coronary artery bypass grafting (CABG), carotid endarterectomy,19,20 noncardiac vascular surgery, and major noncardiac surgery. Two meta-analyses have also evaluated the data.21,22 The only randomized controlled trial (performed by Durazzo et al23) was small and was carried out at a single center in vascular surgery patients, and the event rate was low.

Current recommendations from the National Cholesterol Education Program (NCEP)24 say that patients who need CABG, have peripheral arterial disease, have an abdominal aortic aneurysm, or have cerebrovascular disease should already be on a statin to achieve an LDL-C goal level of less than 100 mg/dL, with an optional goal of less than 70 mg/dL, independent of surgery.

Since not all patients who should be on statins are actually on them, questions arise:

  • Is it important (and safe) to start statin treatment preoperatively?
  • Will patients with cardiovascular risk factors but without known cardiovascular disease benefit from statins perioperatively?

Noncardiac vascular surgery

Multiple retrospective studies have evaluated the effect of statins in patients undergoing major noncardiac vascular surgery.25–32

Kertai et al25 evaluated 570 patients in Holland who underwent elective open surgery for infrarenal abdominal aortic aneurysms between 1991 and 2001, looking for an association between statin use and the incidence of perioperative death from myocardial infarction. Only 162 of the 570 patients had been on long-term statin therapy before the surgery. The use of statins was only one of many known baseline characteristics that were significantly different between the two groups, including age, body mass index, known coronary artery disease, and use of angiotensin-converting enzyme inhibitors and beta-blockers. In univariate analysis, statins appeared to be protective: 6 (3.7%) of the patients in the statin group died of a myocardial infarction, compared with 45 (11%) of those in the nostatin group. A multivariate analysis yielded similar findings, with an odds ratio of 0.24 (95% CI 0.11–0.54).

Ward et al27 performed a very similar retrospective study, with similar findings. In 446 patients who underwent surgery for infrarenal abdominal aortic aneurysm, statin therapy was associated with a significantly lower incidence of the combined end point of death, myocardial infarction, stroke, and major peripheral vascular complications, with an adjusted odds ratio of 0.36 (95% CI 0.14–0.93).

Poldermans et al26 noted similar findings in a case-control study of noncardiac vascular surgery patients. Statin users had a much lower perioperative risk of death than did nonusers, with an adjusted odds ratio of 0.22 (95% CI 0.10–0.47).

O’Neil-Callahan et al,28 in a cohort study, found that statin users had fewer perioperative cardiac complications, with an adjusted odds ratio of 0.49 (95% CI 0.28–0.84, P = .009).

 

 

Dogma of withdrawing statins before major surgery is challenged

Le Manach et al33 reviewed the outcomes for all patients of a single hospital in Paris who underwent nonemergency infrarenal aortic procedures between January 2001 and December 2004. In January 2004, the hospital instituted guidelines to ensure that patients on statins continue taking them up to the evening before surgery and that statins be restarted on the first postoperative day (via nasogastric tube if necessary). Before 2004, there had been no specific guidelines, and patients on statins did not receive them for a median of 4 days postoperatively. Types of procedures were similar during the two time periods, as were the rates of beta-blocker use, preoperative revascularization, venous thromboembolism prophylaxis, and perioperative blood pressure control. After surgery, topononin I levels were measured in all patients as surveillance for cardiac events, and were defined as elevated when greater than 0.2 ng/mL.

Compared with patients not on statins at all, those treated with statins continuously throughout the perioperative period (after January 2004) had a lower rate of elevated troponin (relative risk 0.38). In contrast, those who had their statins transiently discontinued perioperatively (prior to 2004) had troponin elevations more often than those who had never been treated (relative risk 2.1). This suggested an over fivefold risk reduction (P < .001) conferred by not discontinuing statins in the immediate postoperative period. This finding was maintained after multivariate adjustment: statin withdrawal was associated with a 2.9-fold (95% CI 1.6–5.5) increase in the risk of cardiac enzyme elevations postoperatively. No fewer deaths were noted, but the study was not powered to detect a mortality difference.

Comment. Although secular trends cannot be entirely discounted as contributing to these findings, the prompt increase in cardiac events after just 4 days of statin withdrawal adds to the growing body of evidence suggesting that statin discontinuation can have harmful acute effects. It also brings up the question: Can starting statins benefit patients in the same time period?

Should statins be started before vascular surgery?

Schouten et al32 evaluated the effects of newly started or continued statin treatment in patients undergoing major elective vascular surgery. Patients were screened before surgery and started on statins if they were not already receiving them and their total cholesterol levels were elevated; new users received the medication for about 40 days before surgery. Of the 981 screened patients, 44 (5%) were newly started on statins and 182 (19%) were continued on their therapy. Perioperative death or myocardial infarction occurred in 22 (8.8%) of the statin users and 111 (14.7%) of the nonusers, a statistically significant difference. Temporary discontinuation (median 1 day) of statins in this study due to the inability to take an oral medication did not appear to affect the likelihood of a myocardial infarction.

Durazzo et al23 performed a single-center, randomized, prospective, placebo-controlled, double-blind clinical trial of atorvastatin (Lipitor) 20 mg daily vs placebo in 100 patients undergoing noncardiac arterial vascular surgery. Patients were excluded if they had previously used medications to treat dyslipidemia, recently had a cardiovascular event, or had contraindications to statin treatment such as a baseline creatinine level greater than 2.0 mg/dL or severe hepatic disease. The intervention group received atorvastatin starting at least 2 weeks before surgery for a total of 45 days. Patients were then continued or started on a statin after surgery if their LDL-C level was greater than 100 mg/dL. Beta-blocker use was recommended “on the basis of current guidelines.”

One month after surgery, the LDL-C level was statistically significantly lower in the atorvastatin group. Since most patients did not continue or start statin therapy after the 45-day treatment period, the LDL-C levels were not statistically different at 3 and 6 months after surgery.

At 6 months, the rate of the primary end point (death from cardiovascular causes, nonfatal acute myocardial infarction, ischemic stroke, or unstable angina) was 26.0% in the placebo group and 8.0% in the atorvastatin group, a statistically significant difference. Three patients in the atorvastatin group had cardiac events in the first 10 days after surgery, compared with 11 patients in the placebo group. Thirteen of the 17 total cardiac events took place within 10 days after surgery.

One of the atorvastatin patients developed rhabdomyolysis and elevated aminotransferase levels.

Major noncardiac surgery

Lindenauer et al2 performed a retrospective cohort study of surgical patients who were at least 18 years old and survived beyond the second hospital day. Patients were divided into a group receiving any form of lipid-lowering treatment (of whom more than 90% were taking statins) and a group that had never never received a lipid-lowering drug or only started one on the third day of the hospitalization or later. The period of study was from January 1, 2000, to December 31, 2001.

In all, 780,591 patients from 329 hospitals throughout the United States were included, of whom only 77,082 (9.9%) received lipid-lowering therapy. Eight percent of the patients underwent vascular surgery. Not surprisingly, the treated patients were more likely to have a history of hypertension, diabetes, ischemic heart disease, or hyperlipidemia. They also were more likely to have a vascular procedure performed, to have two or more cardiac risk factors (high-risk surgery, ischemic heart disease, congestive heart failure, cerebrovascular disease, renal insufficiency, or diabetes mellitus), and to be treated with beta-blockers and angiotensin-converting enzyme inhibitors, but they were less likely to have high-risk and emergency surgery performed.

The primary end point, perioperative death, occurred in 2.13% of the treated patients and 3.05% of the nontreated group. Compared with the rate in a propensity-matched cohort, the odds ratio adjusted for unbalanced covariates was 0.62 (95% CI 0.58–0.67) in favor of lipid treatment. Stratification by cardiac risk index revealed a number needed to treat of 186 for those with no risk factors, 60 for those with two risk factors, and 30 for those with four or more risk factors.

Unfortunately, this analysis was not able to take into account whether and for how long patients were receiving lipid-lowering therapy before hospitalization. It therefore does not answer the questions of whether starting lipid-lowering therapy before surgery is beneficial or whether stopping it is harmful. It also does not shed light on whether perioperative lipid-lowering increases the risk of rhabdomyolysis or liver disease.

 

 

Carotid endarterectomy

Two recent retrospective cohort studies evaluated the outcomes in patients undergoing carotid endarterectomy.19,20

Kennedy et al19 found that patients on a statin at the time of admission who had symptomatic carotid disease had lower rates of inhospital death (adjusted odds ratio 0.24, 95% CI 0.06–0.91) and ischemic stroke or death (adjusted odds ratio 0.55, 95% CI 0.31–0.97). However, cardiac outcomes among these symptomatic patients were not significantly improved (odds ratio 0.82, 95% CI 0.45–1.50), nor was there benefit for asymptomatic patients, raising the possibility that the positive findings were due to chance or that patients at lower baseline risk for vascular events may have less benefit.

McGirt et al20 performed a similar study; they did not, however, distinguish whether patients had symptomatic vs asymptomatic carotid disease. The 30-day risk of perioperative stroke was lower in patients treated with a statin, with an odds ratio of 0.41 (95% CI 0.18–0.93); the odds ratio for death was 0.21 (95% CI 0.05–0.96). Cardiac outcomes were not significantly affected.

Coronary artery bypass graft surgery

According to the NCEP recommendations, nearly all patients undergoing CABG should already be on a statin before surgery since they all have known coronary artery disease. Multiple observational studies have offered confirmatory evidence that statins are beneficial in this setting.34–38

Liakopoulos et al39 evaluated whether the anti-inflammatory effects of statins may, in part, account for their beneficial effect in the perioperative period. The authors prospectively matched 18 patients who were taking statins and were referred for elective CABG with 18 patients who were not prescribed statins previously. The only major measured baseline characteristic that differed between the two groups was a statistically significantly lower LDL-C level in the statin group. The operative characteristics did not differ, and cytokine levels at baseline were similar.

Tumor necrosis factor alpha levels increased significantly in the control group but did not change significantly in the statin group. Interleukin 8 increased in both groups by a similar amount. Interleukin 6 (the major inducer of C-reactive protein) increased from baseline in both groups but did not increase nearly as much in the statin group as in the control group; the intergroup difference was statistically significant. The anti-inflammatory cytokine interleukin 10 increased minimally from baseline in the control group, while the statin group’s levels increased significantly above baseline and those of the control group.

Christenson40 also found that inflammatory markers were improved with pre-CABG statin treatment in a small randomized trial in which patients received simvastatin 20 mg 4 weeks prior to CABG surgery vs no statin. Interestingly, far fewer statin-treated patients developed thrombocytosis (platelet count > 400 × 109/L) than did control patients (3% vs 81%, P < .0001).

RISKS OF PERIOPERATIVE STATINS

The risks associated with statin therapy in general appear low, but specific perioperative risks have not been well studied.

Baigent et al,41 in a meta-analysis of randomized trials of nonperioperative statin therapy, found that rhabdomyolysis occurred in 9 (0.023%) of 39,884 patients receiving statins vs 6 (0.015%) of the 39,817 controls, with a number needed to harm of 12,500. Moreover, the rates of nonvascular death and cancer did not increase. It is plausible that the risk is somewhat greater in the perioperative setting but is likely not enough to outweigh the potential benefits, especially since the risk of ischemic vascular events is particularly high then.

Some of the perioperative studies cited above specifically addressed potential risks. For example, in the study by Schouten et al,32 mild creatine kinase elevations were more common in the statin-treated group, but the incidence of moderate and severe creatine kinase elevations did not differ significantly. No case of rhabdomyolysis occurred, and length of surgery was the only predictor of myopathy. MIRACL and PROVE-IT revealed similar safety profiles; aminotransferase levels normalized when statins were stopped, and no cases of rhabdomyolysis occurred.11,12 In the vascular surgery study by Durazzo et al,23 1 (2%) of the 50 atorvastatin-treated patients developed both rhabdomyolysis and elevated aminotransferase levels that prompted discontinuation of the statin.

Overall, the observational studies do not indicate that statin continuation or treatment is harmful in perioperative patients. However, these studies did not specifically evaluate patients with acute insults from surgery such as sepsis, renal failure, or hepatitis. It is unknown what effect statin therapy would have in those patients and whether statins should be selectively discontinued in patients who develop major hepatic, musculoskeletal, or renal complications after surgery.

 

 

OUR RECOMMENDATIONS

Before CABG or vascular surgery

Given the NCEP recommendations, existing primary and secondary prevention studies, observational studies of CABG and noncardiac vascular surgery patients, and the one randomized trial of vascular surgery patients, data support the use of statins in nearly all patients undergoing cardiac or vascular surgery. We advocate starting statins in the perioperative period to take advantage of their rapid-acting pleiotropic effects, and continuing them long-term to take advantage of their lipid-lowering effects. This recommendation is in line with the recently released American College of Cardiology/American Heart Association (ACC/AHA) 2007 perioperative guidelines that state “for patients undergoing vascular surgery with or without clinical risk factors, statin use is reasonable.”42

Although the ideal time to start statins is not certain, the study by Durazzo et al23 suggests that they should be started at least 2 weeks before surgery if possible. Moreover, patients already taking statins should definitely not have their statins discontinued if at all possible.

Before major nonvascular surgery

For patients undergoing major nonvascular (intermediate-risk) surgery, physicians should first ascertain if the patient has an indication for statin therapy based on current nonsurgical lipid level recommendations. However, even if there is no clear indication for statin therapy based on NCEP guidelines, we endorse the recently released ACC/AHA perioperative guidelines that state that statin therapy can be considered in patients with a risk factor who are undergoing intermediate-risk procedures. Moreover, we wholeheartedly support the ACC/AHA’s strongest recommendation that patients who are already receiving statins and are undergoing noncardiac surgery should not have their statins discontinued.

When to discontinue statins?

The risk of harm overall appears to be minimal and certainly less than the likelihood of benefit. It is reasonable to observe patients postoperatively for adverse clinical events that may increase the risk of perioperative statin treatment, such as acute renal failure, hepatic failure, or sepsis, but whether statins should be stopped in patients with these complications remains unknown; we advocate individualizing the decision.

More studies needed

We need more data on whether moderate-risk patients undergoing moderate-risk surgery benefit from perioperative statin therapy, when therapy should be started, whether therapy should be started on the day of surgery if it was not started earlier, which statin and what doses are optimal, how long therapy should be continued, and what degree of risk is associated with perioperative statin therapy.

Fortunately, important data should be forthcoming in the next few years: the Dutch Echocardiographic Cardiac Risk Evaluation Applying Stress Echocardiography (DECREASE-IV) study43 is a 4-year two-by-two factorial placebo-controlled study evaluating the use of fluvastatin (Lescol) and bisoprolol (Zebeta, a beta-blocker) separately and together in patients who are older than 40 years, are undergoing elective noncardiac surgery, have an estimated risk of cardiovascular death of more than 1%, have not used statins previously, and do not have elevated cholesterol.

References
  1. Grant PJ, Kedia N. Should statins be discontinued preoperatively? IMPACT consults. Proceedings of the 2nd Annual Cleveland Clinic Perioperative Medicine Summit. Cleve Clin J Med 2006; 73 Electronic suppl 1:S9S10.
  2. Lindenauer PK, Pekow P, Wang K, Gutierrez B, Benjamin EM. Lipid-lowering therapy and in-hospital mortality following major noncardiac surgery. JAMA 2004; 291:20922099.
  3. McFalls EO, Ward HB, Moritz TE, et al. Coronary-artery revascularization before elective major vascular surgery. N Engl J Med 2004; 351:27952804.
  4. Mangano DT, Layug EL, Wallace A, Tateo I. Effect of atenolol on mortality and cardiovascular morbidity after noncardiac surgery. Multicenter Study of Perioperative Ischemia Research Group. N Engl J Med 1996; 335:17131720.
  5. Poldermans D, Boersma E, Bax JJ, et al. The effect of bisoprolol on perioperative mortality and myocardial infarction in high-risk patients undergoing vascular surgery. Dutch Echocardiographic Cardiac Risk Evaluation Applying Stress Echocardiography Study Group. N Engl J Med 1999; 341:17891794.
  6. Brady AR, Gibbs JS, Greenhalgh RM, Powell JT, Sydes MR. Perioperative beta-blockade (POBBLE) for patients undergoing infrarenal vascular surgery: results of a randomized double-blind controlled trial. J Vasc Surg 2005; 41:602609.
  7. Juul AB, Wetterslev J, Gluud C, et al. Effect of perioperative beta blockade in patients with diabetes undergoing major non-cardiac surgery: randomised placebo controlled, blinded multicentre trial. BMJ 2006; 332:1482.
  8. Yang H, Raymer K, Butler R, Parlow J, Roberts R. The effects of perioperative beta-blockade: results of the Metoprolol after Vascular Surgery (MaVS) study, a randomized controlled trial. Am Heart J 2006; 152:983990.
  9. Ridker PM, Cannon CP, Morrow D, et al. C-reactive protein levels and outcomes after statin therapy. N Engl J Med 2005; 352:2028.
  10. Ito MK, Talbert RL, Tsimikas S. Statin-associated pleiotropy: possible beneficial effects beyond cholesterol reduction. Pharmacotherapy 2006; 26:85S97S.
  11. Cannon CP, Braunwald E, McCabe CH, et al. Intensive versus moderate lipid lowering with statins after acute coronary syndromes. N Engl J Med 2004; 350:14951504.
  12. Schwartz GG, Olsson AG, Ezekowitz MD, et al. Effects of atorvastatin on early recurrent ischemic events in acute coronary syndromes: the MIRACL study: a randomized controlled trial. JAMA 2001; 285:17111718.
  13. Lefer AM, Campbell B, Shin YK, Scalia R, Hayward R, Lefer DJ. Simvastatin preserves the ischemic-reperfused myocardium in normocholesterolemic rat hearts. Circulation 1999; 100:178184.
  14. Endres M, Laufs U, Liao JK, Moskowitz MA. Targeting eNOS for stroke protection. Trends Neurosci 2004; 27:283289.
  15. Osborne JA, Lento PH, Siegfried MR, Stahl GL, Fusman B, Lefer AM. Cardiovascular effects of acute hypercholesterolemia in rabbits. Reversal with lovastatin treatment. J Clin Invest 1989; 83:465473.
  16. Sironi L, Cimino M, Guerrini U, et al. Treatment with statins after induction of focal ischemia in rats reduces the extent of brain damage. Arterioscler Thromb Vasc Biol 2003; 23:322327.
  17. Fonarow GC, Wright RS, Spencer FA, et al. Effect of statin use within the first 24 hours of admission for acute myocardial infarction on early morbidity and mortality. Am J Cardiol 2005; 96:611616.
  18. Heeschen C, Hamm CW, Laufs U, Snapinn S, Bohm M, White HD. Withdrawal of statins increases event rates in patients with acute coronary syndromes. Circulation 2002; 105:14461452.
  19. Kennedy J, Quan H, Buchan AM, Ghali WA, Feasby TE. Statins are associated with better outcomes after carotid endarterectomy in symptomatic patients. Stroke 2005; 36:20722076.
  20. McGirt MJ, Perler BA, Brooke BS, et al. 3-hydroxy-3-methylglutaryl coenzyme A reductase inhibitors reduce the risk of perioperative stroke and mortality after carotid endarterectomy. J Vasc Surg 2005; 42:829836.
  21. Hindler K, Shaw AD, Samuels J, Fulton S, Collard CD, Riedel B. Improved postoperative outcomes associated with preoperative statin therapy. Anesthesiology 2006; 105:12601272.
  22. Kapoor AS, Kanji H, Buckingham J, Devereaux PJ, McAlister FA. Strength of evidence for perioperative use of statins to reduce cardiovascular risk: systematic review of controlled studies. BMJ 2006; 333:1149.
  23. Durazzo AE, Machado FS, Ikeoka DT, et al. Reduction in cardiovascular events after vascular surgery with atorvastatin: a randomized trial. J Vasc Surg 2004; 39:967975.
  24. Grundy SM, Cleeman JI, Merz CN, et al. Implications of recent clinical trials for the National Cholesterol Education Program Adult Treatment Panel III guidelines. Circulation 2004; 110:227239.
  25. Kertai MD, Boersma E, Westerhout CM, et al. A combination of statins and beta-blockers is independently associated with a reduction in the incidence of perioperative mortality and nonfatal myocardial infarction in patients undergoing abdominal aortic aneurysm surgery. Eur J Vasc Endovasc Surg 2004; 28:343352.
  26. Poldermans D, Bax JJ, Kertai MD, et al. Statins are associated with a reduced incidence of perioperative mortality in patients undergoing major noncardiac vascular surgery. Circulation 2003; 107:18481851.
  27. Ward RP, Leeper NJ, Kirkpatrick JN, Lang RM, Sorrentino MJ, Williams KA. The effect of preoperative statin therapy on cardiovascular outcomes in patients undergoing infrainguinal vascular surgery. Int J Cardiol 2005; 104:264268.
  28. O’Neil-Callahan K, Katsimaglis G, Tepper MR, et al. Statins decrease perioperative cardiac complications in patients undergoing non-cardiac vascular surgery: the Statins for Risk Reduction in Surgery (StaRRS) study. J Am Coll Cardiol 2005; 45:336342.
  29. Abbruzzese TA, Havens J, Belkin M, et al. Statin therapy is associated with improved patency of autogenous infrainguinal bypass grafts. J Vasc Surg 2004; 39:11781185.
  30. Boersma E, Poldermans D, Bax JJ, et al. Predictors of cardiac events after major vascular surgery: role of clinical characteristics, dobutamine echocardiography, and beta-blocker therapy. JAMA 2001; 285:18651873.
  31. Landesberg G, Mosseri M, Wolf YG, et al. Preoperative thallium scanning, selective coronary revascularization, and long-term survival after major vascular surgery. Circulation 2003; 108:177183.
  32. Schouten O, Kertai MD, Bax JJ, et al. Safety of perioperative statin use in high-risk patients undergoing major vascular surgery. Am J Cardiol 2005; 95:658660.
  33. Le Manach Y, Godet G, Coriat P, et al. The impact of postoperative discontinuation or continuation of chronic statin therapy on cardiac outcome after major vascular surgery. Anesth Analg 2007; 104:13261333.
  34. Ali IS, Buth KJ. Preoperative statin use and outcomes following cardiac surgery. Int J Cardiol 2005; 103:1218.
  35. Clark LL, Ikonomidis JS, Crawford FA, et al. Preoperative statin treatment is associated with reduced postoperative mortality and morbidity in patients undergoing cardiac surgery: an 8-year retrospective cohort study. J Thorac Cardiovasc Surg 2006; 131:679685.
  36. Pan W, Pintar T, Anton J, Lee VV, Vaughn WK, Collard CD. Statins are associated with a reduced incidence of perioperative mortality after coronary artery bypass graft surgery. Circulation 2004; 110(suppl 2):II45II49.
  37. Pascual DA, Arribas JM, Tornel PL, et al. Preoperative statin therapy and troponin T predict early complications of coronary artery surgery. Ann Thorac Surg 2006; 81:7883.
  38. Dotani MI, Elnicki DM, Jain AC, Gibson CM. Effect of preoperative statin therapy and cardiac outcomes after coronary artery bypass grafting. Am J Cardiol 2000; 86:11281130.
  39. Liakopoulos OJ, Dorge H, Schmitto JD, Nagorsnik U, Grabedunkel J, Schoendube FA. Effects of preoperative statin therapy on cytokines after cardiac surgery. Thorac Cardiovasc Surg 2006; 54:250254.
  40. Christenson JT. Preoperative lipid-control with simvastatin reduces the risk of postoperative thrombocytosis and thrombotic complications following CABG. Eur J Cardiothorac Surg 1999; 15:394399.
  41. Baigent C, Keech A, Kearney PM, et al. Efficacy and safety of cholesterol-lowering treatment: prospective meta-analysis of data from 90,056 participants in 14 randomised trials of statins. Lancet 2005; 366:12671278.
  42. Fleisher LA, Beckman JA, Brown KA, et al. ACC/AHA 2007 Guidelines on Perioperative Cardiovascular Evaluation and Care for Noncardiac Surgery. A Report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines (Writing Committee to Revise the 2002 Guidelines on Perioperative Cardiovascular Evaluation for Noncardiac Surgery). Circulation 2007; 116:e418e499.
  43. Schouten O, Poldermans D, Visser L, et al. Fluvastatin and bisoprolol for the reduction of perioperative cardiac mortality and morbidity in high-risk patients undergoing non-cardiac surgery: rationale and design of the DECREASE-IV study. Am Heart J 2004; 148:10471052.
  44. Amar D, Zhang H, Heerdt PM, Park B, Fleisher M, Thaler HT. Statin use is associated with a reduction in atrial fibrillation after noncardiac thoracic surgery independent of C-reactive protein. Chest 2005; 128:34213427.
References
  1. Grant PJ, Kedia N. Should statins be discontinued preoperatively? IMPACT consults. Proceedings of the 2nd Annual Cleveland Clinic Perioperative Medicine Summit. Cleve Clin J Med 2006; 73 Electronic suppl 1:S9S10.
  2. Lindenauer PK, Pekow P, Wang K, Gutierrez B, Benjamin EM. Lipid-lowering therapy and in-hospital mortality following major noncardiac surgery. JAMA 2004; 291:20922099.
  3. McFalls EO, Ward HB, Moritz TE, et al. Coronary-artery revascularization before elective major vascular surgery. N Engl J Med 2004; 351:27952804.
  4. Mangano DT, Layug EL, Wallace A, Tateo I. Effect of atenolol on mortality and cardiovascular morbidity after noncardiac surgery. Multicenter Study of Perioperative Ischemia Research Group. N Engl J Med 1996; 335:17131720.
  5. Poldermans D, Boersma E, Bax JJ, et al. The effect of bisoprolol on perioperative mortality and myocardial infarction in high-risk patients undergoing vascular surgery. Dutch Echocardiographic Cardiac Risk Evaluation Applying Stress Echocardiography Study Group. N Engl J Med 1999; 341:17891794.
  6. Brady AR, Gibbs JS, Greenhalgh RM, Powell JT, Sydes MR. Perioperative beta-blockade (POBBLE) for patients undergoing infrarenal vascular surgery: results of a randomized double-blind controlled trial. J Vasc Surg 2005; 41:602609.
  7. Juul AB, Wetterslev J, Gluud C, et al. Effect of perioperative beta blockade in patients with diabetes undergoing major non-cardiac surgery: randomised placebo controlled, blinded multicentre trial. BMJ 2006; 332:1482.
  8. Yang H, Raymer K, Butler R, Parlow J, Roberts R. The effects of perioperative beta-blockade: results of the Metoprolol after Vascular Surgery (MaVS) study, a randomized controlled trial. Am Heart J 2006; 152:983990.
  9. Ridker PM, Cannon CP, Morrow D, et al. C-reactive protein levels and outcomes after statin therapy. N Engl J Med 2005; 352:2028.
  10. Ito MK, Talbert RL, Tsimikas S. Statin-associated pleiotropy: possible beneficial effects beyond cholesterol reduction. Pharmacotherapy 2006; 26:85S97S.
  11. Cannon CP, Braunwald E, McCabe CH, et al. Intensive versus moderate lipid lowering with statins after acute coronary syndromes. N Engl J Med 2004; 350:14951504.
  12. Schwartz GG, Olsson AG, Ezekowitz MD, et al. Effects of atorvastatin on early recurrent ischemic events in acute coronary syndromes: the MIRACL study: a randomized controlled trial. JAMA 2001; 285:17111718.
  13. Lefer AM, Campbell B, Shin YK, Scalia R, Hayward R, Lefer DJ. Simvastatin preserves the ischemic-reperfused myocardium in normocholesterolemic rat hearts. Circulation 1999; 100:178184.
  14. Endres M, Laufs U, Liao JK, Moskowitz MA. Targeting eNOS for stroke protection. Trends Neurosci 2004; 27:283289.
  15. Osborne JA, Lento PH, Siegfried MR, Stahl GL, Fusman B, Lefer AM. Cardiovascular effects of acute hypercholesterolemia in rabbits. Reversal with lovastatin treatment. J Clin Invest 1989; 83:465473.
  16. Sironi L, Cimino M, Guerrini U, et al. Treatment with statins after induction of focal ischemia in rats reduces the extent of brain damage. Arterioscler Thromb Vasc Biol 2003; 23:322327.
  17. Fonarow GC, Wright RS, Spencer FA, et al. Effect of statin use within the first 24 hours of admission for acute myocardial infarction on early morbidity and mortality. Am J Cardiol 2005; 96:611616.
  18. Heeschen C, Hamm CW, Laufs U, Snapinn S, Bohm M, White HD. Withdrawal of statins increases event rates in patients with acute coronary syndromes. Circulation 2002; 105:14461452.
  19. Kennedy J, Quan H, Buchan AM, Ghali WA, Feasby TE. Statins are associated with better outcomes after carotid endarterectomy in symptomatic patients. Stroke 2005; 36:20722076.
  20. McGirt MJ, Perler BA, Brooke BS, et al. 3-hydroxy-3-methylglutaryl coenzyme A reductase inhibitors reduce the risk of perioperative stroke and mortality after carotid endarterectomy. J Vasc Surg 2005; 42:829836.
  21. Hindler K, Shaw AD, Samuels J, Fulton S, Collard CD, Riedel B. Improved postoperative outcomes associated with preoperative statin therapy. Anesthesiology 2006; 105:12601272.
  22. Kapoor AS, Kanji H, Buckingham J, Devereaux PJ, McAlister FA. Strength of evidence for perioperative use of statins to reduce cardiovascular risk: systematic review of controlled studies. BMJ 2006; 333:1149.
  23. Durazzo AE, Machado FS, Ikeoka DT, et al. Reduction in cardiovascular events after vascular surgery with atorvastatin: a randomized trial. J Vasc Surg 2004; 39:967975.
  24. Grundy SM, Cleeman JI, Merz CN, et al. Implications of recent clinical trials for the National Cholesterol Education Program Adult Treatment Panel III guidelines. Circulation 2004; 110:227239.
  25. Kertai MD, Boersma E, Westerhout CM, et al. A combination of statins and beta-blockers is independently associated with a reduction in the incidence of perioperative mortality and nonfatal myocardial infarction in patients undergoing abdominal aortic aneurysm surgery. Eur J Vasc Endovasc Surg 2004; 28:343352.
  26. Poldermans D, Bax JJ, Kertai MD, et al. Statins are associated with a reduced incidence of perioperative mortality in patients undergoing major noncardiac vascular surgery. Circulation 2003; 107:18481851.
  27. Ward RP, Leeper NJ, Kirkpatrick JN, Lang RM, Sorrentino MJ, Williams KA. The effect of preoperative statin therapy on cardiovascular outcomes in patients undergoing infrainguinal vascular surgery. Int J Cardiol 2005; 104:264268.
  28. O’Neil-Callahan K, Katsimaglis G, Tepper MR, et al. Statins decrease perioperative cardiac complications in patients undergoing non-cardiac vascular surgery: the Statins for Risk Reduction in Surgery (StaRRS) study. J Am Coll Cardiol 2005; 45:336342.
  29. Abbruzzese TA, Havens J, Belkin M, et al. Statin therapy is associated with improved patency of autogenous infrainguinal bypass grafts. J Vasc Surg 2004; 39:11781185.
  30. Boersma E, Poldermans D, Bax JJ, et al. Predictors of cardiac events after major vascular surgery: role of clinical characteristics, dobutamine echocardiography, and beta-blocker therapy. JAMA 2001; 285:18651873.
  31. Landesberg G, Mosseri M, Wolf YG, et al. Preoperative thallium scanning, selective coronary revascularization, and long-term survival after major vascular surgery. Circulation 2003; 108:177183.
  32. Schouten O, Kertai MD, Bax JJ, et al. Safety of perioperative statin use in high-risk patients undergoing major vascular surgery. Am J Cardiol 2005; 95:658660.
  33. Le Manach Y, Godet G, Coriat P, et al. The impact of postoperative discontinuation or continuation of chronic statin therapy on cardiac outcome after major vascular surgery. Anesth Analg 2007; 104:13261333.
  34. Ali IS, Buth KJ. Preoperative statin use and outcomes following cardiac surgery. Int J Cardiol 2005; 103:1218.
  35. Clark LL, Ikonomidis JS, Crawford FA, et al. Preoperative statin treatment is associated with reduced postoperative mortality and morbidity in patients undergoing cardiac surgery: an 8-year retrospective cohort study. J Thorac Cardiovasc Surg 2006; 131:679685.
  36. Pan W, Pintar T, Anton J, Lee VV, Vaughn WK, Collard CD. Statins are associated with a reduced incidence of perioperative mortality after coronary artery bypass graft surgery. Circulation 2004; 110(suppl 2):II45II49.
  37. Pascual DA, Arribas JM, Tornel PL, et al. Preoperative statin therapy and troponin T predict early complications of coronary artery surgery. Ann Thorac Surg 2006; 81:7883.
  38. Dotani MI, Elnicki DM, Jain AC, Gibson CM. Effect of preoperative statin therapy and cardiac outcomes after coronary artery bypass grafting. Am J Cardiol 2000; 86:11281130.
  39. Liakopoulos OJ, Dorge H, Schmitto JD, Nagorsnik U, Grabedunkel J, Schoendube FA. Effects of preoperative statin therapy on cytokines after cardiac surgery. Thorac Cardiovasc Surg 2006; 54:250254.
  40. Christenson JT. Preoperative lipid-control with simvastatin reduces the risk of postoperative thrombocytosis and thrombotic complications following CABG. Eur J Cardiothorac Surg 1999; 15:394399.
  41. Baigent C, Keech A, Kearney PM, et al. Efficacy and safety of cholesterol-lowering treatment: prospective meta-analysis of data from 90,056 participants in 14 randomised trials of statins. Lancet 2005; 366:12671278.
  42. Fleisher LA, Beckman JA, Brown KA, et al. ACC/AHA 2007 Guidelines on Perioperative Cardiovascular Evaluation and Care for Noncardiac Surgery. A Report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines (Writing Committee to Revise the 2002 Guidelines on Perioperative Cardiovascular Evaluation for Noncardiac Surgery). Circulation 2007; 116:e418e499.
  43. Schouten O, Poldermans D, Visser L, et al. Fluvastatin and bisoprolol for the reduction of perioperative cardiac mortality and morbidity in high-risk patients undergoing non-cardiac surgery: rationale and design of the DECREASE-IV study. Am Heart J 2004; 148:10471052.
  44. Amar D, Zhang H, Heerdt PM, Park B, Fleisher M, Thaler HT. Statin use is associated with a reduction in atrial fibrillation after noncardiac thoracic surgery independent of C-reactive protein. Chest 2005; 128:34213427.
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KEY POINTS

  • Experiments in animals suggest that statins, given shortly before or after a cardiovascular event, confer benefit before any changes in lipids are measurable.
  • Retrospective and prospective studies indicate that patients with either acute myocardial infarction or acute coronary syndrome who are already receiving statins should not have them stopped, and those who had not been receiving statins should receive them immediately.
  • Most patients undergoing coronary artery bypass grafting or noncardiac vascular surgery should already be receiving a statin. These drugs can also be considered in patients undergoing intermediate-risk nonvascular surgery. Patients who have been receiving statins prior to surgery should not have them stopped for surgery.
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And then there were none? An internist’s reflections

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Brian F. Mandell, MD, PhD

When I am out lecturing, sitting with colleagues, or chatting with patients about their experiences and relationships with physicians, some allusion to the changing face of medical care invariably crops up. This often translates into a discussion of the forces driving the devaluation of the physician-patient relationship and the eroding satisfaction of physicians with their professional lives. This topic has even hit the New York Times (July 21, and in Letters to the Editor, July 27).

I observe with sadness the decreasing number of our brightest medical students entering into internal medicine careers and other “cognitive” subspecialties. Much effort has been spent on many fronts to understand and reverse this trend, with limited success.

At the other end of their careers, physicians seem to be looking for ways to retire earlier or to withdraw from their usual and customary practice of internal medicine. Hearing these senior physicians’ reasons for withdrawing from clinical practice evokes an even stronger response in me, especially when the physician is a really good one, a role model for the next generation of our internists currently in training.

In an essay in this issue, Dr. Thomas Lansdale, internist and former chairman of medicine at a community teaching hospital, eloquently expresses a common theme: medicine just isn’t that much fun anymore. We don’t generally run this type of article in the Journal. But Dr. Lansdale’s words reflect an undercurrent that is changing the landscape of American medicine. We would like to hear responses from our readers, but not to simply agree or disagree with Dr. Lansdale. Rather, we’d like to hear some solutions, which we hope to print in a future issue.

I have known Dr. Lansdale for over 20 years; we trained together as residents at the University of Pennsylvania. He was a year or so behind me, and over the years I have had the opportunity to follow his clinical career from afar and occasionally to discuss patient care and education issues. He was (and is) a thoughtful and extremely insightful internist, devoted and capable of delivering the highest quality of care to his patients. He has always approached medicine, his trainees, and his patients in a serious and respectful manner. His words should prompt some serious self-reflection.

Send your comments to [email protected]. Please note that sending your comments constitutes permission to publish them, and also that we cannot respond to or publish all submissions.

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A medical center is not a hospital

When I am out lecturing, sitting with colleagues, or chatting with patients about their experiences and relationships with physicians, some allusion to the changing face of medical care invariably crops up. This often translates into a discussion of the forces driving the devaluation of the physician-patient relationship and the eroding satisfaction of physicians with their professional lives. This topic has even hit the New York Times (July 21, and in Letters to the Editor, July 27).

I observe with sadness the decreasing number of our brightest medical students entering into internal medicine careers and other “cognitive” subspecialties. Much effort has been spent on many fronts to understand and reverse this trend, with limited success.

At the other end of their careers, physicians seem to be looking for ways to retire earlier or to withdraw from their usual and customary practice of internal medicine. Hearing these senior physicians’ reasons for withdrawing from clinical practice evokes an even stronger response in me, especially when the physician is a really good one, a role model for the next generation of our internists currently in training.

In an essay in this issue, Dr. Thomas Lansdale, internist and former chairman of medicine at a community teaching hospital, eloquently expresses a common theme: medicine just isn’t that much fun anymore. We don’t generally run this type of article in the Journal. But Dr. Lansdale’s words reflect an undercurrent that is changing the landscape of American medicine. We would like to hear responses from our readers, but not to simply agree or disagree with Dr. Lansdale. Rather, we’d like to hear some solutions, which we hope to print in a future issue.

I have known Dr. Lansdale for over 20 years; we trained together as residents at the University of Pennsylvania. He was a year or so behind me, and over the years I have had the opportunity to follow his clinical career from afar and occasionally to discuss patient care and education issues. He was (and is) a thoughtful and extremely insightful internist, devoted and capable of delivering the highest quality of care to his patients. He has always approached medicine, his trainees, and his patients in a serious and respectful manner. His words should prompt some serious self-reflection.

Send your comments to [email protected]. Please note that sending your comments constitutes permission to publish them, and also that we cannot respond to or publish all submissions.

When I am out lecturing, sitting with colleagues, or chatting with patients about their experiences and relationships with physicians, some allusion to the changing face of medical care invariably crops up. This often translates into a discussion of the forces driving the devaluation of the physician-patient relationship and the eroding satisfaction of physicians with their professional lives. This topic has even hit the New York Times (July 21, and in Letters to the Editor, July 27).

I observe with sadness the decreasing number of our brightest medical students entering into internal medicine careers and other “cognitive” subspecialties. Much effort has been spent on many fronts to understand and reverse this trend, with limited success.

At the other end of their careers, physicians seem to be looking for ways to retire earlier or to withdraw from their usual and customary practice of internal medicine. Hearing these senior physicians’ reasons for withdrawing from clinical practice evokes an even stronger response in me, especially when the physician is a really good one, a role model for the next generation of our internists currently in training.

In an essay in this issue, Dr. Thomas Lansdale, internist and former chairman of medicine at a community teaching hospital, eloquently expresses a common theme: medicine just isn’t that much fun anymore. We don’t generally run this type of article in the Journal. But Dr. Lansdale’s words reflect an undercurrent that is changing the landscape of American medicine. We would like to hear responses from our readers, but not to simply agree or disagree with Dr. Lansdale. Rather, we’d like to hear some solutions, which we hope to print in a future issue.

I have known Dr. Lansdale for over 20 years; we trained together as residents at the University of Pennsylvania. He was a year or so behind me, and over the years I have had the opportunity to follow his clinical career from afar and occasionally to discuss patient care and education issues. He was (and is) a thoughtful and extremely insightful internist, devoted and capable of delivering the highest quality of care to his patients. He has always approached medicine, his trainees, and his patients in a serious and respectful manner. His words should prompt some serious self-reflection.

Send your comments to [email protected]. Please note that sending your comments constitutes permission to publish them, and also that we cannot respond to or publish all submissions.

Issue
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And then there were none? An internist’s reflections
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A case of refractory diarrhea

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Jennifer Monti, BA
J. Harry Isaacson, MD
Bret Lashner, MD

A 68-year-old white woman with irritable bowel syndrome has had worsening symptoms of right-sided abdominal pain, excessive bloating, and loose stools. Her bowel movements have increased from one a day to two or three a day. She has not noted any mucus or blood in the stool. She cannot identify any alleviating or aggravating factors, and the pain is not related to eating.

She consumes a normal diet, including meat and dairy. Over-the-counter antidiarrheal medications do not relieve the symptoms. She has had no fevers, chills, or night sweats, and she has not lost weight over the past year.

Her medical history includes breast cancer (in remission), alcohol abuse (in remission), and hypothyroidism, osteoporosis, and supraventricular tachycardia, all controlled with treatment as noted below. She has never undergone abdominal surgery.

A general review of systems is normal. Her current medications include oxybutynin (available as Ditropan, others), calcium polycarbophil (FiberCon, others), risedronate (Actonel), levothyroxine (Synthroid, others), simethicone (Maalox Anti-Gas, others), atenolol (Tenormin), trazodone (Desyrel), a calcium supplement, and aspirin. She began taking duloxetine (Cymbalta) 18 months ago, and the dose was increased from 60 mg to 90 mg 1 week before this visit.

She has never smoked, and she has abstained from alcohol for 10 years. She has no family history of colon cancer, celiac disease, or inflammatory bowel disease. She has not traveled outside the country in the past several years, and she notes no change in her source of drinking water.

On physical examination, she does not appear to be in acute distress. Her pulse is 64 and her blood pressure is 112/78 mm Hg. The cardiopulmonary examination is normal. Her abdomen is soft, symmetrical, nondistended, and nontender. Bowel sounds are normal. No abdominal masses, palpable organomegaly, or abdominal bruits are noted.

Results of basic laboratory tests, including thyroid-stimulating hormone (TSH), complete blood count, blood chemistries, renal function, and liver function, are normal. Colonoscopy shows normal mucosa as far as the cecum.

DIFFERENTIAL DIAGNOSIS

1. In addition to irritable bowel syndrome, which of these can explain her symptoms?

  • Ulcerative colitis
  • Celiac disease
  • Microscopic colitis
  • Hyperthyroidism
  • Lactase deficiency

Ulcerative colitis typically presents with blood and mucus in the stool and gross abnormalities on colonoscopy, none of which is present in this patient.

Hyperthyroidism can be ruled out by the normal TSH level.

Lactase deficiency or lactose intolerance is unlikely because it is present in only 15% of people of northern European descent (compared with 80% of blacks and Hispanics and up to 100% of Native Americans and Asians).1 Furthermore, her pain is apparently not related to consuming dairy products.

The hydrogen breath test can aid in the diagnosis of lactase deficiency. This test relies on the breakdown of malabsorbed lactose by colonic flora. This is the most widely used test for this deficiency, but its high false-negative rate of 25% means that a negative result does not exclude the diagnosis and should not be relied on in working up a patient with chronic diarrhea.2 Simply noting whether symptoms develop after ingesting 50 g of lactose is clinically useful when lactase deficiency is suspected.

Based on the information so far, it is reasonable in this patient to evaluate for celiac disease and for microscopic colitis.

Celiac disease, also called gluten-sensitive enteropathy, has a varied presentation that includes nonspecific symptoms such as those in this patient. Classically, it causes diarrhea, but patients may present with a single nutrient deficiency and no diarrhea.

This patient lacks the elevated alkaline phosphatase or evidence of vitamin deficiencies characteristic of malabsorption in celiac disease (ie, vitamins A, B12, D, K, and folate)3. She also lacks evidence of malnutrition, such as iron deficiency anemia, weight loss, or low serum albumin. Finally, she does not have the dermatitis herpetiformis rash to suggest autoimmune gluten-sensitive enteropathy, nor does she have evidence of follicular hyperplasia or petechiae due to vitamin malabsorption.3

Because no single serologic test is ideal for diagnosing gluten-sensitive enteropathy, several tests are typically used: immunoglobulin A (IgA) antigliadin antibody, IgG antigliadin antibody, IgA antitransglutaminase antibody, and IgA antiendomysial antibody. IgA antitransglutaminase antibody is 92% to 98% sensitive and 91% to 100% specific for celiac disease. IgG antigliadin antibody is 92% to 97% sensitive and 99% specific. The positive predictive value of the IgA and IgG antigliadin antibody tests is less than 2% in the general population, whereas the positive predictive value for antiendomysial antibody and antitransglutaminase antibody are 15.7% and 21.8%, respectively.4 A positive serologic test for antiendomysial antibody is nearly 100% specific.

Our patient’s entire celiac antibody panel is negative, and thus celiac disease is unlikely.

 

 

Case continued: Features of microscopic colitis

In our patient, colonic biopsy reveals a mildly expanded lamina propria, intraepithelial lymphocytes, and a patchy but prominent thickening of the subepithelial collagen table. This set of features is consistent with collagenous colitis, a variant of microscopic colitis. Histologic signs on biopsy specimens are fairly specific for the disease.5

Chronic, intermittent, secretory diarrhea without bleeding is the hallmark of microscopic colitis. Associated symptoms may include abdominal pain, weight loss, and fatigue. If biopsies are not taken at the time of the initial evaluation, and the colonic pathology is overlooked, patients with collagenous colitis may be diagnosed with irritable bowel syndrome with diarrhea.6 The sedimentation rate is often elevated, and the antinuclear antibody test can be positive.7 Steatorrhea or protein-losing enteropathy can occur, and fecal leukocytes are present in more than 50% of patients.8

This patient fits well the demographics of the typical collagenous colitis patient: ie, a middle-aged woman in her 6th decade in otherwise good general health. The female-to-male ratio is 15:1 overall, although the relative frequency of collagenous colitis in women is greater than that of lymphocytic colitis.9 In a population-based study, the incidence of collagenous colitis was 5.1 per 100,000 per year, with a prevalence of 36 per 100,000; the incidence of lymphocytic colitis was 9.8 per 100,000 per year, with a prevalence of 64 per 100,000.10

Symptoms are typically vague and range from an annoyance to more than 20 non-bloody stools per day. The course of the disease also varies. Case series have reported a spontaneous remission rate of 15% to 20%,11 though flare-ups are common. Microscopic colitis is largely a benign disease. It does not increase a person’s risk of colon cancer.

CAUSES OF COLLAGENOUS COLITIS

2. What causes of collagenous colitis have been identified?

  • Alcohol abuse
  • Previous gastrointestinal surgery
  • Drug-induced injury to colon

Neither alcohol use nor previous gastrointestinal surgery has been associated with the development of collagenous colitis.

Collagenous colitis has, however, been linked to several causes. Abnormal collagen metabolism has been demonstrated in patients as a result of increased expression of procollagen I and metalloproteinase inhibitor TIMP-1.12 Bacterial toxins and a bile-acid malabsorption defect in the terminal ileum and subsequent exposure of the colon to high concentrations of bile acids have also been linked to the development of collagenous colitis.

Many drugs have been linked to the development of collagenous colitis. Damage to the large intestine related to the use of non-steroidal anti-inflammatory drugs has been attributed to the blockage of prostaglandin synthesis.13 Simvastatin (Zocor), lansoprazole (Prilosec), and ticlopidine (Ticlid) have been linked to collagenous colitis; ticlopidine, flutamide (Eulexin), gold salts, lansoprazole, and sertraline (Zoloft) have been linked to the development of lymphocytic colitis.14 In one small series, patients developed colitis after switching from omeprazole (Prevacid) to lansoprazole. All patients had their symptoms and biopsy findings resolve within 1 week of stopping the drug.15

WHICH DRUG IS BEST?

3. Which drug is best for microscopic colitis, based on the current evidence?

  • Bismuth (eg, Kaopectate, Pepto-Bismol)
  • Sulfasalazine (Sulfazine)
  • Budesonide (Entocort)
  • Prednisolone

Studies have evaluated bismuth subsalicylate, Boswellia serrata extract, probiotics, prednisolone, budesonide, and other drugs for treating collagenous colitis.16

Bismuth trials have been small. In an open-label study of bismuth,17 symptoms improved in 11 of 12 patients.

Prednisolone recipients had a trend towards clinical response with treatment vs placebo, but it was not statistically significant, and there was incomplete remission of disease.18

Boswellia serrataextract19 and probiotics20 showed no clinical improvement.

Cholestyramine has been shown to be helpful when used in conjunction with an anti-inflammatory agent,21 and it may be helpful when used alone.

Aminosalicylate compounds have not been tested in prospective randomized trials, even though they are the cornerstone of treatment for ulcerative colitis. Retrospective trials have been equivocal.22

Budesonide currently has the best evidence of efficacy in collagenous colitis,23,24 and some evidence suggests it is also effective for other variants of microscopic colitis.

A total of 94 patients were enrolled in three placebo-controlled trials of budesonide at 9 mg daily or on a tapering schedule for 6 to 8 weeks. The pooled odds ratio for clinical response to treatment with budesonide was 12.32 (95% confidence interval 5.53–27.46), with a number needed to treat of 1.58. Significant histologic improvement with treatment was noted in all three trials.23

Quality of life has also been studied in patients with microscopic colitis who take budesonide. Symptoms, emotional functioning, and physical functioning are improved. Budesonide also improved stool consistency and significantly reduced the mean stool frequency compared with placebo.24

Compared with cortisol, budesonide has a 200 times greater affinity for the glucocorticoid receptor, and a 1,000 times greater topical anti-inflammatory potency. It is also well absorbed in the gastrointestinal tract but is substantially modified into very weak metabolites as a result of first-pass metabolism in the liver.25 This localized effect further supports the use of budesonide in patients with any form of microscopic colitis.

Although studies have shown budesonide to be effective, not every patient with a histologic diagnosis of microscopic colitis needs it. It is reasonable to try antidiarrheal agents, bismuth, or both as a first step because they are inexpensive and have few side effects. If budesonide is used, it should be given for 6 to 8 weeks, then stopped, and the patient should then be monitored for symptom recurrence. If a flare does occur, budesonide can be restarted and continued as maintenance therapy.

 

 

KEY CONSIDERATIONS

Microscopic colitis is diagnosed histologically, while irritable bowel syndrome is a clinical diagnosis. In population-based cohorts of histologically confirmed microscopic colitis, 50% to 70% met symptom-based Rome criteria for the diagnosis of irritable bowel syndrome. The clinical symptom-based criteria for irritable bowel syndrome are not specific enough to rule out the diagnosis of microscopic colitis. Therefore, patients with suspected diarrhea-predominant irritable bowel syndrome should undergo colonoscopy with biopsy to investigate microscopic colitis if symptoms are not well controlled by antidiarrheal therapy.26 The patient’s management may be very different depending on whether colonoscopy is done.

Management of microscopic colitis should include stopping any drugs associated with it. Simple antidiarrheal agents should be tried first to manage symptoms. If symptoms persist, patients can be treated with budesonide (Entocort EC) 9 mg by mouth daily for 8 weeks to induce remission, or 6 mg by mouth daily for 3 months as maintenance therapy.

OUR PATIENT’S COURSE

Our patient’s medication list includes duloxetine, a serotonin-norepinephrine reuptake inhibitor related to drugs that have been associated with the development of microscopic colitis. We tapered the duloxetine, and her symptoms improved by 50%. Her symptoms were eventually controlled after an 8-week course of oral budesonide 9 mg and ongoing intermittent use of loperamide (Imodium).

References
  1. Swagerty DL, Walling AD, Klein RM. Lactose intolerance. Am Fam Physician 2002; 65:18451856.
  2. Thomas PD, Forbes A, Green J, et al. Guidelines for the investigation of chronic diarrhea, 2nd edition. Gut 2003; 52(suppl 5):15.
  3. Nelsen DA. Gluten-sensitive enteropathy (celiac disease): more common than you think. Am Fam Physician 2002; 66:22592266.
  4. Bardella MT, Trovato C, Cesana BM, Pagliari C, Gebbia C, Peracchi M. Serological markers for coeliac disease: is it time to change? Dig Liver Dis 2001; 33:426431.
  5. Barta Z, Mekkel G, Csipo I, et al. Micropscopic colitis: a retrospective study of clinical presentation in 53 patients. World J Gastroenterol 2005; 11:13511355.
  6. Tremaine WJ. Diagnosing collagenous colitis: does it make a difference? Eur J Gastroenterol Hepatol 1999; 11:477479.
  7. Bohr J, Tysk C, Yang P, Danielsson D, Järnerot G. Autoantibodies and immunoglobulins in collagenous colitis. Gut 1996; 39:7781.
  8. Zins BJ, Tremaine WJ, Carpenter HA. Collagenous colitis: mucosal biopsies and association with fecal leukocytes. Mayo Clin Proc 1995; 70:430433.
  9. Olsen M, Eriksson S, Bohr J, Järnerot G, Tysk C. Lymphocytic colitis: a retrospective clinical study of 199 Swedish patients. Gut 2004; 53:536541.
  10. Pardi DS. Microscopic colitis: an update. Inflamm Bowel Dis 2004; 10:860870.
  11. Fernandez-Banares F, Salas A, Esteve M, Espinos J, Forne M, Viver JM. Collagenous and lymphocytic colitis: evaluation of clinical and histological features, response to treatment, and long-term follow-up. Am J Gastroenterol 2003; 98:340347.
  12. Aignet T, Neureiter D, Müller S, Küspert G, Belke J, Kirchner T. Extracellular matrix composition and gene expression in collagenous colitis. Gastroenterology 1997; 113:136143.
  13. Parfitt JR, Driman DK. Pathological effects of drugs on the gastrointestinal tract: a review. Hum Pathol 2007; 38:527536.
  14. Fernández-Bañares F, Esteve M, Espinós JC, et al. Drug consumption and the risk of microscopic colitis. Am J Gastroenterol 2007; 102:324330.
  15. Thomson RD, Lestine LS, Bensen SP, et al. Lansoprazole-associated microscopic colitis: a case series. Am J Gastroenterol 2002; 97:29082913.
  16. Chande N, McDonald JWD, MacDonald JK. Cochrane Inflammatory Bowel Disease and Functional Bowel Disorders Group. Interventions for treating collagenous colitis. Cochrane Database Syst Rev 2007 Jan 24;(1):CD006096.
  17. Fine K, Lee E. Efficacy of open-label bismuth subsalicylate for the treatment of microscopic colitis. Gastroenterology 1998; 114:2936.
  18. Munck LK, Kjeldsen J, Philipsen E, Fscher Hansen B. Incomplete remission with short-term prednisolone treatment in collagenous colitis: a randomized study. Scand J Gastroenterol 2003; 38:606610.
  19. Madisch A, Miehlke S, Eichele E, et al. Boswellia serrata extract for the treatment of collagenous colitis: a randomized, double-blind, placebo-controlled, multicenter trial. Int J Colorectal Dis 2007; 22:14451451.
  20. Wildt S, Munck LK, Vinter-Jensen L, et al. Probiotic treatment of collagenous colitis: a randomized, double-blind, placebo-controlled trial with Lactobacillus acidophilus and Bifidobacterium animalis subsp. lactis. Inflamm Bowel Dis 2006; 12:395401.
  21. Calabrese C, Fabbri A, Areni A, Zahlane D, Scialpi C, Di Febo G. Mesalazine with or without cholestyramine in the treatment of microscopic colitis: randomized controlled trial. J Gastroenterol Hepatol 2007; 22:809814.
  22. Wall GC, Schirmer LL, Page MJ. Pharmacotherapy for microscopic colitis. Pharmacotherapy 2007; 27:425433.
  23. Feyen B, Wall GC, Finnerty EP, DeWitt JE, Reyes RS. Meta-analysis: budesonide treatment for collagenous colitis. Aliment Pharmacol Ther 2004; 20:745749.
  24. Madisch A, Heymer P, Voss C, et al. Oral budesonide therapy improves quality of life in patients with collagenous colitis. Int J Colorectal Dis 2005; 20:312316.
  25. Craig CR, editor. Modern Pharmacology With Clinical Application. 6th edition. Philadelphia: Lippincott Williams and Wilkins, 2003:481.
  26. Limsui D, Pardi DS, Camilleri M, et al. Symptomatic overlap between irritable bowel syndrome and microscopic colitis. Inflamm Bowel Dis 2007; 13:175181.
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Jennifer Monti, BA
Cleveland Clinic Lerner College of Medicine of Case Western Reserve University

J. Harry Isaacson, MD
Department of General Internal Medicine, Cleveland Clinic; Associate Professor of Medicine, Cleveland Clinic Lerner College of Medicine of Case Western Reserve University

Bret Lashner, MD
Department of Gastroenterology and Hepatology, Cleveland Clinic; Director, Center for Inflammatory Bowel Disease; Director, Gastroenterology and Hepatology Fellowship Program; Professor of Medicine, Cleveland Clinic Lerner College of Medicine of Case Western Reserve University

Address: J. Harry Isaacson, MD, General Internal Medicine, A91, Cleveland Clinic, 9500 Euclid Avenue, Cleveland, OH 44195; e-mail [email protected]

Dr. Lashner has disclosed that he has received consulting fees from Prometheus corporation for membership on advisory committees or review panels.

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Jennifer Monti, BA
Cleveland Clinic Lerner College of Medicine of Case Western Reserve University

J. Harry Isaacson, MD
Department of General Internal Medicine, Cleveland Clinic; Associate Professor of Medicine, Cleveland Clinic Lerner College of Medicine of Case Western Reserve University

Bret Lashner, MD
Department of Gastroenterology and Hepatology, Cleveland Clinic; Director, Center for Inflammatory Bowel Disease; Director, Gastroenterology and Hepatology Fellowship Program; Professor of Medicine, Cleveland Clinic Lerner College of Medicine of Case Western Reserve University

Address: J. Harry Isaacson, MD, General Internal Medicine, A91, Cleveland Clinic, 9500 Euclid Avenue, Cleveland, OH 44195; e-mail [email protected]

Dr. Lashner has disclosed that he has received consulting fees from Prometheus corporation for membership on advisory committees or review panels.

Author and Disclosure Information

Jennifer Monti, BA
Cleveland Clinic Lerner College of Medicine of Case Western Reserve University

J. Harry Isaacson, MD
Department of General Internal Medicine, Cleveland Clinic; Associate Professor of Medicine, Cleveland Clinic Lerner College of Medicine of Case Western Reserve University

Bret Lashner, MD
Department of Gastroenterology and Hepatology, Cleveland Clinic; Director, Center for Inflammatory Bowel Disease; Director, Gastroenterology and Hepatology Fellowship Program; Professor of Medicine, Cleveland Clinic Lerner College of Medicine of Case Western Reserve University

Address: J. Harry Isaacson, MD, General Internal Medicine, A91, Cleveland Clinic, 9500 Euclid Avenue, Cleveland, OH 44195; e-mail [email protected]

Dr. Lashner has disclosed that he has received consulting fees from Prometheus corporation for membership on advisory committees or review panels.

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Related Articles
Correction: A case of refractory diarrhea

A 68-year-old white woman with irritable bowel syndrome has had worsening symptoms of right-sided abdominal pain, excessive bloating, and loose stools. Her bowel movements have increased from one a day to two or three a day. She has not noted any mucus or blood in the stool. She cannot identify any alleviating or aggravating factors, and the pain is not related to eating.

She consumes a normal diet, including meat and dairy. Over-the-counter antidiarrheal medications do not relieve the symptoms. She has had no fevers, chills, or night sweats, and she has not lost weight over the past year.

Her medical history includes breast cancer (in remission), alcohol abuse (in remission), and hypothyroidism, osteoporosis, and supraventricular tachycardia, all controlled with treatment as noted below. She has never undergone abdominal surgery.

A general review of systems is normal. Her current medications include oxybutynin (available as Ditropan, others), calcium polycarbophil (FiberCon, others), risedronate (Actonel), levothyroxine (Synthroid, others), simethicone (Maalox Anti-Gas, others), atenolol (Tenormin), trazodone (Desyrel), a calcium supplement, and aspirin. She began taking duloxetine (Cymbalta) 18 months ago, and the dose was increased from 60 mg to 90 mg 1 week before this visit.

She has never smoked, and she has abstained from alcohol for 10 years. She has no family history of colon cancer, celiac disease, or inflammatory bowel disease. She has not traveled outside the country in the past several years, and she notes no change in her source of drinking water.

On physical examination, she does not appear to be in acute distress. Her pulse is 64 and her blood pressure is 112/78 mm Hg. The cardiopulmonary examination is normal. Her abdomen is soft, symmetrical, nondistended, and nontender. Bowel sounds are normal. No abdominal masses, palpable organomegaly, or abdominal bruits are noted.

Results of basic laboratory tests, including thyroid-stimulating hormone (TSH), complete blood count, blood chemistries, renal function, and liver function, are normal. Colonoscopy shows normal mucosa as far as the cecum.

DIFFERENTIAL DIAGNOSIS

1. In addition to irritable bowel syndrome, which of these can explain her symptoms?

  • Ulcerative colitis
  • Celiac disease
  • Microscopic colitis
  • Hyperthyroidism
  • Lactase deficiency

Ulcerative colitis typically presents with blood and mucus in the stool and gross abnormalities on colonoscopy, none of which is present in this patient.

Hyperthyroidism can be ruled out by the normal TSH level.

Lactase deficiency or lactose intolerance is unlikely because it is present in only 15% of people of northern European descent (compared with 80% of blacks and Hispanics and up to 100% of Native Americans and Asians).1 Furthermore, her pain is apparently not related to consuming dairy products.

The hydrogen breath test can aid in the diagnosis of lactase deficiency. This test relies on the breakdown of malabsorbed lactose by colonic flora. This is the most widely used test for this deficiency, but its high false-negative rate of 25% means that a negative result does not exclude the diagnosis and should not be relied on in working up a patient with chronic diarrhea.2 Simply noting whether symptoms develop after ingesting 50 g of lactose is clinically useful when lactase deficiency is suspected.

Based on the information so far, it is reasonable in this patient to evaluate for celiac disease and for microscopic colitis.

Celiac disease, also called gluten-sensitive enteropathy, has a varied presentation that includes nonspecific symptoms such as those in this patient. Classically, it causes diarrhea, but patients may present with a single nutrient deficiency and no diarrhea.

This patient lacks the elevated alkaline phosphatase or evidence of vitamin deficiencies characteristic of malabsorption in celiac disease (ie, vitamins A, B12, D, K, and folate)3. She also lacks evidence of malnutrition, such as iron deficiency anemia, weight loss, or low serum albumin. Finally, she does not have the dermatitis herpetiformis rash to suggest autoimmune gluten-sensitive enteropathy, nor does she have evidence of follicular hyperplasia or petechiae due to vitamin malabsorption.3

Because no single serologic test is ideal for diagnosing gluten-sensitive enteropathy, several tests are typically used: immunoglobulin A (IgA) antigliadin antibody, IgG antigliadin antibody, IgA antitransglutaminase antibody, and IgA antiendomysial antibody. IgA antitransglutaminase antibody is 92% to 98% sensitive and 91% to 100% specific for celiac disease. IgG antigliadin antibody is 92% to 97% sensitive and 99% specific. The positive predictive value of the IgA and IgG antigliadin antibody tests is less than 2% in the general population, whereas the positive predictive value for antiendomysial antibody and antitransglutaminase antibody are 15.7% and 21.8%, respectively.4 A positive serologic test for antiendomysial antibody is nearly 100% specific.

Our patient’s entire celiac antibody panel is negative, and thus celiac disease is unlikely.

 

 

Case continued: Features of microscopic colitis

In our patient, colonic biopsy reveals a mildly expanded lamina propria, intraepithelial lymphocytes, and a patchy but prominent thickening of the subepithelial collagen table. This set of features is consistent with collagenous colitis, a variant of microscopic colitis. Histologic signs on biopsy specimens are fairly specific for the disease.5

Chronic, intermittent, secretory diarrhea without bleeding is the hallmark of microscopic colitis. Associated symptoms may include abdominal pain, weight loss, and fatigue. If biopsies are not taken at the time of the initial evaluation, and the colonic pathology is overlooked, patients with collagenous colitis may be diagnosed with irritable bowel syndrome with diarrhea.6 The sedimentation rate is often elevated, and the antinuclear antibody test can be positive.7 Steatorrhea or protein-losing enteropathy can occur, and fecal leukocytes are present in more than 50% of patients.8

This patient fits well the demographics of the typical collagenous colitis patient: ie, a middle-aged woman in her 6th decade in otherwise good general health. The female-to-male ratio is 15:1 overall, although the relative frequency of collagenous colitis in women is greater than that of lymphocytic colitis.9 In a population-based study, the incidence of collagenous colitis was 5.1 per 100,000 per year, with a prevalence of 36 per 100,000; the incidence of lymphocytic colitis was 9.8 per 100,000 per year, with a prevalence of 64 per 100,000.10

Symptoms are typically vague and range from an annoyance to more than 20 non-bloody stools per day. The course of the disease also varies. Case series have reported a spontaneous remission rate of 15% to 20%,11 though flare-ups are common. Microscopic colitis is largely a benign disease. It does not increase a person’s risk of colon cancer.

CAUSES OF COLLAGENOUS COLITIS

2. What causes of collagenous colitis have been identified?

  • Alcohol abuse
  • Previous gastrointestinal surgery
  • Drug-induced injury to colon

Neither alcohol use nor previous gastrointestinal surgery has been associated with the development of collagenous colitis.

Collagenous colitis has, however, been linked to several causes. Abnormal collagen metabolism has been demonstrated in patients as a result of increased expression of procollagen I and metalloproteinase inhibitor TIMP-1.12 Bacterial toxins and a bile-acid malabsorption defect in the terminal ileum and subsequent exposure of the colon to high concentrations of bile acids have also been linked to the development of collagenous colitis.

Many drugs have been linked to the development of collagenous colitis. Damage to the large intestine related to the use of non-steroidal anti-inflammatory drugs has been attributed to the blockage of prostaglandin synthesis.13 Simvastatin (Zocor), lansoprazole (Prilosec), and ticlopidine (Ticlid) have been linked to collagenous colitis; ticlopidine, flutamide (Eulexin), gold salts, lansoprazole, and sertraline (Zoloft) have been linked to the development of lymphocytic colitis.14 In one small series, patients developed colitis after switching from omeprazole (Prevacid) to lansoprazole. All patients had their symptoms and biopsy findings resolve within 1 week of stopping the drug.15

WHICH DRUG IS BEST?

3. Which drug is best for microscopic colitis, based on the current evidence?

  • Bismuth (eg, Kaopectate, Pepto-Bismol)
  • Sulfasalazine (Sulfazine)
  • Budesonide (Entocort)
  • Prednisolone

Studies have evaluated bismuth subsalicylate, Boswellia serrata extract, probiotics, prednisolone, budesonide, and other drugs for treating collagenous colitis.16

Bismuth trials have been small. In an open-label study of bismuth,17 symptoms improved in 11 of 12 patients.

Prednisolone recipients had a trend towards clinical response with treatment vs placebo, but it was not statistically significant, and there was incomplete remission of disease.18

Boswellia serrataextract19 and probiotics20 showed no clinical improvement.

Cholestyramine has been shown to be helpful when used in conjunction with an anti-inflammatory agent,21 and it may be helpful when used alone.

Aminosalicylate compounds have not been tested in prospective randomized trials, even though they are the cornerstone of treatment for ulcerative colitis. Retrospective trials have been equivocal.22

Budesonide currently has the best evidence of efficacy in collagenous colitis,23,24 and some evidence suggests it is also effective for other variants of microscopic colitis.

A total of 94 patients were enrolled in three placebo-controlled trials of budesonide at 9 mg daily or on a tapering schedule for 6 to 8 weeks. The pooled odds ratio for clinical response to treatment with budesonide was 12.32 (95% confidence interval 5.53–27.46), with a number needed to treat of 1.58. Significant histologic improvement with treatment was noted in all three trials.23

Quality of life has also been studied in patients with microscopic colitis who take budesonide. Symptoms, emotional functioning, and physical functioning are improved. Budesonide also improved stool consistency and significantly reduced the mean stool frequency compared with placebo.24

Compared with cortisol, budesonide has a 200 times greater affinity for the glucocorticoid receptor, and a 1,000 times greater topical anti-inflammatory potency. It is also well absorbed in the gastrointestinal tract but is substantially modified into very weak metabolites as a result of first-pass metabolism in the liver.25 This localized effect further supports the use of budesonide in patients with any form of microscopic colitis.

Although studies have shown budesonide to be effective, not every patient with a histologic diagnosis of microscopic colitis needs it. It is reasonable to try antidiarrheal agents, bismuth, or both as a first step because they are inexpensive and have few side effects. If budesonide is used, it should be given for 6 to 8 weeks, then stopped, and the patient should then be monitored for symptom recurrence. If a flare does occur, budesonide can be restarted and continued as maintenance therapy.

 

 

KEY CONSIDERATIONS

Microscopic colitis is diagnosed histologically, while irritable bowel syndrome is a clinical diagnosis. In population-based cohorts of histologically confirmed microscopic colitis, 50% to 70% met symptom-based Rome criteria for the diagnosis of irritable bowel syndrome. The clinical symptom-based criteria for irritable bowel syndrome are not specific enough to rule out the diagnosis of microscopic colitis. Therefore, patients with suspected diarrhea-predominant irritable bowel syndrome should undergo colonoscopy with biopsy to investigate microscopic colitis if symptoms are not well controlled by antidiarrheal therapy.26 The patient’s management may be very different depending on whether colonoscopy is done.

Management of microscopic colitis should include stopping any drugs associated with it. Simple antidiarrheal agents should be tried first to manage symptoms. If symptoms persist, patients can be treated with budesonide (Entocort EC) 9 mg by mouth daily for 8 weeks to induce remission, or 6 mg by mouth daily for 3 months as maintenance therapy.

OUR PATIENT’S COURSE

Our patient’s medication list includes duloxetine, a serotonin-norepinephrine reuptake inhibitor related to drugs that have been associated with the development of microscopic colitis. We tapered the duloxetine, and her symptoms improved by 50%. Her symptoms were eventually controlled after an 8-week course of oral budesonide 9 mg and ongoing intermittent use of loperamide (Imodium).

A 68-year-old white woman with irritable bowel syndrome has had worsening symptoms of right-sided abdominal pain, excessive bloating, and loose stools. Her bowel movements have increased from one a day to two or three a day. She has not noted any mucus or blood in the stool. She cannot identify any alleviating or aggravating factors, and the pain is not related to eating.

She consumes a normal diet, including meat and dairy. Over-the-counter antidiarrheal medications do not relieve the symptoms. She has had no fevers, chills, or night sweats, and she has not lost weight over the past year.

Her medical history includes breast cancer (in remission), alcohol abuse (in remission), and hypothyroidism, osteoporosis, and supraventricular tachycardia, all controlled with treatment as noted below. She has never undergone abdominal surgery.

A general review of systems is normal. Her current medications include oxybutynin (available as Ditropan, others), calcium polycarbophil (FiberCon, others), risedronate (Actonel), levothyroxine (Synthroid, others), simethicone (Maalox Anti-Gas, others), atenolol (Tenormin), trazodone (Desyrel), a calcium supplement, and aspirin. She began taking duloxetine (Cymbalta) 18 months ago, and the dose was increased from 60 mg to 90 mg 1 week before this visit.

She has never smoked, and she has abstained from alcohol for 10 years. She has no family history of colon cancer, celiac disease, or inflammatory bowel disease. She has not traveled outside the country in the past several years, and she notes no change in her source of drinking water.

On physical examination, she does not appear to be in acute distress. Her pulse is 64 and her blood pressure is 112/78 mm Hg. The cardiopulmonary examination is normal. Her abdomen is soft, symmetrical, nondistended, and nontender. Bowel sounds are normal. No abdominal masses, palpable organomegaly, or abdominal bruits are noted.

Results of basic laboratory tests, including thyroid-stimulating hormone (TSH), complete blood count, blood chemistries, renal function, and liver function, are normal. Colonoscopy shows normal mucosa as far as the cecum.

DIFFERENTIAL DIAGNOSIS

1. In addition to irritable bowel syndrome, which of these can explain her symptoms?

  • Ulcerative colitis
  • Celiac disease
  • Microscopic colitis
  • Hyperthyroidism
  • Lactase deficiency

Ulcerative colitis typically presents with blood and mucus in the stool and gross abnormalities on colonoscopy, none of which is present in this patient.

Hyperthyroidism can be ruled out by the normal TSH level.

Lactase deficiency or lactose intolerance is unlikely because it is present in only 15% of people of northern European descent (compared with 80% of blacks and Hispanics and up to 100% of Native Americans and Asians).1 Furthermore, her pain is apparently not related to consuming dairy products.

The hydrogen breath test can aid in the diagnosis of lactase deficiency. This test relies on the breakdown of malabsorbed lactose by colonic flora. This is the most widely used test for this deficiency, but its high false-negative rate of 25% means that a negative result does not exclude the diagnosis and should not be relied on in working up a patient with chronic diarrhea.2 Simply noting whether symptoms develop after ingesting 50 g of lactose is clinically useful when lactase deficiency is suspected.

Based on the information so far, it is reasonable in this patient to evaluate for celiac disease and for microscopic colitis.

Celiac disease, also called gluten-sensitive enteropathy, has a varied presentation that includes nonspecific symptoms such as those in this patient. Classically, it causes diarrhea, but patients may present with a single nutrient deficiency and no diarrhea.

This patient lacks the elevated alkaline phosphatase or evidence of vitamin deficiencies characteristic of malabsorption in celiac disease (ie, vitamins A, B12, D, K, and folate)3. She also lacks evidence of malnutrition, such as iron deficiency anemia, weight loss, or low serum albumin. Finally, she does not have the dermatitis herpetiformis rash to suggest autoimmune gluten-sensitive enteropathy, nor does she have evidence of follicular hyperplasia or petechiae due to vitamin malabsorption.3

Because no single serologic test is ideal for diagnosing gluten-sensitive enteropathy, several tests are typically used: immunoglobulin A (IgA) antigliadin antibody, IgG antigliadin antibody, IgA antitransglutaminase antibody, and IgA antiendomysial antibody. IgA antitransglutaminase antibody is 92% to 98% sensitive and 91% to 100% specific for celiac disease. IgG antigliadin antibody is 92% to 97% sensitive and 99% specific. The positive predictive value of the IgA and IgG antigliadin antibody tests is less than 2% in the general population, whereas the positive predictive value for antiendomysial antibody and antitransglutaminase antibody are 15.7% and 21.8%, respectively.4 A positive serologic test for antiendomysial antibody is nearly 100% specific.

Our patient’s entire celiac antibody panel is negative, and thus celiac disease is unlikely.

 

 

Case continued: Features of microscopic colitis

In our patient, colonic biopsy reveals a mildly expanded lamina propria, intraepithelial lymphocytes, and a patchy but prominent thickening of the subepithelial collagen table. This set of features is consistent with collagenous colitis, a variant of microscopic colitis. Histologic signs on biopsy specimens are fairly specific for the disease.5

Chronic, intermittent, secretory diarrhea without bleeding is the hallmark of microscopic colitis. Associated symptoms may include abdominal pain, weight loss, and fatigue. If biopsies are not taken at the time of the initial evaluation, and the colonic pathology is overlooked, patients with collagenous colitis may be diagnosed with irritable bowel syndrome with diarrhea.6 The sedimentation rate is often elevated, and the antinuclear antibody test can be positive.7 Steatorrhea or protein-losing enteropathy can occur, and fecal leukocytes are present in more than 50% of patients.8

This patient fits well the demographics of the typical collagenous colitis patient: ie, a middle-aged woman in her 6th decade in otherwise good general health. The female-to-male ratio is 15:1 overall, although the relative frequency of collagenous colitis in women is greater than that of lymphocytic colitis.9 In a population-based study, the incidence of collagenous colitis was 5.1 per 100,000 per year, with a prevalence of 36 per 100,000; the incidence of lymphocytic colitis was 9.8 per 100,000 per year, with a prevalence of 64 per 100,000.10

Symptoms are typically vague and range from an annoyance to more than 20 non-bloody stools per day. The course of the disease also varies. Case series have reported a spontaneous remission rate of 15% to 20%,11 though flare-ups are common. Microscopic colitis is largely a benign disease. It does not increase a person’s risk of colon cancer.

CAUSES OF COLLAGENOUS COLITIS

2. What causes of collagenous colitis have been identified?

  • Alcohol abuse
  • Previous gastrointestinal surgery
  • Drug-induced injury to colon

Neither alcohol use nor previous gastrointestinal surgery has been associated with the development of collagenous colitis.

Collagenous colitis has, however, been linked to several causes. Abnormal collagen metabolism has been demonstrated in patients as a result of increased expression of procollagen I and metalloproteinase inhibitor TIMP-1.12 Bacterial toxins and a bile-acid malabsorption defect in the terminal ileum and subsequent exposure of the colon to high concentrations of bile acids have also been linked to the development of collagenous colitis.

Many drugs have been linked to the development of collagenous colitis. Damage to the large intestine related to the use of non-steroidal anti-inflammatory drugs has been attributed to the blockage of prostaglandin synthesis.13 Simvastatin (Zocor), lansoprazole (Prilosec), and ticlopidine (Ticlid) have been linked to collagenous colitis; ticlopidine, flutamide (Eulexin), gold salts, lansoprazole, and sertraline (Zoloft) have been linked to the development of lymphocytic colitis.14 In one small series, patients developed colitis after switching from omeprazole (Prevacid) to lansoprazole. All patients had their symptoms and biopsy findings resolve within 1 week of stopping the drug.15

WHICH DRUG IS BEST?

3. Which drug is best for microscopic colitis, based on the current evidence?

  • Bismuth (eg, Kaopectate, Pepto-Bismol)
  • Sulfasalazine (Sulfazine)
  • Budesonide (Entocort)
  • Prednisolone

Studies have evaluated bismuth subsalicylate, Boswellia serrata extract, probiotics, prednisolone, budesonide, and other drugs for treating collagenous colitis.16

Bismuth trials have been small. In an open-label study of bismuth,17 symptoms improved in 11 of 12 patients.

Prednisolone recipients had a trend towards clinical response with treatment vs placebo, but it was not statistically significant, and there was incomplete remission of disease.18

Boswellia serrataextract19 and probiotics20 showed no clinical improvement.

Cholestyramine has been shown to be helpful when used in conjunction with an anti-inflammatory agent,21 and it may be helpful when used alone.

Aminosalicylate compounds have not been tested in prospective randomized trials, even though they are the cornerstone of treatment for ulcerative colitis. Retrospective trials have been equivocal.22

Budesonide currently has the best evidence of efficacy in collagenous colitis,23,24 and some evidence suggests it is also effective for other variants of microscopic colitis.

A total of 94 patients were enrolled in three placebo-controlled trials of budesonide at 9 mg daily or on a tapering schedule for 6 to 8 weeks. The pooled odds ratio for clinical response to treatment with budesonide was 12.32 (95% confidence interval 5.53–27.46), with a number needed to treat of 1.58. Significant histologic improvement with treatment was noted in all three trials.23

Quality of life has also been studied in patients with microscopic colitis who take budesonide. Symptoms, emotional functioning, and physical functioning are improved. Budesonide also improved stool consistency and significantly reduced the mean stool frequency compared with placebo.24

Compared with cortisol, budesonide has a 200 times greater affinity for the glucocorticoid receptor, and a 1,000 times greater topical anti-inflammatory potency. It is also well absorbed in the gastrointestinal tract but is substantially modified into very weak metabolites as a result of first-pass metabolism in the liver.25 This localized effect further supports the use of budesonide in patients with any form of microscopic colitis.

Although studies have shown budesonide to be effective, not every patient with a histologic diagnosis of microscopic colitis needs it. It is reasonable to try antidiarrheal agents, bismuth, or both as a first step because they are inexpensive and have few side effects. If budesonide is used, it should be given for 6 to 8 weeks, then stopped, and the patient should then be monitored for symptom recurrence. If a flare does occur, budesonide can be restarted and continued as maintenance therapy.

 

 

KEY CONSIDERATIONS

Microscopic colitis is diagnosed histologically, while irritable bowel syndrome is a clinical diagnosis. In population-based cohorts of histologically confirmed microscopic colitis, 50% to 70% met symptom-based Rome criteria for the diagnosis of irritable bowel syndrome. The clinical symptom-based criteria for irritable bowel syndrome are not specific enough to rule out the diagnosis of microscopic colitis. Therefore, patients with suspected diarrhea-predominant irritable bowel syndrome should undergo colonoscopy with biopsy to investigate microscopic colitis if symptoms are not well controlled by antidiarrheal therapy.26 The patient’s management may be very different depending on whether colonoscopy is done.

Management of microscopic colitis should include stopping any drugs associated with it. Simple antidiarrheal agents should be tried first to manage symptoms. If symptoms persist, patients can be treated with budesonide (Entocort EC) 9 mg by mouth daily for 8 weeks to induce remission, or 6 mg by mouth daily for 3 months as maintenance therapy.

OUR PATIENT’S COURSE

Our patient’s medication list includes duloxetine, a serotonin-norepinephrine reuptake inhibitor related to drugs that have been associated with the development of microscopic colitis. We tapered the duloxetine, and her symptoms improved by 50%. Her symptoms were eventually controlled after an 8-week course of oral budesonide 9 mg and ongoing intermittent use of loperamide (Imodium).

References
  1. Swagerty DL, Walling AD, Klein RM. Lactose intolerance. Am Fam Physician 2002; 65:18451856.
  2. Thomas PD, Forbes A, Green J, et al. Guidelines for the investigation of chronic diarrhea, 2nd edition. Gut 2003; 52(suppl 5):15.
  3. Nelsen DA. Gluten-sensitive enteropathy (celiac disease): more common than you think. Am Fam Physician 2002; 66:22592266.
  4. Bardella MT, Trovato C, Cesana BM, Pagliari C, Gebbia C, Peracchi M. Serological markers for coeliac disease: is it time to change? Dig Liver Dis 2001; 33:426431.
  5. Barta Z, Mekkel G, Csipo I, et al. Micropscopic colitis: a retrospective study of clinical presentation in 53 patients. World J Gastroenterol 2005; 11:13511355.
  6. Tremaine WJ. Diagnosing collagenous colitis: does it make a difference? Eur J Gastroenterol Hepatol 1999; 11:477479.
  7. Bohr J, Tysk C, Yang P, Danielsson D, Järnerot G. Autoantibodies and immunoglobulins in collagenous colitis. Gut 1996; 39:7781.
  8. Zins BJ, Tremaine WJ, Carpenter HA. Collagenous colitis: mucosal biopsies and association with fecal leukocytes. Mayo Clin Proc 1995; 70:430433.
  9. Olsen M, Eriksson S, Bohr J, Järnerot G, Tysk C. Lymphocytic colitis: a retrospective clinical study of 199 Swedish patients. Gut 2004; 53:536541.
  10. Pardi DS. Microscopic colitis: an update. Inflamm Bowel Dis 2004; 10:860870.
  11. Fernandez-Banares F, Salas A, Esteve M, Espinos J, Forne M, Viver JM. Collagenous and lymphocytic colitis: evaluation of clinical and histological features, response to treatment, and long-term follow-up. Am J Gastroenterol 2003; 98:340347.
  12. Aignet T, Neureiter D, Müller S, Küspert G, Belke J, Kirchner T. Extracellular matrix composition and gene expression in collagenous colitis. Gastroenterology 1997; 113:136143.
  13. Parfitt JR, Driman DK. Pathological effects of drugs on the gastrointestinal tract: a review. Hum Pathol 2007; 38:527536.
  14. Fernández-Bañares F, Esteve M, Espinós JC, et al. Drug consumption and the risk of microscopic colitis. Am J Gastroenterol 2007; 102:324330.
  15. Thomson RD, Lestine LS, Bensen SP, et al. Lansoprazole-associated microscopic colitis: a case series. Am J Gastroenterol 2002; 97:29082913.
  16. Chande N, McDonald JWD, MacDonald JK. Cochrane Inflammatory Bowel Disease and Functional Bowel Disorders Group. Interventions for treating collagenous colitis. Cochrane Database Syst Rev 2007 Jan 24;(1):CD006096.
  17. Fine K, Lee E. Efficacy of open-label bismuth subsalicylate for the treatment of microscopic colitis. Gastroenterology 1998; 114:2936.
  18. Munck LK, Kjeldsen J, Philipsen E, Fscher Hansen B. Incomplete remission with short-term prednisolone treatment in collagenous colitis: a randomized study. Scand J Gastroenterol 2003; 38:606610.
  19. Madisch A, Miehlke S, Eichele E, et al. Boswellia serrata extract for the treatment of collagenous colitis: a randomized, double-blind, placebo-controlled, multicenter trial. Int J Colorectal Dis 2007; 22:14451451.
  20. Wildt S, Munck LK, Vinter-Jensen L, et al. Probiotic treatment of collagenous colitis: a randomized, double-blind, placebo-controlled trial with Lactobacillus acidophilus and Bifidobacterium animalis subsp. lactis. Inflamm Bowel Dis 2006; 12:395401.
  21. Calabrese C, Fabbri A, Areni A, Zahlane D, Scialpi C, Di Febo G. Mesalazine with or without cholestyramine in the treatment of microscopic colitis: randomized controlled trial. J Gastroenterol Hepatol 2007; 22:809814.
  22. Wall GC, Schirmer LL, Page MJ. Pharmacotherapy for microscopic colitis. Pharmacotherapy 2007; 27:425433.
  23. Feyen B, Wall GC, Finnerty EP, DeWitt JE, Reyes RS. Meta-analysis: budesonide treatment for collagenous colitis. Aliment Pharmacol Ther 2004; 20:745749.
  24. Madisch A, Heymer P, Voss C, et al. Oral budesonide therapy improves quality of life in patients with collagenous colitis. Int J Colorectal Dis 2005; 20:312316.
  25. Craig CR, editor. Modern Pharmacology With Clinical Application. 6th edition. Philadelphia: Lippincott Williams and Wilkins, 2003:481.
  26. Limsui D, Pardi DS, Camilleri M, et al. Symptomatic overlap between irritable bowel syndrome and microscopic colitis. Inflamm Bowel Dis 2007; 13:175181.
References
  1. Swagerty DL, Walling AD, Klein RM. Lactose intolerance. Am Fam Physician 2002; 65:18451856.
  2. Thomas PD, Forbes A, Green J, et al. Guidelines for the investigation of chronic diarrhea, 2nd edition. Gut 2003; 52(suppl 5):15.
  3. Nelsen DA. Gluten-sensitive enteropathy (celiac disease): more common than you think. Am Fam Physician 2002; 66:22592266.
  4. Bardella MT, Trovato C, Cesana BM, Pagliari C, Gebbia C, Peracchi M. Serological markers for coeliac disease: is it time to change? Dig Liver Dis 2001; 33:426431.
  5. Barta Z, Mekkel G, Csipo I, et al. Micropscopic colitis: a retrospective study of clinical presentation in 53 patients. World J Gastroenterol 2005; 11:13511355.
  6. Tremaine WJ. Diagnosing collagenous colitis: does it make a difference? Eur J Gastroenterol Hepatol 1999; 11:477479.
  7. Bohr J, Tysk C, Yang P, Danielsson D, Järnerot G. Autoantibodies and immunoglobulins in collagenous colitis. Gut 1996; 39:7781.
  8. Zins BJ, Tremaine WJ, Carpenter HA. Collagenous colitis: mucosal biopsies and association with fecal leukocytes. Mayo Clin Proc 1995; 70:430433.
  9. Olsen M, Eriksson S, Bohr J, Järnerot G, Tysk C. Lymphocytic colitis: a retrospective clinical study of 199 Swedish patients. Gut 2004; 53:536541.
  10. Pardi DS. Microscopic colitis: an update. Inflamm Bowel Dis 2004; 10:860870.
  11. Fernandez-Banares F, Salas A, Esteve M, Espinos J, Forne M, Viver JM. Collagenous and lymphocytic colitis: evaluation of clinical and histological features, response to treatment, and long-term follow-up. Am J Gastroenterol 2003; 98:340347.
  12. Aignet T, Neureiter D, Müller S, Küspert G, Belke J, Kirchner T. Extracellular matrix composition and gene expression in collagenous colitis. Gastroenterology 1997; 113:136143.
  13. Parfitt JR, Driman DK. Pathological effects of drugs on the gastrointestinal tract: a review. Hum Pathol 2007; 38:527536.
  14. Fernández-Bañares F, Esteve M, Espinós JC, et al. Drug consumption and the risk of microscopic colitis. Am J Gastroenterol 2007; 102:324330.
  15. Thomson RD, Lestine LS, Bensen SP, et al. Lansoprazole-associated microscopic colitis: a case series. Am J Gastroenterol 2002; 97:29082913.
  16. Chande N, McDonald JWD, MacDonald JK. Cochrane Inflammatory Bowel Disease and Functional Bowel Disorders Group. Interventions for treating collagenous colitis. Cochrane Database Syst Rev 2007 Jan 24;(1):CD006096.
  17. Fine K, Lee E. Efficacy of open-label bismuth subsalicylate for the treatment of microscopic colitis. Gastroenterology 1998; 114:2936.
  18. Munck LK, Kjeldsen J, Philipsen E, Fscher Hansen B. Incomplete remission with short-term prednisolone treatment in collagenous colitis: a randomized study. Scand J Gastroenterol 2003; 38:606610.
  19. Madisch A, Miehlke S, Eichele E, et al. Boswellia serrata extract for the treatment of collagenous colitis: a randomized, double-blind, placebo-controlled, multicenter trial. Int J Colorectal Dis 2007; 22:14451451.
  20. Wildt S, Munck LK, Vinter-Jensen L, et al. Probiotic treatment of collagenous colitis: a randomized, double-blind, placebo-controlled trial with Lactobacillus acidophilus and Bifidobacterium animalis subsp. lactis. Inflamm Bowel Dis 2006; 12:395401.
  21. Calabrese C, Fabbri A, Areni A, Zahlane D, Scialpi C, Di Febo G. Mesalazine with or without cholestyramine in the treatment of microscopic colitis: randomized controlled trial. J Gastroenterol Hepatol 2007; 22:809814.
  22. Wall GC, Schirmer LL, Page MJ. Pharmacotherapy for microscopic colitis. Pharmacotherapy 2007; 27:425433.
  23. Feyen B, Wall GC, Finnerty EP, DeWitt JE, Reyes RS. Meta-analysis: budesonide treatment for collagenous colitis. Aliment Pharmacol Ther 2004; 20:745749.
  24. Madisch A, Heymer P, Voss C, et al. Oral budesonide therapy improves quality of life in patients with collagenous colitis. Int J Colorectal Dis 2005; 20:312316.
  25. Craig CR, editor. Modern Pharmacology With Clinical Application. 6th edition. Philadelphia: Lippincott Williams and Wilkins, 2003:481.
  26. Limsui D, Pardi DS, Camilleri M, et al. Symptomatic overlap between irritable bowel syndrome and microscopic colitis. Inflamm Bowel Dis 2007; 13:175181.
Issue
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A medical center is not a hospital

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A medical center is not a hospital
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Thomas Franklin Lansdale, MD

Editor’s note: We are interested in your thoughts on this article. See the Editor-in-Chief’s comments.

I use to be a hospital guy. I was only a few days into my third-year medicine clerkship in medical school nearly three decades ago when I fell in love with the hospital and knew I was going to be an internist. The hospital wasn’t called a medical center back then. It was a fascinating and magical place, where internists were fired in the furnace of rounds, night call, and morning report. I loved the association with the great case, the flush of excitement that accompanied the difficult diagnosis, the hard-earned annual promotion through the hierarchy of trainees seeking the rarefied air of the attending physicians. We bonded as fellow house officers more tightly than with friends outside the hospital. We prowled the wards, intensive care units, emergency room, and laboratories and never slept. The hospital was the most exclusive of clubs, and our training granted us lifelong membership.

A humming beehive of academic activity, the hospital was also a web of powerful social relationships. Everybody knew everybody, from the hospital CEO to the night security officer. The nurses called you by your first name and worked with you for weeks at a time, fostering mutual respect and sometimes even affection. In those days, nurses actually nursed their patients, spoon-feeding them broth with their medications, washing them in bed and bathroom, holding their hands and heads. Patients came to the hospital to be diagnosed and treated until they recovered from whatever illness had felled them. They stayed long enough so that you knew them and their families as well as you knew your own.

I have been a general internist and clinician-educator for 23 years, working in two university hospitals and one community hospital. That’s more than seven generations of house staff with whom I’ve toiled and learned. Somewhere along the way, I became increasingly aware that teaching clinical medicine to students, interns, and residents was getting harder and harder. The patients were sicker and stayed only 3.2 days in the hospital. What we were teaching wasn’t how to diagnose and treat diseases, but how to manage only their most serious complications—the respiratory distress from pneumonia, the ketosis of uncontrolled diabetes, the septic shock from infections. The wards became intensive care units, and the critical care units the province of “intensivists” who were more adept than we were at taming all the machinery and technology. We struggled to keep up with the unending deluge of arcane demands from the accreditation organizations watchdogging our teaching efforts. We pretended that we somehow distinguished teaching rounds from working rounds, and documented the silliness in computer files. Medical education slowly slipped from being a calling to folks like me, finally succumbing to bureaucratic lunacy. The pace of teaching and caring for acutely ill patients became intolerable. Rounds went from the bedside to the classroom to the cell phone. The house staff were getting cheated out of the whole point of residency—the miracle of turning medical students into attending physicians in a little over a thousand days.

Worse, though, was the ebbing of the lifeblood of the hospital. Now the medical center, riddled with “centers of excellence” instead of departments, answered only to administrators who cared nothing about medical education, except for the Medicare dollars they would lose if they cut the training programs. They spent enormous amounts of money marketing the centers of excellence, and they cut everything else to manipulate the bottom line.

The biggest casualty, of course, was the nursing staff. Underpaid, depleted of leadership and morale, they simply disappeared. They were replaced by agency nurses who worked their shifts and didn’t know the doctors or the patients. The complex bedside care of increasingly sick, old, and vulnerable patients was delegated to people with high school equivalency degrees. Nurses now cared for their patients by managing their own support staff, and spent much of their time entering useless information in the computer. The doctor-nurse collaboration I grew up with as a trainee and young attending didn’t exist any-more, and patients suffered as a result.

In 2000, the Institute of Medicine informed the public and the medical community that being a patient in an American hospital was dangerous.1 We were told that at least 44,000 and perhaps as many as 98,000 patients die annually in US hospitals as the result of preventable medical mishaps, more deaths than are attributable yearly to motor vehicle accidents, breast cancer, or AIDS.1 Although there has been an emerging body of literature pertaining to this epidemic, not much has changed, at least not in my hospital. We remain absurdly complacent about rising iatrogenic infection rates, knowing all too well that we are allowing immunocompromised patients to die unnecessarily in our intensive care units. There are alcohol-based hand-washing gels everywhere, but no police or policy with teeth in it to enforce handwashing. We lurch toward physician computer order entry, clinging to the false belief that software programs will prevent adverse drug reactions and delivery of the wrong dangerous drug to the wrong patient. We understaff our pharmacies so that they can’t get the medications to the patients on time or alert us to our own prescribing errors. We burn out our nurses despite years of loyal service. And worst of all, we capitulate to the for-profit insurance industry that informs us they won’t pay for day 4 of Mr. Jones’ hospitalization because he has failed to meet some arbitrary criteria in their manual.

I stepped down as chairman of my department 3 years ago because I couldn’t stand it any longer. I couldn’t stand the management retreats in which we obsessed about “customer service” while the waiting time in the emergency department ballooned to 12 hours because there were “no beds.” There were plenty of beds, but no nurses to staff them. I was marginalized when I protested the budget cycles bleeding out support of medical education in favor of the annual purchase of new scanners and surgical gizmos. I couldn’t get anybody fired up about patient safety.

Retreating to the privacy of clinical medicine, I realized the other day that my real job is not to diagnose, treat, and teach about diseases anymore. My real job is to do everything in my power to keep my patients out of the medical center. I walk the halls now and don’t recognize the institution I grew up in and came to love. Everywhere I look, I see not magic and promise, but dirt and danger.

I’m not a hospital guy anymore.

References
  1. Kohn LT, Corrigan JM, Donaldson MS, editors. To Err is Human: Building a Safer Health System. Washington, DC: National Academy Press, 2000.
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Address: Thomas F. Lansdale III, MD, 6535 North Charles Street, Suite 500, Baltimore, MD 21204; e-mail [email protected]

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Related Articles
And then there were none? An internist’s reflections

Editor’s note: We are interested in your thoughts on this article. See the Editor-in-Chief’s comments.

I use to be a hospital guy. I was only a few days into my third-year medicine clerkship in medical school nearly three decades ago when I fell in love with the hospital and knew I was going to be an internist. The hospital wasn’t called a medical center back then. It was a fascinating and magical place, where internists were fired in the furnace of rounds, night call, and morning report. I loved the association with the great case, the flush of excitement that accompanied the difficult diagnosis, the hard-earned annual promotion through the hierarchy of trainees seeking the rarefied air of the attending physicians. We bonded as fellow house officers more tightly than with friends outside the hospital. We prowled the wards, intensive care units, emergency room, and laboratories and never slept. The hospital was the most exclusive of clubs, and our training granted us lifelong membership.

A humming beehive of academic activity, the hospital was also a web of powerful social relationships. Everybody knew everybody, from the hospital CEO to the night security officer. The nurses called you by your first name and worked with you for weeks at a time, fostering mutual respect and sometimes even affection. In those days, nurses actually nursed their patients, spoon-feeding them broth with their medications, washing them in bed and bathroom, holding their hands and heads. Patients came to the hospital to be diagnosed and treated until they recovered from whatever illness had felled them. They stayed long enough so that you knew them and their families as well as you knew your own.

I have been a general internist and clinician-educator for 23 years, working in two university hospitals and one community hospital. That’s more than seven generations of house staff with whom I’ve toiled and learned. Somewhere along the way, I became increasingly aware that teaching clinical medicine to students, interns, and residents was getting harder and harder. The patients were sicker and stayed only 3.2 days in the hospital. What we were teaching wasn’t how to diagnose and treat diseases, but how to manage only their most serious complications—the respiratory distress from pneumonia, the ketosis of uncontrolled diabetes, the septic shock from infections. The wards became intensive care units, and the critical care units the province of “intensivists” who were more adept than we were at taming all the machinery and technology. We struggled to keep up with the unending deluge of arcane demands from the accreditation organizations watchdogging our teaching efforts. We pretended that we somehow distinguished teaching rounds from working rounds, and documented the silliness in computer files. Medical education slowly slipped from being a calling to folks like me, finally succumbing to bureaucratic lunacy. The pace of teaching and caring for acutely ill patients became intolerable. Rounds went from the bedside to the classroom to the cell phone. The house staff were getting cheated out of the whole point of residency—the miracle of turning medical students into attending physicians in a little over a thousand days.

Worse, though, was the ebbing of the lifeblood of the hospital. Now the medical center, riddled with “centers of excellence” instead of departments, answered only to administrators who cared nothing about medical education, except for the Medicare dollars they would lose if they cut the training programs. They spent enormous amounts of money marketing the centers of excellence, and they cut everything else to manipulate the bottom line.

The biggest casualty, of course, was the nursing staff. Underpaid, depleted of leadership and morale, they simply disappeared. They were replaced by agency nurses who worked their shifts and didn’t know the doctors or the patients. The complex bedside care of increasingly sick, old, and vulnerable patients was delegated to people with high school equivalency degrees. Nurses now cared for their patients by managing their own support staff, and spent much of their time entering useless information in the computer. The doctor-nurse collaboration I grew up with as a trainee and young attending didn’t exist any-more, and patients suffered as a result.

In 2000, the Institute of Medicine informed the public and the medical community that being a patient in an American hospital was dangerous.1 We were told that at least 44,000 and perhaps as many as 98,000 patients die annually in US hospitals as the result of preventable medical mishaps, more deaths than are attributable yearly to motor vehicle accidents, breast cancer, or AIDS.1 Although there has been an emerging body of literature pertaining to this epidemic, not much has changed, at least not in my hospital. We remain absurdly complacent about rising iatrogenic infection rates, knowing all too well that we are allowing immunocompromised patients to die unnecessarily in our intensive care units. There are alcohol-based hand-washing gels everywhere, but no police or policy with teeth in it to enforce handwashing. We lurch toward physician computer order entry, clinging to the false belief that software programs will prevent adverse drug reactions and delivery of the wrong dangerous drug to the wrong patient. We understaff our pharmacies so that they can’t get the medications to the patients on time or alert us to our own prescribing errors. We burn out our nurses despite years of loyal service. And worst of all, we capitulate to the for-profit insurance industry that informs us they won’t pay for day 4 of Mr. Jones’ hospitalization because he has failed to meet some arbitrary criteria in their manual.

I stepped down as chairman of my department 3 years ago because I couldn’t stand it any longer. I couldn’t stand the management retreats in which we obsessed about “customer service” while the waiting time in the emergency department ballooned to 12 hours because there were “no beds.” There were plenty of beds, but no nurses to staff them. I was marginalized when I protested the budget cycles bleeding out support of medical education in favor of the annual purchase of new scanners and surgical gizmos. I couldn’t get anybody fired up about patient safety.

Retreating to the privacy of clinical medicine, I realized the other day that my real job is not to diagnose, treat, and teach about diseases anymore. My real job is to do everything in my power to keep my patients out of the medical center. I walk the halls now and don’t recognize the institution I grew up in and came to love. Everywhere I look, I see not magic and promise, but dirt and danger.

I’m not a hospital guy anymore.

Editor’s note: We are interested in your thoughts on this article. See the Editor-in-Chief’s comments.

I use to be a hospital guy. I was only a few days into my third-year medicine clerkship in medical school nearly three decades ago when I fell in love with the hospital and knew I was going to be an internist. The hospital wasn’t called a medical center back then. It was a fascinating and magical place, where internists were fired in the furnace of rounds, night call, and morning report. I loved the association with the great case, the flush of excitement that accompanied the difficult diagnosis, the hard-earned annual promotion through the hierarchy of trainees seeking the rarefied air of the attending physicians. We bonded as fellow house officers more tightly than with friends outside the hospital. We prowled the wards, intensive care units, emergency room, and laboratories and never slept. The hospital was the most exclusive of clubs, and our training granted us lifelong membership.

A humming beehive of academic activity, the hospital was also a web of powerful social relationships. Everybody knew everybody, from the hospital CEO to the night security officer. The nurses called you by your first name and worked with you for weeks at a time, fostering mutual respect and sometimes even affection. In those days, nurses actually nursed their patients, spoon-feeding them broth with their medications, washing them in bed and bathroom, holding their hands and heads. Patients came to the hospital to be diagnosed and treated until they recovered from whatever illness had felled them. They stayed long enough so that you knew them and their families as well as you knew your own.

I have been a general internist and clinician-educator for 23 years, working in two university hospitals and one community hospital. That’s more than seven generations of house staff with whom I’ve toiled and learned. Somewhere along the way, I became increasingly aware that teaching clinical medicine to students, interns, and residents was getting harder and harder. The patients were sicker and stayed only 3.2 days in the hospital. What we were teaching wasn’t how to diagnose and treat diseases, but how to manage only their most serious complications—the respiratory distress from pneumonia, the ketosis of uncontrolled diabetes, the septic shock from infections. The wards became intensive care units, and the critical care units the province of “intensivists” who were more adept than we were at taming all the machinery and technology. We struggled to keep up with the unending deluge of arcane demands from the accreditation organizations watchdogging our teaching efforts. We pretended that we somehow distinguished teaching rounds from working rounds, and documented the silliness in computer files. Medical education slowly slipped from being a calling to folks like me, finally succumbing to bureaucratic lunacy. The pace of teaching and caring for acutely ill patients became intolerable. Rounds went from the bedside to the classroom to the cell phone. The house staff were getting cheated out of the whole point of residency—the miracle of turning medical students into attending physicians in a little over a thousand days.

Worse, though, was the ebbing of the lifeblood of the hospital. Now the medical center, riddled with “centers of excellence” instead of departments, answered only to administrators who cared nothing about medical education, except for the Medicare dollars they would lose if they cut the training programs. They spent enormous amounts of money marketing the centers of excellence, and they cut everything else to manipulate the bottom line.

The biggest casualty, of course, was the nursing staff. Underpaid, depleted of leadership and morale, they simply disappeared. They were replaced by agency nurses who worked their shifts and didn’t know the doctors or the patients. The complex bedside care of increasingly sick, old, and vulnerable patients was delegated to people with high school equivalency degrees. Nurses now cared for their patients by managing their own support staff, and spent much of their time entering useless information in the computer. The doctor-nurse collaboration I grew up with as a trainee and young attending didn’t exist any-more, and patients suffered as a result.

In 2000, the Institute of Medicine informed the public and the medical community that being a patient in an American hospital was dangerous.1 We were told that at least 44,000 and perhaps as many as 98,000 patients die annually in US hospitals as the result of preventable medical mishaps, more deaths than are attributable yearly to motor vehicle accidents, breast cancer, or AIDS.1 Although there has been an emerging body of literature pertaining to this epidemic, not much has changed, at least not in my hospital. We remain absurdly complacent about rising iatrogenic infection rates, knowing all too well that we are allowing immunocompromised patients to die unnecessarily in our intensive care units. There are alcohol-based hand-washing gels everywhere, but no police or policy with teeth in it to enforce handwashing. We lurch toward physician computer order entry, clinging to the false belief that software programs will prevent adverse drug reactions and delivery of the wrong dangerous drug to the wrong patient. We understaff our pharmacies so that they can’t get the medications to the patients on time or alert us to our own prescribing errors. We burn out our nurses despite years of loyal service. And worst of all, we capitulate to the for-profit insurance industry that informs us they won’t pay for day 4 of Mr. Jones’ hospitalization because he has failed to meet some arbitrary criteria in their manual.

I stepped down as chairman of my department 3 years ago because I couldn’t stand it any longer. I couldn’t stand the management retreats in which we obsessed about “customer service” while the waiting time in the emergency department ballooned to 12 hours because there were “no beds.” There were plenty of beds, but no nurses to staff them. I was marginalized when I protested the budget cycles bleeding out support of medical education in favor of the annual purchase of new scanners and surgical gizmos. I couldn’t get anybody fired up about patient safety.

Retreating to the privacy of clinical medicine, I realized the other day that my real job is not to diagnose, treat, and teach about diseases anymore. My real job is to do everything in my power to keep my patients out of the medical center. I walk the halls now and don’t recognize the institution I grew up in and came to love. Everywhere I look, I see not magic and promise, but dirt and danger.

I’m not a hospital guy anymore.

References
  1. Kohn LT, Corrigan JM, Donaldson MS, editors. To Err is Human: Building a Safer Health System. Washington, DC: National Academy Press, 2000.
References
  1. Kohn LT, Corrigan JM, Donaldson MS, editors. To Err is Human: Building a Safer Health System. Washington, DC: National Academy Press, 2000.
Issue
Cleveland Clinic Journal of Medicine - 75(9)
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Cleveland Clinic Journal of Medicine - 75(9)
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A medical center is not a hospital
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Autism Gene Mutations May Have Shared Mechanism

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Autism Gene Mutations May Have Shared Mechanism

Seemingly diverse autism mutations may share the same underlying mechanism, according to Eric M. Morrow, MD, PhD, Instructor in Psychiatry at Harvard Medical School in Boston, and colleagues.
“The regulation of expression of some autism candidate genes by neuronal membrane depolarization suggests the appealing hypothesis that neural activity–dependent regulation of synapse development may be a mechanism common to several autism mutations,” stated Dr. Morrow and colleagues in the July 11 Science. “Therefore, disruption of activity-regulated synaptic development may be one mechanism common to at least a subset of seemingly heterogeneous autism-associated mutations.”
The researchers studied 88 large families—in which both parents shared recent ancestors—to find inherited causes of autism spectrum disorders. The families, who came from Jordan, Saudi Arabia, Kuwait, Oman, Pakistan, Qatar, Turkey, and the United Arab Emirates, were selected to emphasize the role of inherited genetic mutations.
The investigators gathered data with use of homozygosity mapping and compared the DNA of family members with and without autism to identify recessive mutations. Most individuals exhibited different genetic causes with little overlap between families, but a few exceptions were observed.
“Although the large size of linked loci precluded systemic gene sequencing in most cases, we were surprised to see that several consanguineous pedigrees showed large, rare, inherited homozygous deletions within linked regions, some of which are very likely causative mutations,” Dr. Morrow and colleagues said. Specifically, such deletions linked to autism were found in five families, or 6.4% of the study sample. Family members with one remaining functional copy of their genome segments did not have autism, while those with both copies missing did have autism.
The investigators found six gene disruptions that contributed to autism spectrum disorders. The largest of these gene disruptions involved genes essential for learning in the brain, as they are regulated either directly or indirectly by neuronal activity triggered by experience. Not all the genes were deleted—the remaining genes were simply turned off, leaving room for therapies to possibly turn these genes back on.
“Early brain development is driven largely by intrinsic patterns of gene expression that do not depend on experience-driven synaptic activity,” the investigators stated. “In contrast, postnatal brain development requires input from the environment that triggers the release of neurotransmitter and promotes critical aspects of synaptic maturation.... The connection between experience-dependent neural activity and gene expression in the postnatal period forms the basis of learning and memory, and autism symptoms typically emerge during these later stages of development.”
The researchers’ findings also pointed to potential genetic similarities, such as inherited recessive causes, between autism and other neurologic disorders. Among families in the present study who had one member with autism, there was a relatively equivalent male/female ratio compared with other families with autism, indicating that parents who shared a common recent ancestor was a determining factor. In families with more than one member with autism, the male/female ratio was even more balanced.
“The accumulating number of distinct, individually rare genetic causes in autism suggests that the genetic architecture of autism resembles that of mental retardation and epilepsy, with many syndromes, each individually rare, as well as other cases potentially reflecting complex interactions between inherited changes,” Dr. Morrow and colleagues elaborated. “The relatively reduced male/female ratio of affected children and the reduced rate of linked de novo copy number variants in the consanguineous sample [of the present study] ... both suggest that consanguineous pedigrees with autism are enriched for autosomal recessive causes similar to other congenital neurological disorders in consanguineous populations.”
The research team stated that although their findings support recent studies that suggest autism is highly heterogeneous genetically, homozygosity mapping appears to be an effective way to find underlying shared mechanisms. Understanding these genetic underpinnings could eventually help direct various therapies for the different clinical manifestations of autism.
“Our finding that deletions of genes regulated by neuronal activity or regions potentially involved in regulation of gene expression in autism suggests that defects in activity-dependent gene expression may be a cause of cognitive deficits in patients with autism,” the researchers concluded. In addition, their “data implicating noncoding elements in patients with shared ancestry, as well as the heterozygous nonsense changes in patients without shared ancestry, suggest that loss of proper regulation of gene dosage may be an important genetic mechanism in autism.”

—John Merriman


References

Suggested Reading
Morrow EM, Yoo SY, Flavell SW, et al. Identifying autism loci and genes by tracing recent shared ancestry. Science. 2008;321(5886):218-223.
Sutcliffe JS. Genetics: insights into the pathogenesis of autism. Science. 2008;321(5886):208-209.

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Seemingly diverse autism mutations may share the same underlying mechanism, according to Eric M. Morrow, MD, PhD, Instructor in Psychiatry at Harvard Medical School in Boston, and colleagues.
“The regulation of expression of some autism candidate genes by neuronal membrane depolarization suggests the appealing hypothesis that neural activity–dependent regulation of synapse development may be a mechanism common to several autism mutations,” stated Dr. Morrow and colleagues in the July 11 Science. “Therefore, disruption of activity-regulated synaptic development may be one mechanism common to at least a subset of seemingly heterogeneous autism-associated mutations.”
The researchers studied 88 large families—in which both parents shared recent ancestors—to find inherited causes of autism spectrum disorders. The families, who came from Jordan, Saudi Arabia, Kuwait, Oman, Pakistan, Qatar, Turkey, and the United Arab Emirates, were selected to emphasize the role of inherited genetic mutations.
The investigators gathered data with use of homozygosity mapping and compared the DNA of family members with and without autism to identify recessive mutations. Most individuals exhibited different genetic causes with little overlap between families, but a few exceptions were observed.
“Although the large size of linked loci precluded systemic gene sequencing in most cases, we were surprised to see that several consanguineous pedigrees showed large, rare, inherited homozygous deletions within linked regions, some of which are very likely causative mutations,” Dr. Morrow and colleagues said. Specifically, such deletions linked to autism were found in five families, or 6.4% of the study sample. Family members with one remaining functional copy of their genome segments did not have autism, while those with both copies missing did have autism.
The investigators found six gene disruptions that contributed to autism spectrum disorders. The largest of these gene disruptions involved genes essential for learning in the brain, as they are regulated either directly or indirectly by neuronal activity triggered by experience. Not all the genes were deleted—the remaining genes were simply turned off, leaving room for therapies to possibly turn these genes back on.
“Early brain development is driven largely by intrinsic patterns of gene expression that do not depend on experience-driven synaptic activity,” the investigators stated. “In contrast, postnatal brain development requires input from the environment that triggers the release of neurotransmitter and promotes critical aspects of synaptic maturation.... The connection between experience-dependent neural activity and gene expression in the postnatal period forms the basis of learning and memory, and autism symptoms typically emerge during these later stages of development.”
The researchers’ findings also pointed to potential genetic similarities, such as inherited recessive causes, between autism and other neurologic disorders. Among families in the present study who had one member with autism, there was a relatively equivalent male/female ratio compared with other families with autism, indicating that parents who shared a common recent ancestor was a determining factor. In families with more than one member with autism, the male/female ratio was even more balanced.
“The accumulating number of distinct, individually rare genetic causes in autism suggests that the genetic architecture of autism resembles that of mental retardation and epilepsy, with many syndromes, each individually rare, as well as other cases potentially reflecting complex interactions between inherited changes,” Dr. Morrow and colleagues elaborated. “The relatively reduced male/female ratio of affected children and the reduced rate of linked de novo copy number variants in the consanguineous sample [of the present study] ... both suggest that consanguineous pedigrees with autism are enriched for autosomal recessive causes similar to other congenital neurological disorders in consanguineous populations.”
The research team stated that although their findings support recent studies that suggest autism is highly heterogeneous genetically, homozygosity mapping appears to be an effective way to find underlying shared mechanisms. Understanding these genetic underpinnings could eventually help direct various therapies for the different clinical manifestations of autism.
“Our finding that deletions of genes regulated by neuronal activity or regions potentially involved in regulation of gene expression in autism suggests that defects in activity-dependent gene expression may be a cause of cognitive deficits in patients with autism,” the researchers concluded. In addition, their “data implicating noncoding elements in patients with shared ancestry, as well as the heterozygous nonsense changes in patients without shared ancestry, suggest that loss of proper regulation of gene dosage may be an important genetic mechanism in autism.”

—John Merriman


Seemingly diverse autism mutations may share the same underlying mechanism, according to Eric M. Morrow, MD, PhD, Instructor in Psychiatry at Harvard Medical School in Boston, and colleagues.
“The regulation of expression of some autism candidate genes by neuronal membrane depolarization suggests the appealing hypothesis that neural activity–dependent regulation of synapse development may be a mechanism common to several autism mutations,” stated Dr. Morrow and colleagues in the July 11 Science. “Therefore, disruption of activity-regulated synaptic development may be one mechanism common to at least a subset of seemingly heterogeneous autism-associated mutations.”
The researchers studied 88 large families—in which both parents shared recent ancestors—to find inherited causes of autism spectrum disorders. The families, who came from Jordan, Saudi Arabia, Kuwait, Oman, Pakistan, Qatar, Turkey, and the United Arab Emirates, were selected to emphasize the role of inherited genetic mutations.
The investigators gathered data with use of homozygosity mapping and compared the DNA of family members with and without autism to identify recessive mutations. Most individuals exhibited different genetic causes with little overlap between families, but a few exceptions were observed.
“Although the large size of linked loci precluded systemic gene sequencing in most cases, we were surprised to see that several consanguineous pedigrees showed large, rare, inherited homozygous deletions within linked regions, some of which are very likely causative mutations,” Dr. Morrow and colleagues said. Specifically, such deletions linked to autism were found in five families, or 6.4% of the study sample. Family members with one remaining functional copy of their genome segments did not have autism, while those with both copies missing did have autism.
The investigators found six gene disruptions that contributed to autism spectrum disorders. The largest of these gene disruptions involved genes essential for learning in the brain, as they are regulated either directly or indirectly by neuronal activity triggered by experience. Not all the genes were deleted—the remaining genes were simply turned off, leaving room for therapies to possibly turn these genes back on.
“Early brain development is driven largely by intrinsic patterns of gene expression that do not depend on experience-driven synaptic activity,” the investigators stated. “In contrast, postnatal brain development requires input from the environment that triggers the release of neurotransmitter and promotes critical aspects of synaptic maturation.... The connection between experience-dependent neural activity and gene expression in the postnatal period forms the basis of learning and memory, and autism symptoms typically emerge during these later stages of development.”
The researchers’ findings also pointed to potential genetic similarities, such as inherited recessive causes, between autism and other neurologic disorders. Among families in the present study who had one member with autism, there was a relatively equivalent male/female ratio compared with other families with autism, indicating that parents who shared a common recent ancestor was a determining factor. In families with more than one member with autism, the male/female ratio was even more balanced.
“The accumulating number of distinct, individually rare genetic causes in autism suggests that the genetic architecture of autism resembles that of mental retardation and epilepsy, with many syndromes, each individually rare, as well as other cases potentially reflecting complex interactions between inherited changes,” Dr. Morrow and colleagues elaborated. “The relatively reduced male/female ratio of affected children and the reduced rate of linked de novo copy number variants in the consanguineous sample [of the present study] ... both suggest that consanguineous pedigrees with autism are enriched for autosomal recessive causes similar to other congenital neurological disorders in consanguineous populations.”
The research team stated that although their findings support recent studies that suggest autism is highly heterogeneous genetically, homozygosity mapping appears to be an effective way to find underlying shared mechanisms. Understanding these genetic underpinnings could eventually help direct various therapies for the different clinical manifestations of autism.
“Our finding that deletions of genes regulated by neuronal activity or regions potentially involved in regulation of gene expression in autism suggests that defects in activity-dependent gene expression may be a cause of cognitive deficits in patients with autism,” the researchers concluded. In addition, their “data implicating noncoding elements in patients with shared ancestry, as well as the heterozygous nonsense changes in patients without shared ancestry, suggest that loss of proper regulation of gene dosage may be an important genetic mechanism in autism.”

—John Merriman


References

Suggested Reading
Morrow EM, Yoo SY, Flavell SW, et al. Identifying autism loci and genes by tracing recent shared ancestry. Science. 2008;321(5886):218-223.
Sutcliffe JS. Genetics: insights into the pathogenesis of autism. Science. 2008;321(5886):208-209.

References

Suggested Reading
Morrow EM, Yoo SY, Flavell SW, et al. Identifying autism loci and genes by tracing recent shared ancestry. Science. 2008;321(5886):218-223.
Sutcliffe JS. Genetics: insights into the pathogenesis of autism. Science. 2008;321(5886):208-209.

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May 2008 Instant Poll Results

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FAILED HOME BIRTH, NOW IN THE ED

You are at the hospital, caring for your patients in labor, when a 32-year-old G3P2 with two prior cesarean section deliveries is brought to the emergency department in labor after a failed home birth.

“Will you assume care for this woman?” the nursing administrator asks you. Quickly! What would you do?



7%  Refuse to accept responsibility for a high-risk patient whom you’ve never seen

29%  Assume her care and recommend cesarean section

46%  Assume her care and recommend cesarean section—plus, later, report the responsible midwife to the department of public health and her credentialing organization

18%  Agree to assume her care as long as the hospital’s attorney and risk management team indemnify you

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FAILED HOME BIRTH, NOW IN THE ED

You are at the hospital, caring for your patients in labor, when a 32-year-old G3P2 with two prior cesarean section deliveries is brought to the emergency department in labor after a failed home birth.

“Will you assume care for this woman?” the nursing administrator asks you. Quickly! What would you do?



7%  Refuse to accept responsibility for a high-risk patient whom you’ve never seen

29%  Assume her care and recommend cesarean section

46%  Assume her care and recommend cesarean section—plus, later, report the responsible midwife to the department of public health and her credentialing organization

18%  Agree to assume her care as long as the hospital’s attorney and risk management team indemnify you

FAILED HOME BIRTH, NOW IN THE ED

You are at the hospital, caring for your patients in labor, when a 32-year-old G3P2 with two prior cesarean section deliveries is brought to the emergency department in labor after a failed home birth.

“Will you assume care for this woman?” the nursing administrator asks you. Quickly! What would you do?



7%  Refuse to accept responsibility for a high-risk patient whom you’ve never seen

29%  Assume her care and recommend cesarean section

46%  Assume her care and recommend cesarean section—plus, later, report the responsible midwife to the department of public health and her credentialing organization

18%  Agree to assume her care as long as the hospital’s attorney and risk management team indemnify you

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Come October 1, a multitude of ICD-9 code additions and revisions arrive

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The author reports no financial relationships relevant to this article.

OBs get codes for unremarkable sonograms ordered on the basis of suspicion. For gyn practice, options expand for abnormal Pap smear results. Here are the details.

Revisions and additions to the International Classification of Diseases, Clinical Modification (ICD-9-CM) for 2009, which take effect on October 1, 2008, bring especially good news to obstetricians who are testing for “conditions not found,” evaluating or treating twin-to-twin transfusion syndrome, dealing with the aftermath of maternal surgery, and providing the correct diagnostic code match for screening tests.

Gyn practitioners, don’t feel slighted: Many new codes take effect on that October day, covering abnormal Pap smear results, prophylactic drug treatment, breast conditions, and taking a patient’s personal history.

Remember: 1) October 1 is the key date here—when all the new and revised codes described in this article (and others not reviewed here) are added to the national code set, and 2) as in past years, there will be no grace period!

New and revised OB codes

FOR “CONDITIONS NOT FOUND”

How many times have you ordered a sonogram for a suspected problem with a pregnancy, only to have the scan reveal that all is normal? You then had to use either 1) a screening code for the condition or 2) an unspecified code because you could not assign a code that gave a condition to the patient that she did not have.

With addition of a new category of codes (V89), this obstetrical problem will be solved.

V89.01  Suspected problem with amniotic cavity and membrane not found

V89.02  Suspected placenta not found

V89.03  Suspected fetal anomaly not found

V89.04  Suspected problem with fetal growth not found

V89.05  Suspected cervical shortening not found

V89.09  Other suspected maternal and fetal condition not found

CERVICAL SHORTENING

Women undergo cervical shortening normally as their body prepares for labor, of course, but, on occasion, cervical shortening can indicate impending premature birth. Until now, you might have reflected this condition with 654.5x (Cervical incompetence complicating pregnancy), 654.6x (Other congenital or acquired abnormality of cervix), or 644.1x (Other threatened labor). Starting October 1, however, you’ll have a more precise code available to report this condition: 649.7x (Cervical shortening).

HIGH-RISK PREGNANCY

The V23 category of codes, which represent supervision of high-risk pregnancy, becomes more specific with two additions: V23.85 (Pregnancy resulting from assisted reproductive technology) and V23.86 (Pregnancy with history of in utero procedure during previous pregnancy).

ANTENATAL SCREENING

How to select the right code to report a screening test has been less than clear. Were you performing it to screen for malformation of a fetus? Some other reason? Three new antenatal codes and revision of an existing code (V28.3) clarify the distinction.

V28.3  Encounter for routine screening for malformation using ultrasonics

V28.81  Encounter for fetal anatomic survey

V28.82  Encounter for screening for risk of preterm labor

V28.89  Other specified antenatal screening

ICD-9-CM now directs that the latter code, V28.89, be reported for screening as part of chorionic villus sampling, nuchal translucency testing, genomic screening, and proteomic screening.

COMPLICATIONS OF PREGNANCY AND IN UTERO PROCEDURES

At last, you have a specific code for fetal conjoined twins (678.1x) and one for such fetal hematologic conditions as fetal anemia, thrombocytopenia, and twin-to-twin transfusion syndrome (678.0x).

In addition, complications from an in utero procedure will have two new codes: 679.0x (Maternal complications from in utero procedure) and 679.1x (Fetal complications from in utero procedure).

Gynecologic code changes and additions

ABNORMAL RESULTS OF A PAP SMEAR

You already know to look at the 795 series for ICD-9 codes to support various abnormal Pap smear results; after October 1, you’ll have a lot of new options.

Key developments:

  • The risk of dysplasia and carcinoma is the same for the anus as it is for the cervix, so physicians can take anal cytologic smears.
  • The cervix and the anus both have transformation zones where mucosa turns from squamous to columnar, so parallel codes have been created for anal smears.
In creating these new codes, ICD-9-CM modified existing abnormal cervical cytology codes to indicate a result in which the transformation zone is absent in the specimen. But, because the vagina and vulva do not have transitional zones, ICD-9-CM expanded and redefined subcategory 795.1 for an abnormal smear of the vagina and vulva. Until now, 795.1 was reported for any abnormal Pap result from a site other than the cervix.

The new codes are listed below.

CERVIX

795.07  Satisfactory cervical smear but lacking transformation zone

VAGINA AND VULVA

795.10  Abnormal Papanicolaou smear of vagina

795.11  Papanicolaou smear of vagina with atypical squamous cells of undetermined significance (ASC-US)

 

 

795.12  Papanicolaou smear of vagina with atypical squamous cells cannot exclude high grade squamous intraepithelial lesion (ASC-H)

795.13  Papanicolaou smear of vagina with low grade squamous intraepithelial lesion (LGSIL)

795.14  Papanicolaou smear of vagina with high grade squamous intraepithelial lesion (HGSIL)

795.15  Vaginal high risk papillomavirus (HPV) DNA test positive

795.16  Papanicolaou smear of vagina with cytologic evidence of malignancy

795.18  Unsatisfactory cytology smear

795.19  Other abnormal smear of vagina and vaginal HPV

ANUS

796.70  Abnormal glandular Papanicolaou smear of anus

796.71  Papanicolaou smear of anus with atypical squamous cells of undetermined significance (ASC-US)

796.72  Papanicolaou smear of anus with atypical squamous cells cannot exclude high grade squamous intraepithelial lesion (ASC-H)

796.73  Papanicolaou smear of anus with low grade squamous intraepithelial lesion (LGSIL)

796.74  Papanicolaou smear of anus with high grade squamous intraepithelial lesion (HGSIL)

796.75  Anal high risk human papillomavirus (HPV) DNA test positive

796.76  Papanicolaou smear of anus with cytologic evidence of malignancy

796.77  Satisfactory anal smear but lacking transformation zone

796.78  Unsatisfactory anal cytology smear

796.79  Other abnormal Papanicolaou smear of anus and anal HPV

There is also a new code, 569.44 (Dysplasia of anus), to report anal dysplasia. In the past, this condition was reported using 569.49 (Other specified disorders of rectum and anus).

ACQUIRED ABSENCE CODES

Until now, only V45.77 (Acquired absence of genital organs) could be used to report this patient status. As of October 1, you’ll have to be more specific about what is absent, using any of the following three new codes. You might find these codes helpful in supporting the performance of screening Pap smears:

V88.01  Acquired absence of both cervix and uterus

V88.02  Acquired absence of uterus with remaining cervical stump

V88.03  Acquired absence of cervix with remaining uterus

These new codes can be reported in conjunction with V67.01 (Follow-up vaginal Pap smear) and V76.47 (Special screening for malignant neoplasm of vagina).

URINARY PROBLEMS

Use these three new codes to report various presentations of hematuria:

599.70  Hematuria, unspecified

599.71  Gross hematuria

599.72  Microscopic hematuria

Note: The old code for hematuria (599.7) did not require a fifth digit; after October 1, using that old code will trigger a denial of your claim.

In addition, you have two new codes with which to report urinary symptoms:

788.91  Functional urinary incontinence

788.99  Other symptoms involving urinary symptoms

VULVODYNIA AND VULVAR VESTIBULITIS

A single code (625.8) has been available to describe vulvodynia, and it was grouped into a general category that covered symptoms. This condition has been given three new codes.

625.70  Vulvodynia, unspecified

625.71  Vulvar vestibulitis

625.79  Other vulvodynia

BREAST DISORDERS

New codes for breast conditions are about to take effect. These include ptosis (611.81), hypoplasia (611.82), and other disorders of the breast, such as capsular contracture of a breast implant (611.89).

For surgeons who handle follow-up after breast surgery, two new codes describe problems with the reconstructed breast: 612.0 (Deformity of reconstructed breast) and 612.1 (Disproportion of reconstructed breast).

WOUND DISRUPTION

Under current ICD-9-CM guidelines, you must specify “external wound” or “internal wound” to code correctly for dehiscence. On October 1, you have the option to report an unspecified code, 998.30 (Disruption of wound, unspecified) if the record does not specify the type of wound.

PROPHYLACTIC USE OF AGENTS AFFECTING ESTROGEN RECEPTORS AND ESTROGEN LEVELS

ICD-9-CM created a V code to capture data on the many women who receive tamoxifen and raloxifene after treatment of breast cancer. This code has been expanded to include V codes for different classes of drugs used for this type of therapy:

V07.51  Prophylactic use of selective estrogen receptor modulators (SERMs)

V07.52  Prophylactic use of aromatase inhibitors

V07.59  Prophylactic use of agents affecting estrogen receptors and estrogen levels

From a guideline perspective, you can use the cancer code with one of these codes throughout the course of treatment, including during routine chemotherapy and radiation therapy. Long-term use of a drug that falls under the V07.5x category doesn’t require continued use of the cancer code, however.

You can provide additional information on your patient by reporting her estrogen receptor-positive status (V86.0), personal or family history of breast cancer (V10.3/V16.3), genetic susceptibility to cancer (V84.01–V84.09), and postmenopausal status (V49.81).

TAKING A PERSONAL HISTORY

This year, 11 codes make their debut to allow you to report a patient’s personal history. Use them for encounters in which the personal history has a direct impact on the patient’s complaints or status.

V13.51  Personal history of pathologic fracture

V13.52  Personal history of stress fracture

V13.59  Personal history of other musculoskeletal disorders

V15.51  Personal history of traumatic fracture

V15.59  Personal history of other injury

V15.21  Personal history of undergoing in utero procedure during pregnancy

V15.22  Personal history of undergoing in utero procedure while a fetus

V15.29  Personal history of surgery to other organs

 

 

V87.41  Personal history of antineoplastic chemotherapy

V87.42  Personal history of monoclonal drug therapy

V87.49  Personal history of other drug therapy

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OBs get codes for unremarkable sonograms ordered on the basis of suspicion. For gyn practice, options expand for abnormal Pap smear results. Here are the details.

Revisions and additions to the International Classification of Diseases, Clinical Modification (ICD-9-CM) for 2009, which take effect on October 1, 2008, bring especially good news to obstetricians who are testing for “conditions not found,” evaluating or treating twin-to-twin transfusion syndrome, dealing with the aftermath of maternal surgery, and providing the correct diagnostic code match for screening tests.

Gyn practitioners, don’t feel slighted: Many new codes take effect on that October day, covering abnormal Pap smear results, prophylactic drug treatment, breast conditions, and taking a patient’s personal history.

Remember: 1) October 1 is the key date here—when all the new and revised codes described in this article (and others not reviewed here) are added to the national code set, and 2) as in past years, there will be no grace period!

New and revised OB codes

FOR “CONDITIONS NOT FOUND”

How many times have you ordered a sonogram for a suspected problem with a pregnancy, only to have the scan reveal that all is normal? You then had to use either 1) a screening code for the condition or 2) an unspecified code because you could not assign a code that gave a condition to the patient that she did not have.

With addition of a new category of codes (V89), this obstetrical problem will be solved.

V89.01  Suspected problem with amniotic cavity and membrane not found

V89.02  Suspected placenta not found

V89.03  Suspected fetal anomaly not found

V89.04  Suspected problem with fetal growth not found

V89.05  Suspected cervical shortening not found

V89.09  Other suspected maternal and fetal condition not found

CERVICAL SHORTENING

Women undergo cervical shortening normally as their body prepares for labor, of course, but, on occasion, cervical shortening can indicate impending premature birth. Until now, you might have reflected this condition with 654.5x (Cervical incompetence complicating pregnancy), 654.6x (Other congenital or acquired abnormality of cervix), or 644.1x (Other threatened labor). Starting October 1, however, you’ll have a more precise code available to report this condition: 649.7x (Cervical shortening).

HIGH-RISK PREGNANCY

The V23 category of codes, which represent supervision of high-risk pregnancy, becomes more specific with two additions: V23.85 (Pregnancy resulting from assisted reproductive technology) and V23.86 (Pregnancy with history of in utero procedure during previous pregnancy).

ANTENATAL SCREENING

How to select the right code to report a screening test has been less than clear. Were you performing it to screen for malformation of a fetus? Some other reason? Three new antenatal codes and revision of an existing code (V28.3) clarify the distinction.

V28.3  Encounter for routine screening for malformation using ultrasonics

V28.81  Encounter for fetal anatomic survey

V28.82  Encounter for screening for risk of preterm labor

V28.89  Other specified antenatal screening

ICD-9-CM now directs that the latter code, V28.89, be reported for screening as part of chorionic villus sampling, nuchal translucency testing, genomic screening, and proteomic screening.

COMPLICATIONS OF PREGNANCY AND IN UTERO PROCEDURES

At last, you have a specific code for fetal conjoined twins (678.1x) and one for such fetal hematologic conditions as fetal anemia, thrombocytopenia, and twin-to-twin transfusion syndrome (678.0x).

In addition, complications from an in utero procedure will have two new codes: 679.0x (Maternal complications from in utero procedure) and 679.1x (Fetal complications from in utero procedure).

Gynecologic code changes and additions

ABNORMAL RESULTS OF A PAP SMEAR

You already know to look at the 795 series for ICD-9 codes to support various abnormal Pap smear results; after October 1, you’ll have a lot of new options.

Key developments:

  • The risk of dysplasia and carcinoma is the same for the anus as it is for the cervix, so physicians can take anal cytologic smears.
  • The cervix and the anus both have transformation zones where mucosa turns from squamous to columnar, so parallel codes have been created for anal smears.
In creating these new codes, ICD-9-CM modified existing abnormal cervical cytology codes to indicate a result in which the transformation zone is absent in the specimen. But, because the vagina and vulva do not have transitional zones, ICD-9-CM expanded and redefined subcategory 795.1 for an abnormal smear of the vagina and vulva. Until now, 795.1 was reported for any abnormal Pap result from a site other than the cervix.

The new codes are listed below.

CERVIX

795.07  Satisfactory cervical smear but lacking transformation zone

VAGINA AND VULVA

795.10  Abnormal Papanicolaou smear of vagina

795.11  Papanicolaou smear of vagina with atypical squamous cells of undetermined significance (ASC-US)

 

 

795.12  Papanicolaou smear of vagina with atypical squamous cells cannot exclude high grade squamous intraepithelial lesion (ASC-H)

795.13  Papanicolaou smear of vagina with low grade squamous intraepithelial lesion (LGSIL)

795.14  Papanicolaou smear of vagina with high grade squamous intraepithelial lesion (HGSIL)

795.15  Vaginal high risk papillomavirus (HPV) DNA test positive

795.16  Papanicolaou smear of vagina with cytologic evidence of malignancy

795.18  Unsatisfactory cytology smear

795.19  Other abnormal smear of vagina and vaginal HPV

ANUS

796.70  Abnormal glandular Papanicolaou smear of anus

796.71  Papanicolaou smear of anus with atypical squamous cells of undetermined significance (ASC-US)

796.72  Papanicolaou smear of anus with atypical squamous cells cannot exclude high grade squamous intraepithelial lesion (ASC-H)

796.73  Papanicolaou smear of anus with low grade squamous intraepithelial lesion (LGSIL)

796.74  Papanicolaou smear of anus with high grade squamous intraepithelial lesion (HGSIL)

796.75  Anal high risk human papillomavirus (HPV) DNA test positive

796.76  Papanicolaou smear of anus with cytologic evidence of malignancy

796.77  Satisfactory anal smear but lacking transformation zone

796.78  Unsatisfactory anal cytology smear

796.79  Other abnormal Papanicolaou smear of anus and anal HPV

There is also a new code, 569.44 (Dysplasia of anus), to report anal dysplasia. In the past, this condition was reported using 569.49 (Other specified disorders of rectum and anus).

ACQUIRED ABSENCE CODES

Until now, only V45.77 (Acquired absence of genital organs) could be used to report this patient status. As of October 1, you’ll have to be more specific about what is absent, using any of the following three new codes. You might find these codes helpful in supporting the performance of screening Pap smears:

V88.01  Acquired absence of both cervix and uterus

V88.02  Acquired absence of uterus with remaining cervical stump

V88.03  Acquired absence of cervix with remaining uterus

These new codes can be reported in conjunction with V67.01 (Follow-up vaginal Pap smear) and V76.47 (Special screening for malignant neoplasm of vagina).

URINARY PROBLEMS

Use these three new codes to report various presentations of hematuria:

599.70  Hematuria, unspecified

599.71  Gross hematuria

599.72  Microscopic hematuria

Note: The old code for hematuria (599.7) did not require a fifth digit; after October 1, using that old code will trigger a denial of your claim.

In addition, you have two new codes with which to report urinary symptoms:

788.91  Functional urinary incontinence

788.99  Other symptoms involving urinary symptoms

VULVODYNIA AND VULVAR VESTIBULITIS

A single code (625.8) has been available to describe vulvodynia, and it was grouped into a general category that covered symptoms. This condition has been given three new codes.

625.70  Vulvodynia, unspecified

625.71  Vulvar vestibulitis

625.79  Other vulvodynia

BREAST DISORDERS

New codes for breast conditions are about to take effect. These include ptosis (611.81), hypoplasia (611.82), and other disorders of the breast, such as capsular contracture of a breast implant (611.89).

For surgeons who handle follow-up after breast surgery, two new codes describe problems with the reconstructed breast: 612.0 (Deformity of reconstructed breast) and 612.1 (Disproportion of reconstructed breast).

WOUND DISRUPTION

Under current ICD-9-CM guidelines, you must specify “external wound” or “internal wound” to code correctly for dehiscence. On October 1, you have the option to report an unspecified code, 998.30 (Disruption of wound, unspecified) if the record does not specify the type of wound.

PROPHYLACTIC USE OF AGENTS AFFECTING ESTROGEN RECEPTORS AND ESTROGEN LEVELS

ICD-9-CM created a V code to capture data on the many women who receive tamoxifen and raloxifene after treatment of breast cancer. This code has been expanded to include V codes for different classes of drugs used for this type of therapy:

V07.51  Prophylactic use of selective estrogen receptor modulators (SERMs)

V07.52  Prophylactic use of aromatase inhibitors

V07.59  Prophylactic use of agents affecting estrogen receptors and estrogen levels

From a guideline perspective, you can use the cancer code with one of these codes throughout the course of treatment, including during routine chemotherapy and radiation therapy. Long-term use of a drug that falls under the V07.5x category doesn’t require continued use of the cancer code, however.

You can provide additional information on your patient by reporting her estrogen receptor-positive status (V86.0), personal or family history of breast cancer (V10.3/V16.3), genetic susceptibility to cancer (V84.01–V84.09), and postmenopausal status (V49.81).

TAKING A PERSONAL HISTORY

This year, 11 codes make their debut to allow you to report a patient’s personal history. Use them for encounters in which the personal history has a direct impact on the patient’s complaints or status.

V13.51  Personal history of pathologic fracture

V13.52  Personal history of stress fracture

V13.59  Personal history of other musculoskeletal disorders

V15.51  Personal history of traumatic fracture

V15.59  Personal history of other injury

V15.21  Personal history of undergoing in utero procedure during pregnancy

V15.22  Personal history of undergoing in utero procedure while a fetus

V15.29  Personal history of surgery to other organs

 

 

V87.41  Personal history of antineoplastic chemotherapy

V87.42  Personal history of monoclonal drug therapy

V87.49  Personal history of other drug therapy

The author reports no financial relationships relevant to this article.

OBs get codes for unremarkable sonograms ordered on the basis of suspicion. For gyn practice, options expand for abnormal Pap smear results. Here are the details.

Revisions and additions to the International Classification of Diseases, Clinical Modification (ICD-9-CM) for 2009, which take effect on October 1, 2008, bring especially good news to obstetricians who are testing for “conditions not found,” evaluating or treating twin-to-twin transfusion syndrome, dealing with the aftermath of maternal surgery, and providing the correct diagnostic code match for screening tests.

Gyn practitioners, don’t feel slighted: Many new codes take effect on that October day, covering abnormal Pap smear results, prophylactic drug treatment, breast conditions, and taking a patient’s personal history.

Remember: 1) October 1 is the key date here—when all the new and revised codes described in this article (and others not reviewed here) are added to the national code set, and 2) as in past years, there will be no grace period!

New and revised OB codes

FOR “CONDITIONS NOT FOUND”

How many times have you ordered a sonogram for a suspected problem with a pregnancy, only to have the scan reveal that all is normal? You then had to use either 1) a screening code for the condition or 2) an unspecified code because you could not assign a code that gave a condition to the patient that she did not have.

With addition of a new category of codes (V89), this obstetrical problem will be solved.

V89.01  Suspected problem with amniotic cavity and membrane not found

V89.02  Suspected placenta not found

V89.03  Suspected fetal anomaly not found

V89.04  Suspected problem with fetal growth not found

V89.05  Suspected cervical shortening not found

V89.09  Other suspected maternal and fetal condition not found

CERVICAL SHORTENING

Women undergo cervical shortening normally as their body prepares for labor, of course, but, on occasion, cervical shortening can indicate impending premature birth. Until now, you might have reflected this condition with 654.5x (Cervical incompetence complicating pregnancy), 654.6x (Other congenital or acquired abnormality of cervix), or 644.1x (Other threatened labor). Starting October 1, however, you’ll have a more precise code available to report this condition: 649.7x (Cervical shortening).

HIGH-RISK PREGNANCY

The V23 category of codes, which represent supervision of high-risk pregnancy, becomes more specific with two additions: V23.85 (Pregnancy resulting from assisted reproductive technology) and V23.86 (Pregnancy with history of in utero procedure during previous pregnancy).

ANTENATAL SCREENING

How to select the right code to report a screening test has been less than clear. Were you performing it to screen for malformation of a fetus? Some other reason? Three new antenatal codes and revision of an existing code (V28.3) clarify the distinction.

V28.3  Encounter for routine screening for malformation using ultrasonics

V28.81  Encounter for fetal anatomic survey

V28.82  Encounter for screening for risk of preterm labor

V28.89  Other specified antenatal screening

ICD-9-CM now directs that the latter code, V28.89, be reported for screening as part of chorionic villus sampling, nuchal translucency testing, genomic screening, and proteomic screening.

COMPLICATIONS OF PREGNANCY AND IN UTERO PROCEDURES

At last, you have a specific code for fetal conjoined twins (678.1x) and one for such fetal hematologic conditions as fetal anemia, thrombocytopenia, and twin-to-twin transfusion syndrome (678.0x).

In addition, complications from an in utero procedure will have two new codes: 679.0x (Maternal complications from in utero procedure) and 679.1x (Fetal complications from in utero procedure).

Gynecologic code changes and additions

ABNORMAL RESULTS OF A PAP SMEAR

You already know to look at the 795 series for ICD-9 codes to support various abnormal Pap smear results; after October 1, you’ll have a lot of new options.

Key developments:

  • The risk of dysplasia and carcinoma is the same for the anus as it is for the cervix, so physicians can take anal cytologic smears.
  • The cervix and the anus both have transformation zones where mucosa turns from squamous to columnar, so parallel codes have been created for anal smears.
In creating these new codes, ICD-9-CM modified existing abnormal cervical cytology codes to indicate a result in which the transformation zone is absent in the specimen. But, because the vagina and vulva do not have transitional zones, ICD-9-CM expanded and redefined subcategory 795.1 for an abnormal smear of the vagina and vulva. Until now, 795.1 was reported for any abnormal Pap result from a site other than the cervix.

The new codes are listed below.

CERVIX

795.07  Satisfactory cervical smear but lacking transformation zone

VAGINA AND VULVA

795.10  Abnormal Papanicolaou smear of vagina

795.11  Papanicolaou smear of vagina with atypical squamous cells of undetermined significance (ASC-US)

 

 

795.12  Papanicolaou smear of vagina with atypical squamous cells cannot exclude high grade squamous intraepithelial lesion (ASC-H)

795.13  Papanicolaou smear of vagina with low grade squamous intraepithelial lesion (LGSIL)

795.14  Papanicolaou smear of vagina with high grade squamous intraepithelial lesion (HGSIL)

795.15  Vaginal high risk papillomavirus (HPV) DNA test positive

795.16  Papanicolaou smear of vagina with cytologic evidence of malignancy

795.18  Unsatisfactory cytology smear

795.19  Other abnormal smear of vagina and vaginal HPV

ANUS

796.70  Abnormal glandular Papanicolaou smear of anus

796.71  Papanicolaou smear of anus with atypical squamous cells of undetermined significance (ASC-US)

796.72  Papanicolaou smear of anus with atypical squamous cells cannot exclude high grade squamous intraepithelial lesion (ASC-H)

796.73  Papanicolaou smear of anus with low grade squamous intraepithelial lesion (LGSIL)

796.74  Papanicolaou smear of anus with high grade squamous intraepithelial lesion (HGSIL)

796.75  Anal high risk human papillomavirus (HPV) DNA test positive

796.76  Papanicolaou smear of anus with cytologic evidence of malignancy

796.77  Satisfactory anal smear but lacking transformation zone

796.78  Unsatisfactory anal cytology smear

796.79  Other abnormal Papanicolaou smear of anus and anal HPV

There is also a new code, 569.44 (Dysplasia of anus), to report anal dysplasia. In the past, this condition was reported using 569.49 (Other specified disorders of rectum and anus).

ACQUIRED ABSENCE CODES

Until now, only V45.77 (Acquired absence of genital organs) could be used to report this patient status. As of October 1, you’ll have to be more specific about what is absent, using any of the following three new codes. You might find these codes helpful in supporting the performance of screening Pap smears:

V88.01  Acquired absence of both cervix and uterus

V88.02  Acquired absence of uterus with remaining cervical stump

V88.03  Acquired absence of cervix with remaining uterus

These new codes can be reported in conjunction with V67.01 (Follow-up vaginal Pap smear) and V76.47 (Special screening for malignant neoplasm of vagina).

URINARY PROBLEMS

Use these three new codes to report various presentations of hematuria:

599.70  Hematuria, unspecified

599.71  Gross hematuria

599.72  Microscopic hematuria

Note: The old code for hematuria (599.7) did not require a fifth digit; after October 1, using that old code will trigger a denial of your claim.

In addition, you have two new codes with which to report urinary symptoms:

788.91  Functional urinary incontinence

788.99  Other symptoms involving urinary symptoms

VULVODYNIA AND VULVAR VESTIBULITIS

A single code (625.8) has been available to describe vulvodynia, and it was grouped into a general category that covered symptoms. This condition has been given three new codes.

625.70  Vulvodynia, unspecified

625.71  Vulvar vestibulitis

625.79  Other vulvodynia

BREAST DISORDERS

New codes for breast conditions are about to take effect. These include ptosis (611.81), hypoplasia (611.82), and other disorders of the breast, such as capsular contracture of a breast implant (611.89).

For surgeons who handle follow-up after breast surgery, two new codes describe problems with the reconstructed breast: 612.0 (Deformity of reconstructed breast) and 612.1 (Disproportion of reconstructed breast).

WOUND DISRUPTION

Under current ICD-9-CM guidelines, you must specify “external wound” or “internal wound” to code correctly for dehiscence. On October 1, you have the option to report an unspecified code, 998.30 (Disruption of wound, unspecified) if the record does not specify the type of wound.

PROPHYLACTIC USE OF AGENTS AFFECTING ESTROGEN RECEPTORS AND ESTROGEN LEVELS

ICD-9-CM created a V code to capture data on the many women who receive tamoxifen and raloxifene after treatment of breast cancer. This code has been expanded to include V codes for different classes of drugs used for this type of therapy:

V07.51  Prophylactic use of selective estrogen receptor modulators (SERMs)

V07.52  Prophylactic use of aromatase inhibitors

V07.59  Prophylactic use of agents affecting estrogen receptors and estrogen levels

From a guideline perspective, you can use the cancer code with one of these codes throughout the course of treatment, including during routine chemotherapy and radiation therapy. Long-term use of a drug that falls under the V07.5x category doesn’t require continued use of the cancer code, however.

You can provide additional information on your patient by reporting her estrogen receptor-positive status (V86.0), personal or family history of breast cancer (V10.3/V16.3), genetic susceptibility to cancer (V84.01–V84.09), and postmenopausal status (V49.81).

TAKING A PERSONAL HISTORY

This year, 11 codes make their debut to allow you to report a patient’s personal history. Use them for encounters in which the personal history has a direct impact on the patient’s complaints or status.

V13.51  Personal history of pathologic fracture

V13.52  Personal history of stress fracture

V13.59  Personal history of other musculoskeletal disorders

V15.51  Personal history of traumatic fracture

V15.59  Personal history of other injury

V15.21  Personal history of undergoing in utero procedure during pregnancy

V15.22  Personal history of undergoing in utero procedure while a fetus

V15.29  Personal history of surgery to other organs

 

 

V87.41  Personal history of antineoplastic chemotherapy

V87.42  Personal history of monoclonal drug therapy

V87.49  Personal history of other drug therapy

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Melanie Witt RN CPC-OBGYN MA; Reimbursement Adviser; reimbursement; coding; International Classification of Diseases;Clinical Modification; ICD-9-CM; 2009; conditions not found; V89; cervical shortening; high-risk pregnancy; V23; antenatal screening; V28.3; Pap smear; 795; cervix; vagina; vulva; anus; urinary symptoms; urinary problems; vulvodynia; vulvar vestibulitis; breast disorders; dehiscence; tamoxifen; raloxifene; breast cancer; selective estrogen receptor modulators; aromatase inhibitor
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Melanie Witt RN CPC-OBGYN MA; Reimbursement Adviser; reimbursement; coding; International Classification of Diseases;Clinical Modification; ICD-9-CM; 2009; conditions not found; V89; cervical shortening; high-risk pregnancy; V23; antenatal screening; V28.3; Pap smear; 795; cervix; vagina; vulva; anus; urinary symptoms; urinary problems; vulvodynia; vulvar vestibulitis; breast disorders; dehiscence; tamoxifen; raloxifene; breast cancer; selective estrogen receptor modulators; aromatase inhibitor
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Help smokers quit: Tell them their “lung age”

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Help smokers quit: Tell them their “lung age”
Author(s)
Kristen Deane, MD
John Hickner, MD, MSc
 

ILLUSTRATIVE CASE

A 48-year-old man comes to your office for a routine physical. He has a 30 pack-year smoking history. When you talk to him about smoking cessation, he tells you he’s tried to stop more than once, but he can’t seem to stay motivated. You find no evidence of chronic lung disease and do not perform spirometry screening. (The US Preventive Services Task Force does not recommend spirometry for asymptomatic patients.) But could spirometry have therapeutic value in this case?

Smoking is the leading modifiable risk factor for mortality in the United States,2 and smoking cessation is the most effective intervention. Nortriptyline, bupropion, nicotine replacement agents, and varenicline are effective pharmacological treatments.3 Adding counseling to medication significantly improves quit rates (estimated odds ratio [OR]=1.4; 95% confidence interval [CI], 1.2-1.6).3 Nonetheless, physicians’ efforts to help patients stop smoking frequently fail.

But another option has caught—and held—the attention of researchers.

The promise of biomarkers

It has long been suspected that presenting smokers with evidence of tobacco’s harmful effect on their bodies—biomarkers—might encourage them to stop. Biomarkers that have been tested in randomized controlled trials (RCTs) include spirometry, exhaled carbon monoxide measurement, ultrasonography of carotid and femoral arteries, and genetic susceptibility to lung cancer, as well as combinations of these markers. But the results of most biomarker studies have been disappointing. A 2005 Cochrane Database review found insufficient evidence of the effectiveness of these markers in boosting quit rates.4

Lung age, a biomarker that’s easily understood

Lung age, a clever presentation of spirometry results, had not been tested in an RCT prior to the study we summarize below. Defined in 1985, lung age refers to the average age of a nonsmoker with a forced expiratory volume at 1 second (FEV1) equal to that of the person being tested ( FIGURE 1 ). The primary purpose was to make spirometry results easier for patients to understand, but researchers also envisioned it as a way to demonstrate the premature lung damage suffered as a consequence of smoking.5

FIGURE 1
Translating FEV1 into lung age1

STUDY SUMMARY: Graphic display more effective than FEV1 results

FAST TRACK

For every 14 smokers who are told their lung age and shown a graphic display of this biomarker, 1 additional smoker will quit

This study was a well-done, multicenter RCT evaluating the effect on tobacco quit rates of informing adult smokers of their lung age.1 Smokers ages 35 and older from 5 general practices in England were invited to participate. The authors excluded patients using oxygen and those with a history of tuberculosis, lung cancer, asbestosis, bronchiectasis, silicosis, or pneumonectomy. The study included 561 participants with an average of 33 pack-years of smoking, who underwent spirometry before being divided into an intervention or a control group. The researchers used standardized instruments to confirm the baseline comparability of the 2 groups.

Subjects in both groups were given information about local smoking cessation clinics and strongly encouraged to quit. All were told that their lung function would be retested in 12 months.

The controls received letters with their spirometry results presented as FEV1. In contrast, participants in the intervention group received the results in the form of a computer-generated graphic display of lung age ( FIGURE 2 ), which was further explained by a health care worker. They also received a letter within 1 month containing the same data. Participants were evaluated for smoking cessation at 12 months, and those who reported quitting received confirmatory carbon monoxide breath testing and salivary cotinine testing. Eleven percent of the subjects were lost to follow-up.

FIGURE 2
Lung age helps spirometry pack a bigger punch


Drawing a vertical line from the patient’s age (on the horizontal axis) to reach the solid curve representing the lung function of the “susceptible smoker” and extending the line horizontally to reach the curve with the broken lines representing “never smokers” graphically shows the patient’s lung age and the accelerated decline in lung function associated with smoking. The patient shown here is a 52-year-old smoker with FEV1 equivalent to a 75-year-old nonsmoker.
Source: Parkes G et al. BMJ. 2008;336:598-600. Reproduced with permission from the BMJ Publishing Group.

 

 

 

Quit rates higher when patients know lung age

At 1 year, verified quit rates were 13.6% in the intervention group and 6.4% in the control group (a difference of 7.2%, 95% CI, 2.2%-12.1%; P=.005). This means that for every 14 smokers who are told their lung age and shown a graphic display of this biomarker, 1 additional smoker will quit after 1 year.

Contrary to what might be expected, the investigators found that quitting did not depend on the degree of lung damage. Patients with both normal and abnormal lung age quit smoking at similar rates.

WHAT’S NEW: Lung age resonates more than spirometry alone

FAST TRACK

Simply using spirometry to encourage smoking cessation is not sufficient

This is the first RCT demonstrating that informing smokers of their lung age can help them quit, and the first well-designed study to demonstrate improved cessation rates using a physiological biomarker. The research also suggests that successful quitting may have less to do with spirometry results—the level of severity of lung damage it shows—than with the way the results are presented. Giving patients information about their lung function in an easily understandable format, the authors observe, appears to result in higher quit rates.

CAVEATS: Young smokers weren’t studied

The study did not test to see if this intervention would work in younger adults, as only those 35 years of age and older were enrolled. This is a single study, and it is possible that the findings cannot be generalized to other groups or are due to unmeasured confounding factors. However, the intervention is unlikely to cause any significant harm, so we see no risks associated with it other than the cost of spirometry.

CHALLENGES TO IMPLEMENTATION: Time and expense of spirometry

We suspect the biggest challenges to implementing this recommendation in clinical practice are the expense of obtaining a spirometer ( TABLE ), staff training for those practices without one, and the time needed for the intervention. The average time to perform spirometry on study participants was 30 minutes; a health care worker spent, on average, another 15 minutes reviewing results with each member of the intervention group.

Another challenge: Not all spirometers calculate lung age or can create a graphic similar to FIGURE 2 . However, any FEV1 measurement, whether it is generated by formal pulmonary function testing or by an inexpensive hand-held meter, can easily be converted to lung age using the formula shown in FIGURE 1 . If desired, the same elements—the patient’s age, height, and gender as well as FEV1—could also be used to create a computer-generated graphic display.

TABLE
Spirometry: equipment costs

The initial cost of a spirometer varies widely, depending on the sophistication of the equipment and the available options and features. Additional costs—for disposable mouthpieces, line filters, nose clips, and hoses, for example—are low. A sampling of reasonably priced models well suited for office use is shown below. All of these models meet American Thoracic Society criteria for spirometry, and all calculate lung age.
SPIROMETER MANUFACTURER/MODELPRICESUPPLIER
Futuremed Discovery-2$2,125medsupplier.com
Micro Medical MicroLoop$1,780Miami-med.com
Micro Medical SpiroUSB$1,580Miami-med.com
NDD EasyOne Frontline$1,000medsupplier.com
SDI Diagnostics Spirolab II$2,600med-electronics.com

 

This study was selected and evaluated using FPIN’s Priority Updates from the Research Literature (PURL) Surveillance System methodology. The criteria and findings leading to the selection of this study as a PURL can be accessed at www.jfponline.com/purls.

PURL METHODOLOGY
The PURLs Surveillance System is supported in part by Grant Number UL1RR024999 from the National Center For Research Resources, a Clinical Translational Science Award to the University of Chicago. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Center For Research Resources or the National Institutes of Health.

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References

1. Parkes G, Greenhalgh T, Griffin M, Dent R. Effect on smoking quit rate of telling patients their lung age: the Step2quit randomised controlled trial. BMJ. 2008;336:598-600.

2. Mokdad AH, Marks JS, Stroup DF, Gerberding JL. Actual causes of death in the United States, 2000. JAMA. 2004;291:1238-1245.

3. Fiore MC, Jaén CR, Baker TB, et al. Treating Tobacco Use and Dependence: 2008 Update. Clinical practice guideline. Rockville, MD: US Department of Health and Human Services, Public Health Service; May 2008. Available at: http://www.surgeongeneral.gov/tobacco/treating_tobacco_use08.pdf. Accessed July 6, 2008.

4. Bize R, Burnand B, Mueller Y, Cornuz J. Biomedical risk assessment as an aid for smoking cessation. Cochrane Database Syst Rev. 2005;(4):CD004705.-

5. Morris JF, Temple W. Spirometric “lung age” estimation for motivating smoking cessation. Prev Med. 1985;14:655-662.

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James J. Stevermer, MD, MSPH
Department of Family and Community Medicine University of Missouri – Columbia

PURLs EDITOR
John Hickner, MD, MSc
Department of Family Medicine The University of Chicago

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James J. Stevermer, MD, MSPH
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Department of Family Medicine The University of Chicago

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James J. Stevermer, MD, MSPH
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ILLUSTRATIVE CASE

A 48-year-old man comes to your office for a routine physical. He has a 30 pack-year smoking history. When you talk to him about smoking cessation, he tells you he’s tried to stop more than once, but he can’t seem to stay motivated. You find no evidence of chronic lung disease and do not perform spirometry screening. (The US Preventive Services Task Force does not recommend spirometry for asymptomatic patients.) But could spirometry have therapeutic value in this case?

Smoking is the leading modifiable risk factor for mortality in the United States,2 and smoking cessation is the most effective intervention. Nortriptyline, bupropion, nicotine replacement agents, and varenicline are effective pharmacological treatments.3 Adding counseling to medication significantly improves quit rates (estimated odds ratio [OR]=1.4; 95% confidence interval [CI], 1.2-1.6).3 Nonetheless, physicians’ efforts to help patients stop smoking frequently fail.

But another option has caught—and held—the attention of researchers.

The promise of biomarkers

It has long been suspected that presenting smokers with evidence of tobacco’s harmful effect on their bodies—biomarkers—might encourage them to stop. Biomarkers that have been tested in randomized controlled trials (RCTs) include spirometry, exhaled carbon monoxide measurement, ultrasonography of carotid and femoral arteries, and genetic susceptibility to lung cancer, as well as combinations of these markers. But the results of most biomarker studies have been disappointing. A 2005 Cochrane Database review found insufficient evidence of the effectiveness of these markers in boosting quit rates.4

Lung age, a biomarker that’s easily understood

Lung age, a clever presentation of spirometry results, had not been tested in an RCT prior to the study we summarize below. Defined in 1985, lung age refers to the average age of a nonsmoker with a forced expiratory volume at 1 second (FEV1) equal to that of the person being tested ( FIGURE 1 ). The primary purpose was to make spirometry results easier for patients to understand, but researchers also envisioned it as a way to demonstrate the premature lung damage suffered as a consequence of smoking.5

FIGURE 1
Translating FEV1 into lung age1

STUDY SUMMARY: Graphic display more effective than FEV1 results

FAST TRACK

For every 14 smokers who are told their lung age and shown a graphic display of this biomarker, 1 additional smoker will quit

This study was a well-done, multicenter RCT evaluating the effect on tobacco quit rates of informing adult smokers of their lung age.1 Smokers ages 35 and older from 5 general practices in England were invited to participate. The authors excluded patients using oxygen and those with a history of tuberculosis, lung cancer, asbestosis, bronchiectasis, silicosis, or pneumonectomy. The study included 561 participants with an average of 33 pack-years of smoking, who underwent spirometry before being divided into an intervention or a control group. The researchers used standardized instruments to confirm the baseline comparability of the 2 groups.

Subjects in both groups were given information about local smoking cessation clinics and strongly encouraged to quit. All were told that their lung function would be retested in 12 months.

The controls received letters with their spirometry results presented as FEV1. In contrast, participants in the intervention group received the results in the form of a computer-generated graphic display of lung age ( FIGURE 2 ), which was further explained by a health care worker. They also received a letter within 1 month containing the same data. Participants were evaluated for smoking cessation at 12 months, and those who reported quitting received confirmatory carbon monoxide breath testing and salivary cotinine testing. Eleven percent of the subjects were lost to follow-up.

FIGURE 2
Lung age helps spirometry pack a bigger punch


Drawing a vertical line from the patient’s age (on the horizontal axis) to reach the solid curve representing the lung function of the “susceptible smoker” and extending the line horizontally to reach the curve with the broken lines representing “never smokers” graphically shows the patient’s lung age and the accelerated decline in lung function associated with smoking. The patient shown here is a 52-year-old smoker with FEV1 equivalent to a 75-year-old nonsmoker.
Source: Parkes G et al. BMJ. 2008;336:598-600. Reproduced with permission from the BMJ Publishing Group.

 

 

 

Quit rates higher when patients know lung age

At 1 year, verified quit rates were 13.6% in the intervention group and 6.4% in the control group (a difference of 7.2%, 95% CI, 2.2%-12.1%; P=.005). This means that for every 14 smokers who are told their lung age and shown a graphic display of this biomarker, 1 additional smoker will quit after 1 year.

Contrary to what might be expected, the investigators found that quitting did not depend on the degree of lung damage. Patients with both normal and abnormal lung age quit smoking at similar rates.

WHAT’S NEW: Lung age resonates more than spirometry alone

FAST TRACK

Simply using spirometry to encourage smoking cessation is not sufficient

This is the first RCT demonstrating that informing smokers of their lung age can help them quit, and the first well-designed study to demonstrate improved cessation rates using a physiological biomarker. The research also suggests that successful quitting may have less to do with spirometry results—the level of severity of lung damage it shows—than with the way the results are presented. Giving patients information about their lung function in an easily understandable format, the authors observe, appears to result in higher quit rates.

CAVEATS: Young smokers weren’t studied

The study did not test to see if this intervention would work in younger adults, as only those 35 years of age and older were enrolled. This is a single study, and it is possible that the findings cannot be generalized to other groups or are due to unmeasured confounding factors. However, the intervention is unlikely to cause any significant harm, so we see no risks associated with it other than the cost of spirometry.

CHALLENGES TO IMPLEMENTATION: Time and expense of spirometry

We suspect the biggest challenges to implementing this recommendation in clinical practice are the expense of obtaining a spirometer ( TABLE ), staff training for those practices without one, and the time needed for the intervention. The average time to perform spirometry on study participants was 30 minutes; a health care worker spent, on average, another 15 minutes reviewing results with each member of the intervention group.

Another challenge: Not all spirometers calculate lung age or can create a graphic similar to FIGURE 2 . However, any FEV1 measurement, whether it is generated by formal pulmonary function testing or by an inexpensive hand-held meter, can easily be converted to lung age using the formula shown in FIGURE 1 . If desired, the same elements—the patient’s age, height, and gender as well as FEV1—could also be used to create a computer-generated graphic display.

TABLE
Spirometry: equipment costs

The initial cost of a spirometer varies widely, depending on the sophistication of the equipment and the available options and features. Additional costs—for disposable mouthpieces, line filters, nose clips, and hoses, for example—are low. A sampling of reasonably priced models well suited for office use is shown below. All of these models meet American Thoracic Society criteria for spirometry, and all calculate lung age.
SPIROMETER MANUFACTURER/MODELPRICESUPPLIER
Futuremed Discovery-2$2,125medsupplier.com
Micro Medical MicroLoop$1,780Miami-med.com
Micro Medical SpiroUSB$1,580Miami-med.com
NDD EasyOne Frontline$1,000medsupplier.com
SDI Diagnostics Spirolab II$2,600med-electronics.com

 

This study was selected and evaluated using FPIN’s Priority Updates from the Research Literature (PURL) Surveillance System methodology. The criteria and findings leading to the selection of this study as a PURL can be accessed at www.jfponline.com/purls.

PURL METHODOLOGY
The PURLs Surveillance System is supported in part by Grant Number UL1RR024999 from the National Center For Research Resources, a Clinical Translational Science Award to the University of Chicago. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Center For Research Resources or the National Institutes of Health.

 

ILLUSTRATIVE CASE

A 48-year-old man comes to your office for a routine physical. He has a 30 pack-year smoking history. When you talk to him about smoking cessation, he tells you he’s tried to stop more than once, but he can’t seem to stay motivated. You find no evidence of chronic lung disease and do not perform spirometry screening. (The US Preventive Services Task Force does not recommend spirometry for asymptomatic patients.) But could spirometry have therapeutic value in this case?

Smoking is the leading modifiable risk factor for mortality in the United States,2 and smoking cessation is the most effective intervention. Nortriptyline, bupropion, nicotine replacement agents, and varenicline are effective pharmacological treatments.3 Adding counseling to medication significantly improves quit rates (estimated odds ratio [OR]=1.4; 95% confidence interval [CI], 1.2-1.6).3 Nonetheless, physicians’ efforts to help patients stop smoking frequently fail.

But another option has caught—and held—the attention of researchers.

The promise of biomarkers

It has long been suspected that presenting smokers with evidence of tobacco’s harmful effect on their bodies—biomarkers—might encourage them to stop. Biomarkers that have been tested in randomized controlled trials (RCTs) include spirometry, exhaled carbon monoxide measurement, ultrasonography of carotid and femoral arteries, and genetic susceptibility to lung cancer, as well as combinations of these markers. But the results of most biomarker studies have been disappointing. A 2005 Cochrane Database review found insufficient evidence of the effectiveness of these markers in boosting quit rates.4

Lung age, a biomarker that’s easily understood

Lung age, a clever presentation of spirometry results, had not been tested in an RCT prior to the study we summarize below. Defined in 1985, lung age refers to the average age of a nonsmoker with a forced expiratory volume at 1 second (FEV1) equal to that of the person being tested ( FIGURE 1 ). The primary purpose was to make spirometry results easier for patients to understand, but researchers also envisioned it as a way to demonstrate the premature lung damage suffered as a consequence of smoking.5

FIGURE 1
Translating FEV1 into lung age1

STUDY SUMMARY: Graphic display more effective than FEV1 results

FAST TRACK

For every 14 smokers who are told their lung age and shown a graphic display of this biomarker, 1 additional smoker will quit

This study was a well-done, multicenter RCT evaluating the effect on tobacco quit rates of informing adult smokers of their lung age.1 Smokers ages 35 and older from 5 general practices in England were invited to participate. The authors excluded patients using oxygen and those with a history of tuberculosis, lung cancer, asbestosis, bronchiectasis, silicosis, or pneumonectomy. The study included 561 participants with an average of 33 pack-years of smoking, who underwent spirometry before being divided into an intervention or a control group. The researchers used standardized instruments to confirm the baseline comparability of the 2 groups.

Subjects in both groups were given information about local smoking cessation clinics and strongly encouraged to quit. All were told that their lung function would be retested in 12 months.

The controls received letters with their spirometry results presented as FEV1. In contrast, participants in the intervention group received the results in the form of a computer-generated graphic display of lung age ( FIGURE 2 ), which was further explained by a health care worker. They also received a letter within 1 month containing the same data. Participants were evaluated for smoking cessation at 12 months, and those who reported quitting received confirmatory carbon monoxide breath testing and salivary cotinine testing. Eleven percent of the subjects were lost to follow-up.

FIGURE 2
Lung age helps spirometry pack a bigger punch


Drawing a vertical line from the patient’s age (on the horizontal axis) to reach the solid curve representing the lung function of the “susceptible smoker” and extending the line horizontally to reach the curve with the broken lines representing “never smokers” graphically shows the patient’s lung age and the accelerated decline in lung function associated with smoking. The patient shown here is a 52-year-old smoker with FEV1 equivalent to a 75-year-old nonsmoker.
Source: Parkes G et al. BMJ. 2008;336:598-600. Reproduced with permission from the BMJ Publishing Group.

 

 

 

Quit rates higher when patients know lung age

At 1 year, verified quit rates were 13.6% in the intervention group and 6.4% in the control group (a difference of 7.2%, 95% CI, 2.2%-12.1%; P=.005). This means that for every 14 smokers who are told their lung age and shown a graphic display of this biomarker, 1 additional smoker will quit after 1 year.

Contrary to what might be expected, the investigators found that quitting did not depend on the degree of lung damage. Patients with both normal and abnormal lung age quit smoking at similar rates.

WHAT’S NEW: Lung age resonates more than spirometry alone

FAST TRACK

Simply using spirometry to encourage smoking cessation is not sufficient

This is the first RCT demonstrating that informing smokers of their lung age can help them quit, and the first well-designed study to demonstrate improved cessation rates using a physiological biomarker. The research also suggests that successful quitting may have less to do with spirometry results—the level of severity of lung damage it shows—than with the way the results are presented. Giving patients information about their lung function in an easily understandable format, the authors observe, appears to result in higher quit rates.

CAVEATS: Young smokers weren’t studied

The study did not test to see if this intervention would work in younger adults, as only those 35 years of age and older were enrolled. This is a single study, and it is possible that the findings cannot be generalized to other groups or are due to unmeasured confounding factors. However, the intervention is unlikely to cause any significant harm, so we see no risks associated with it other than the cost of spirometry.

CHALLENGES TO IMPLEMENTATION: Time and expense of spirometry

We suspect the biggest challenges to implementing this recommendation in clinical practice are the expense of obtaining a spirometer ( TABLE ), staff training for those practices without one, and the time needed for the intervention. The average time to perform spirometry on study participants was 30 minutes; a health care worker spent, on average, another 15 minutes reviewing results with each member of the intervention group.

Another challenge: Not all spirometers calculate lung age or can create a graphic similar to FIGURE 2 . However, any FEV1 measurement, whether it is generated by formal pulmonary function testing or by an inexpensive hand-held meter, can easily be converted to lung age using the formula shown in FIGURE 1 . If desired, the same elements—the patient’s age, height, and gender as well as FEV1—could also be used to create a computer-generated graphic display.

TABLE
Spirometry: equipment costs

The initial cost of a spirometer varies widely, depending on the sophistication of the equipment and the available options and features. Additional costs—for disposable mouthpieces, line filters, nose clips, and hoses, for example—are low. A sampling of reasonably priced models well suited for office use is shown below. All of these models meet American Thoracic Society criteria for spirometry, and all calculate lung age.
SPIROMETER MANUFACTURER/MODELPRICESUPPLIER
Futuremed Discovery-2$2,125medsupplier.com
Micro Medical MicroLoop$1,780Miami-med.com
Micro Medical SpiroUSB$1,580Miami-med.com
NDD EasyOne Frontline$1,000medsupplier.com
SDI Diagnostics Spirolab II$2,600med-electronics.com

 

This study was selected and evaluated using FPIN’s Priority Updates from the Research Literature (PURL) Surveillance System methodology. The criteria and findings leading to the selection of this study as a PURL can be accessed at www.jfponline.com/purls.

PURL METHODOLOGY
The PURLs Surveillance System is supported in part by Grant Number UL1RR024999 from the National Center For Research Resources, a Clinical Translational Science Award to the University of Chicago. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Center For Research Resources or the National Institutes of Health.

References

1. Parkes G, Greenhalgh T, Griffin M, Dent R. Effect on smoking quit rate of telling patients their lung age: the Step2quit randomised controlled trial. BMJ. 2008;336:598-600.

2. Mokdad AH, Marks JS, Stroup DF, Gerberding JL. Actual causes of death in the United States, 2000. JAMA. 2004;291:1238-1245.

3. Fiore MC, Jaén CR, Baker TB, et al. Treating Tobacco Use and Dependence: 2008 Update. Clinical practice guideline. Rockville, MD: US Department of Health and Human Services, Public Health Service; May 2008. Available at: http://www.surgeongeneral.gov/tobacco/treating_tobacco_use08.pdf. Accessed July 6, 2008.

4. Bize R, Burnand B, Mueller Y, Cornuz J. Biomedical risk assessment as an aid for smoking cessation. Cochrane Database Syst Rev. 2005;(4):CD004705.-

5. Morris JF, Temple W. Spirometric “lung age” estimation for motivating smoking cessation. Prev Med. 1985;14:655-662.

References

1. Parkes G, Greenhalgh T, Griffin M, Dent R. Effect on smoking quit rate of telling patients their lung age: the Step2quit randomised controlled trial. BMJ. 2008;336:598-600.

2. Mokdad AH, Marks JS, Stroup DF, Gerberding JL. Actual causes of death in the United States, 2000. JAMA. 2004;291:1238-1245.

3. Fiore MC, Jaén CR, Baker TB, et al. Treating Tobacco Use and Dependence: 2008 Update. Clinical practice guideline. Rockville, MD: US Department of Health and Human Services, Public Health Service; May 2008. Available at: http://www.surgeongeneral.gov/tobacco/treating_tobacco_use08.pdf. Accessed July 6, 2008.

4. Bize R, Burnand B, Mueller Y, Cornuz J. Biomedical risk assessment as an aid for smoking cessation. Cochrane Database Syst Rev. 2005;(4):CD004705.-

5. Morris JF, Temple W. Spirometric “lung age” estimation for motivating smoking cessation. Prev Med. 1985;14:655-662.

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Help patients gain better asthma control

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Help patients gain better asthma control
Author(s)
Stuart W. Stoloff, MD

 

Practice recommendations

 

  • Assess asthma severity before initiating treatment; monitor asthma control to guide adjustments in therapy using measures of impairment (B) and risk (C) (National Heart, Lung, and Blood Institute [NHLBI] and National Asthma Education and Prevention Program [NAEPP] third expert panel report [EPR-3]).
  • Base treatment decisions on recommendations specific to each age group (0-4 years, 5-11 years, and ≥12 years) (A).
  • Use spirometry in patients ≥5 years of age to diagnose asthma, classify severity, and assess control (C).
  • Provide each patient with a written asthma action plan with instructions for daily disease management, as well as identification of, and response to, worsening symptoms (B).

EPR-3 evidence categories:

 

  1. Randomized, controlled trials (RCTs), rich body of data
  2. RCTs, limited body of data
  3. Nonrandomized trials and observational studies
  4. Panel consensus judgment

JJ, a 4-year-old boy, was taken to an urgent care clinic 3 times last winter for “recurrent bronchitis” and given a 7-day course of prednisone and antibiotics at each visit. His mother reports that “his colds always seem to go to his chest” and his skin is always dry. She was given a nebulizer and albuterol for use when JJ begins wheezing, which often happens when he has a cold, plays vigorously, or visits a friend who has cats.

JJ is one of approximately 6.7 million children—and 22.9 million US residents—who have asthma.1 To help guide the care of patients like JJ, the National Heart, Lung, and Blood Institute (NHLBI) and National Asthma Education and Prevention Program (NAEPP) released the third expert panel report (EPR-3) in 2007. Available at http://www.nhlbi.nih.gov/guidelines/asthma/asthgdln.htm, the EPR-3 provides the most comprehensive evidence-based guidance for the diagnosis and management of asthma to date.2

The guidelines were an invaluable resource for JJ’s family physician, who referred to them to categorize the severity of JJ’s asthma as “mild persistent.” In initiating treatment, JJ’s physician relied on specific recommendations for children 0 to 4 years of age to prescribe low-dose inhaled corticosteroids (ICS). Without the new guidelines, which underscore the safety of controller medication for young children, JJ’s physician would likely have been reluctant to place a 4-year-old on ICS.

This review highlights the EPR-3’s key recommendations to encourage widespread implementation by family physicians.

The EPR-3: What’s changed

The 2007 guidelines:
Recommend assessing asthma severity before starting treatment and assessing asthma control to guide adjustments in treatment.
Address both severity and control in terms of impairment and risk.
Feature 3 age breakdowns (0-4 years, 5-11 years, and ≥12 years) and a 6-step approach to asthma management.
Make it easier to individualize and adjust treatment.

What’s changed?

There’s a new paradigm

The 2007 update to guidelines released in 1997 and 2002 reflects a paradigm shift in the overall approach to asthma management. The change in focus addresses the highly variable nature of asthma2 and the recognition that asthma severity and asthma control are distinct concepts serving different functions in clinical practice.

Severity and control in 2 domains. Asthma severity—a measure of the intrinsic intensity of the disease process—is ideally assessed before initiating treatment. In contrast, asthma control is monitored over time to guide adjustments to therapy. The guidelines call for assessing severity and control within the domains of:

 

  • impairment, based on asthma symptoms (identified by patient or caregiver recall of the past 2-4 weeks), quality of life, and functional limitations; and
  • risk, of asthma exacerbations, progressive decline in pulmonary function (or reduced lung growth in children), or adverse events. Predictors of increased risk for exacerbations or death include persistent and/or severe airflow obstruction; at least 2 visits to the emergency department or hospitalizations for asthma within the past year; and a history of intubation or admission to intensive care, especially within the past 5 years.

 

FAST TRACK

Peak expiratory flow testing is not a reliable measure of asthma severity

The specific criteria for determining asthma severity and assessing asthma control are detailed in FIGURES 1 AND 2, respectively. Because treatment affects impairment and risk differently, this dual assessment helps ensure that therapeutic interventions minimize all manifestations of asthma as much as possible.

More steps and age-specific interventions. The EPR-3’s stepwise approach to asthma therapy has gone from 4 steps to 6, and the recommended treatments, as well as the levels of severity and criteria for assessing control that guide them, are now divided into 3 age groups: 0 to 4 years, 5 to 11 years, and ≥12 years (FIGURE 3). The previous guidelines, issued in 2002, divided treatment recommendations into 2 age groups: ≤5 years and >5 years. The EPR-3’s expansion makes it easier for physicians to initiate, individualize, and adjust treatment.

FIGURE 1
Classifying asthma severity and initiating therapy in children, adolescents, and adults


EIB, exercise-induced bronchospasm; FEV1, forced expiratory volume in 1 second; FVC, forced vital capacity; ICS, inhaled corticosteroids; NA, not applicable; OCS, oral corticosteroids; SABA, short-acting β2-adrenergic agonist.
*Normal FEV1/FVC values are defined according to age: 8–9 years (85%), 20–39 years (80%), 40–59 years (75%), 60–80 years (70%).
For treatment purposes, children with at least 2 exacerbations (eg, requiring urgent, unscheduled care; hospitalization; or intensive care unit admission) or adolescents/adults with at least 2 exacerbations requiring OCS in the past year may be considered the same as patients who have persistent asthma, even in the absence of impairment levels consistent with persistent asthma.
Adapted from: National Heart, Lung, and Blood Institute (NHLBI).2

FIGURE 2
Assessing asthma control and adjusting therapy


ACQ, Asthma Control Questionnaire; ACT, Asthma Control Test; ATAQ, Asthma Therapy Assessment Questionnaire; EIB, exercise-induced bronchospasm; FEV1, forced expiratory volume in 1 second; FVC, forced vital capacity; N/A, not applicable; OCS, oral corticosteroids; SABA, short-acting β2-adrenergic agonist.
*ACQ values of 0.76 to 1.4 are indeterminate regarding well-controlled asthma.
For treatment purposes, children with at least 2 exacerbations (eg, requiring urgent, unscheduled care; hospitalization; or intensive care unit admission) or adolescents/adults with at least 2 exacerbations requiring OCS in the past year may be considered the same as patients who have asthma that is not well controlled, even in the absence of impairment levels consistent with that classification.
Adapted from: National Heart, Lung, and Blood Institute (NHLBI).2

FIGURE 3
Stepwise approach for managing asthma


EIB, exercise-induced bronchospasm; ICS, inhaled corticosteroid; LABA, long-acting β2-adrenergic agonist; LTRA, leukotriene receptor antagonist; OCS, oral corticosteroid; PRN, as needed; SABA, short-acting β2-adrenergic agonist.
Adapted from: National Heart, Lung, and Blood Institute (NHLBI).2

 

 

Putting guidelines into practice begins with the history

A detailed medical history and a physical examination focusing on the upper respiratory tract, chest, and skin are needed to arrive at an asthma diagnosis. JJ’s physician asked his mother to describe recent symptoms and inquired about comorbid conditions that can aggravate asthma. He also identified viral respiratory infections, environmental causes, and activity as precipitating factors.

In considering an asthma diagnosis, try to determine the presence of episodic symptoms of airflow obstruction or bronchial hyperresponsiveness, as well as airflow obstruction that is at least partly reversible (an increase in forced expiratory volume in 1 second [FEV1] of >200 mL and ≥12% from baseline or an increase of ≥10% of predicted FEV1), and to exclude alternative diagnoses.

EPR-3 emphasizes spirometry

Recognizing that patients’ perception of airflow obstruction is highly variable and that pulmonary function measures do not always correlate directly with symptoms,3,4 the EPR-3 recommends spirometry for patients ≥5 years of age, both before and after bronchodilation. In addition to helping to confirm an asthma diagnosis, spirometry is the preferred measure of pulmonary function in classifying severity, because peak expiratory flow (PEF) testing has not proven reliable.5,6

 

FAST TRACK

Low-dose inhaled corticosteroids are safe and effective for the youngest asthma patients

Objective measurement of pulmonary function is difficult to obtain in children <5 years of age. If diagnosis remains uncertain for patients in this age group, a therapeutic trial of medication is recommended. In JJ’s case, however, 3 courses of oral corticosteroids (OCS) in less than 6 months were indicative of persistent asthma.

Spirometry is often underutilized. For patients ≥5 years of age, spirometry is a vital tool, but often underutilized in family practice. A recent study by Yawn and colleagues found that family physicians made changes in the management of approximately half of the asthma patients who underwent spirometry.7 (Information about spirometry training is available through the National Institute for Occupational Safety and Health at http://www.cdc.gov/niosh.) Referral to a specialist is recommended if the physician has difficulty making a differential diagnosis or is unable to perform spirometry on a patient who presents with atypical signs and symptoms of asthma.

What is the patient’s level of severity?

In patients who are not yet receiving long-term controller therapy, severity level is based on an assessment of impairment and risk (FIGURE 1). For patients who are already receiving treatment, severity is determined by the minimum pharmacologic therapy needed to maintain asthma control.

The severity classification—intermittent asthma or persistent asthma that is mild, moderate, or severe—is determined by the most severe category in which any feature occurs. (In children, FEV1/FVC [forced vital capacity] ratio has been shown to be a more sensitive determinant of severity than FEV1,4 which may be more useful in predicting exacerbations.8)

Asthma management: Preferred and alternative Tx

The recommended stepwise interventions include both preferred therapies (evidence-based) and alternative treatments (listed alphabetically in FIGURE 3 because there is insufficient evidence to rank them). The additional steps and age categories support the goal of using the least possible medication needed to maintain good control and minimize the potential for adverse events.

In initiating treatment, select the step that corresponds to the level of severity in the bottom row of FIGURE 1; to adjust medications, determine the patient’s level of asthma control and follow the corresponding guidance in the bottom row of FIGURE 2.

Inhaled corticosteroids remain the bedrock of therapy

ICS, the most potent and consistently effective long-term controller therapy, remain the foundation of therapy for patients of all ages who have persistent asthma. (Evidence: A).

Several of the age-based recommendations follow, with a focus on preferred treatments:

Children 0 to 4 years of age

 

  • The guidelines recommend low-dose ICS at Step 2 (Evidence: A) and medium-dose ICS at Step 3 (Evidence: D), as inhaled corticosteroids have been shown to reduce impairment and risk in this age group.9-16 The potential risk is generally limited to a small reduction in growth velocity during the first year of treatment, and offset by the benefits of therapy.15,16
  • Add a long-acting β2-adrenergic agonist (LABA) or montelukast to medium-dose ICS therapy at Step 4 rather than increasing the ICS dose (Evidence: D) to avoid the risk of side effects associated with high-dose ICS. Montelukast has demonstrated efficacy in children 2 to 5 years of age with persistent asthma.17
  • Recommendations for preferred therapy at Steps 5 (high-dose ICS + LABA or montelukast) and 6 (Step 5 therapy + OCS) are based on expert panel judgment (Evidence: D). When severe persistent asthma warrants Step 6 therapy, start with a 2-week course of the lowest possible dose of OCS to confirm reversibility.
  • In this age group, a therapeutic trial with close monitoring is recommended for patients whose asthma is not well controlled. If there is no response in 4 to 6 weeks, consider alternative therapies or diagnoses (Evidence: D).
 

 

 

FAST TRACK

Spirometry testing, which is underused in family practice, often leads to adjustments in asthma therapy

Children 5 to 11 years of age

 

  • For Step 3 therapy, the guidelines recommend either low-dose ICS plus a LABA, leukotriene receptor antagonist (LTRA), or theophylline; or medium-dose ICS (Evidence: B). Treatment decisions at Step 3 depend on whether impairment or risk is the chief concern, as well as on safety considerations.
  • For Steps 4 and 5, ICS (medium dose for Step 5 and high dose for Step 6) plus a LABA is preferred, based on studies of patients ≥12 years of age (Evidence: B). Step 6 builds on Step 5, adding an OCS to the LABA/ICS combination (Evidence: D).
  • If theophylline is prescribed—a viable option if cost and adherence to inhaled medications are key concerns—serum levels must be closely monitored because of the risk of toxicity.
  • Closely monitor and be prepared to identify and respond to anaphylaxis in a child at Step 2, 3, or 4 who is receiving allergen immunotherapy.

Adolescents ≥12 years of age and adults

 

  • There are 2 preferred Step 3 treatments: Low-dose ICS plus a LABA, or medium-dose ICS. The combination therapy has shown greater improvement in impairment24,25 and risk24-26 compared with the higher dose of ICS.
  • Preferred treatments at Steps 4, 5, and 6 are the same as those for children ages 5 to 11 years, with one exception: Subcutaneous anti-IgE therapy (omalizumab) may be added to the regimen at Steps 5 and 6 for adolescents and adults with severe persistent allergic asthma to reduce the risk of exacerbations.27

 

FAST TRACK

If a step down is in order, reduce ICS dosing gradually, at a rate of about 25% to 50% every 3 months

Weigh the benefits and risks of therapy

Safety is a key consideration for all asthma patients. Carefully weigh the benefits and risks of therapy, including the rare but potential risk of life-threatening or fatal exacerbations with daily LABA therapy28 and systemic effects with higher doses of ICS.23 Patients who begin receiving oral corticosteroids require close monitoring, regardless of age.

Regular reassessment and monitoring are critical

 

FAST TRACK

For a list of asthma education resources, see Table W1 online at www.jfponline.com

Schedule visits at 2- to 6-week intervals for those who are starting therapy or require a step up to achieve or regain asthma control. After control is achieved, reassess at least every 1 to 6 months. Measures of asthma control are the same as those used to assess severity, with the addition of validated multidimensional questionnaires (eg, Asthma Control Test [ACT])29 to gauge impairment.

JJ’s physician scheduled a follow-up visit in 4 weeks, at which time he did a reassessment based on a physical exam and symptom recall. Finding JJ’s asthma to be well controlled, the physician asked the boy’s mother to bring him back to the office in 2 months, or earlier if symptoms recurred.

TABLE W1
Asthma education resources

 

Allergy & Asthma Network Mothers of Asthmatics
2751 Prosperity Avenue, Suite 150
Fairfax, VA 22030
www.breatherville.org
(800) 878-4403 or (703) 641-9595		Asthma and Allergy Foundation of America
1233 20th Street, NW, Suite 402
Washington, DC 20036
www.aafa.org
(800) 727-8462
American Academy of Allergy,
Asthma, and Immunology
555 East Wells Street, Suite 1100
Milwaukee, WI 53202-3823
www.aaaai.org
(414) 272-6071		Centers for Disease Control and Prevention
1600 Clifton Road
Atlanta, GA 30333
www.cdc.gov
(800) 311-3435
American Association for Respiratory Care
9125 North macArthur boulevard, Suite 100
Irving, TX 75063
www.aarc.org
(972) 243-2272		Food Allergy & Anaphylaxis Network
11781 lee Jackson Highway, Suite 160
Fairfax, VA 22033
www.foodallergy.org
(800) 929-4040
American College of Allergy, Asthma, and Immunology
85 West Algonquin road, Suite 550
Arlington Heights, IL 60005
www.acaai.org
(800) 842-7777 or (847) 427-1200		National Heart, Lung, and Blood Institute Information Center
P.O. Box 30105
Bethesda, MD 20824-0105
www.nhlbi.nih.gov
(301) 592-8573
American Lung Association
61 Broadway
New York, NY 10006
www.lungusa.org
(800) 586-4872		National Jewish Medical and Research Center (Lung Line)
1400 Jackson Street
Denver, CO 80206
www.njc.org
(800) 222-lUNG
Association of Asthma Educators
1215 Anthony Avenue
Columbia, SC 29201
www.asthmaeducators.org
(888) 988-7747		US Environmental Protection Agency
National Center for Environmental Publications
P.O. Box 42419
Cincinnati, OH 45242-0419
www.airnow.gov
(800) 490-9198

Does your patient require a step down or step up?

A step down is recommended for patients whose asthma is well controlled for 3 months or more. Reduce the dose of ICS gradually, about 25% to 50% every 3 months, because deterioration in asthma control is highly variable. Review adherence and medication administration technique with patients whose asthma is not well controlled, and consider a step up in treatment. If an alternative treatment is used but does not result in an adequate response, it should be discontinued and the preferred treatment used before stepping up. Refer patients to an asthma specialist if their asthma does not respond to these adjustments.

 

 

Partner with patients for optimal care

The EPR-3 recommends the integration of patient education into all aspects of asthma care. To forge an active partnership, identify and address concerns about the condition and its treatment and involve the patient and family in developing treatment goals and making treatment decisions. If the patient is old enough, encourage self-monitoring and management.

The EPR-3 recommends that physicians give every patient a written asthma action plan that addresses individual symptoms and/or PEF measurements and includes instructions for self-management. Daily PEF monitoring can be useful in identifying early changes in the disease state and evaluating response to changes in therapy. It is ideal for those who have moderate to severe persistent asthma, difficulty recognizing signs of exacerbations, or a history of severe exacerbations.

Correspondence
Stuart W. Stoloff, MD, Clinical Professor, Department of Family and Community Medicine, University of Nevada–Reno, 1200 Mountain Street, Suite 220, Carson City, NV 89703; [email protected].

References

 

1. National Center for Health Statistics. Fast stats A to Z. Available at: www.cdc.gov/nchs/fastats/asthma.htm. Accessed August 1, 2008.

2. National Heart, Lung, and Blood Institute (NHLBI). National Asthma Education and Prevention Program Expert Panel Report 3: Guidelines for the Diagnosis and Management of Asthma. Full Report 2007. Bethesda, MD: NHLBI; August 2007. NIH publication no. 07-4051. Available at: http://www.nhlbi.nih.gov/guidelines/asthma/asthgdln.htm. Accessed July 17, 2008.

3. Stout JW, Visness CM, Enright P, et al. Classification of asthma severity in children: the contribution of pulmonary function testing. Arch Pediatr Adolesc Med. 2006;160:844-850.

4. Bacharier LB, Strunk RC, Mauger D, et al. Classifying asthma severity in children: mismatch between symptoms, medication use, and lung function. Am J Respir Crit Care Med. 2004;170:426-432.

5. Eid N, Yandell B, Howell L, Eddy M, Sheikh S. Can children with asthma? Pediatrics. 2000;105:354-358.

6. Llewellin P, Sawyer G, Lewis S, et al. The relationship between FEV1 and PEF in the assessment of the severity of airways obstruction. Respirology. 2002;7:333-337.

7. Yawn BP, Enright PL, Lemanske RF, Jr, et al. Spirometry can be done in family physicians’ offices and alters clinical decisions in management of asthma and COPD. Chest. 2007;132:1162-1168.

8. Fuhlbrigge AL, Kitch BT, Paltiel AD, et al. FEV1 is associated with risk of asthma attacks in a pediatric population. J Allergy Clin Immunol. 2001;107:61-67.

9. Roorda RJ, Mezei G, Bisgaard H, Maden C. Response of preschool children with asthma symptoms to fluticasone propionate. J Allergy Clin Immunol. 2001;108:540-546.

10. Baker JW, Mellon M, Wald J, Welch M, Cruz-Rivera M, Walton-Bowen K. A multiple-dosing, placebo-controlled study of budesonide inhalation suspension given once or twice daily for treatment of persistent asthma in young children and infants. Pediatrics. 1999;103:414-421.

11. Kemp JP, Skoner DP, Szefler SJ, Walton-Bowen K, Cruz-Rivera M, Smith JA. Once-daily budesonide inhalation suspension for the treatment of persistent asthma in infants and young children. Ann Allergy Asthma Immunol. 1999;83:231-239.

12. Shapiro G, Mendelson L, Kraemer MJ, Cruz-Rivera M, Walton-Bowen K, Smith JA. Efficacy and safety of budesonide inhalation suspension (Pulmicort Respules) in young children with inhaled steroid-dependent, persistent asthma. J Allergy Clin Immunol. 1998;102:789-796.

13. Bisgaard H, Gillies J, Groenewald M, Maden C. The effect of inhaled fluticasone propionate in the treatment of young asthmatic children: a dose comparison study. Am J Respir Crit Care Med. 1999;160:126-131.

14. Szefler SJ, Eigen H. Budesonide inhalation suspension: a nebulized corticosteroid for persistent asthma. J Allergy Clin Immunol. 2002;109:730-742.

15. Guilbert TW, Morgan WJ, Zeiger RS, et al. Long-term inhaled corticosteroids in preschool children at high risk for asthma. N Engl J Med. 2006;354:1985-1997.

16. Bisgaard H, Allen D, Milanowski J, Kalev I, Willits L, Davies P. Twelve-month safety and efficacy of inhaled fluticasone propionate in children aged 1 to 3 years with recurrent wheezing. Pediatrics. 2004;113:e87-e94.

17. Knorr B, Franchi LM, Bisgaard H, et al. Montelukast, a leukotriene receptor antagonist, for the treatment of persistent asthma in children aged 2 to 5 years. Pediatrics 2001;108:e48.-

18. Russell G, Williams DA, Weller P, Price JF. Salmeterol xinafoate in children on high dose inhaled steroids. Ann Allergy Asthma Immunol. 1995;75:423-428.

19. Zimmerman B, D’Urzo A, Bérubé D. Efficacy and safety of formoterol Turbuhaler when added to inhaled corticosteroid treatment in children with asthma. Pediatr Pulmonol. 2004;37:122-127.

20. Simons FE, Villa JR, Lee BW, et al. Montelukast added to budesonide in children with persistent asthma: a randomized, double-blind, crossover study. J Pediatr. 2001;138:694-698.

21. Shapiro G, Bronsky EA, LaForce CF, et al. Dose-related efficacy of budesonide administered via a dry powder inhaler in the treatment of children with moderate to severe persistent asthma. J Pediatr. 1998;132:976-982.

22. Pauwels RA, Lofdahl C-G, Postma DS, et al. for the Formoterol and Corticosteroids Establishing Therapy (FACET) International Study Group. Effect of inhaled formoterol and budesonide on exacerbations of asthma. N Engl J Med. 1997;337:1405-1411.

23. Tattersfield AE, Harrison TW, Hubbard RB, Mortimer K. Safety of inhaled corticosteroids. Proc Am Thorac Soc. 2004;1:171-175.

24. Bateman ED, Boushey HA, Bousquet J, et al. For the GOAL Investigators Group. Can guideline-defined asthma control be achieved? The Gaining Optimal Asthma ControL study. Am J Respir Crit Care Med. 2004;170:836-844.

25. O’Byrne PM, Barnes PJ, Rodriguez-Roisin R, et al. Low dose inhaled budesonide and formoterol in mild persistent asthma: the OPTIMA randomized trial. Am J Respir Crit Care Med. 2001;164:1392-1397.

26. Masoli M, Weatherall M, Holt S, Beasley R. Moderate dose inhaled corticosteroids plus salmeterol versus higher doses of inhaled corticosteroids in symptomatic asthma. Thorax. 2005;60:730-734.

27. Bousquet J, Wenzel S, Holgate S, Lumry W, Freeman P, Fox H. Predicting response to omalizumab, an anti-IgE antibody, in patients with allergic asthma. Chest. 2004;125:1378-1386.

28. Nelson HS, Weiss ST, Bleecker ER, Yancey SW, Dorinsky PM. For the SMART Study Group. The Salmeterol Multicenter Asthma Research Trial: a comparison of usual pharmacotherapy for asthma or usual pharmacotherapy plus salmeterol. Chest. 2006;129:15-26.

29. Nathan RA, Sorkness CA, Kosinski M, et al. Development of the asthma control test: a survey for assessing asthma control. J Allergy Clin Immunol. 2004;113:59-65.

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Stuart W. Stoloff, MD
Department of Family and Community Medicine, University of Nevada—Reno

Dr. Stoloff served on the panel that issued the National Asthma Education and Prevention Program (NAEPP) Expert Panel Report 3: Guidelines for the Diagnosis and Management of Asthma

Dr. Stoloff discloses that he serves as a consultant to Adelphi Publishing, Alcon, AstraZeneca LP, Dey, Dyson, Genentech, GlaxoSmithKline, Merck & Co., Novartis, Pfizer, Schering-Plough, and Teva Pharmaceutical Industries. He is on the speakers’ bureau of Alcon, AstraZeneca LP, Dey, Genentech, GlaxoSmithKline, Novartis, Schering-Plough, and Teva Pharmaceutical Industries.

Dr. Stoloff received writing assistance from Cynthia Gobbel, PhD, at Scientific Connexions, Newtown, PA, funded by AstraZeneca LP.

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Stuart W. Stoloff, MD
Department of Family and Community Medicine, University of Nevada—Reno

Dr. Stoloff served on the panel that issued the National Asthma Education and Prevention Program (NAEPP) Expert Panel Report 3: Guidelines for the Diagnosis and Management of Asthma

Dr. Stoloff discloses that he serves as a consultant to Adelphi Publishing, Alcon, AstraZeneca LP, Dey, Dyson, Genentech, GlaxoSmithKline, Merck & Co., Novartis, Pfizer, Schering-Plough, and Teva Pharmaceutical Industries. He is on the speakers’ bureau of Alcon, AstraZeneca LP, Dey, Genentech, GlaxoSmithKline, Novartis, Schering-Plough, and Teva Pharmaceutical Industries.

Dr. Stoloff received writing assistance from Cynthia Gobbel, PhD, at Scientific Connexions, Newtown, PA, funded by AstraZeneca LP.

Author and Disclosure Information

 

Stuart W. Stoloff, MD
Department of Family and Community Medicine, University of Nevada—Reno

Dr. Stoloff served on the panel that issued the National Asthma Education and Prevention Program (NAEPP) Expert Panel Report 3: Guidelines for the Diagnosis and Management of Asthma

Dr. Stoloff discloses that he serves as a consultant to Adelphi Publishing, Alcon, AstraZeneca LP, Dey, Dyson, Genentech, GlaxoSmithKline, Merck & Co., Novartis, Pfizer, Schering-Plough, and Teva Pharmaceutical Industries. He is on the speakers’ bureau of Alcon, AstraZeneca LP, Dey, Genentech, GlaxoSmithKline, Novartis, Schering-Plough, and Teva Pharmaceutical Industries.

Dr. Stoloff received writing assistance from Cynthia Gobbel, PhD, at Scientific Connexions, Newtown, PA, funded by AstraZeneca LP.

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Practice recommendations

 

  • Assess asthma severity before initiating treatment; monitor asthma control to guide adjustments in therapy using measures of impairment (B) and risk (C) (National Heart, Lung, and Blood Institute [NHLBI] and National Asthma Education and Prevention Program [NAEPP] third expert panel report [EPR-3]).
  • Base treatment decisions on recommendations specific to each age group (0-4 years, 5-11 years, and ≥12 years) (A).
  • Use spirometry in patients ≥5 years of age to diagnose asthma, classify severity, and assess control (C).
  • Provide each patient with a written asthma action plan with instructions for daily disease management, as well as identification of, and response to, worsening symptoms (B).

EPR-3 evidence categories:

 

  1. Randomized, controlled trials (RCTs), rich body of data
  2. RCTs, limited body of data
  3. Nonrandomized trials and observational studies
  4. Panel consensus judgment

JJ, a 4-year-old boy, was taken to an urgent care clinic 3 times last winter for “recurrent bronchitis” and given a 7-day course of prednisone and antibiotics at each visit. His mother reports that “his colds always seem to go to his chest” and his skin is always dry. She was given a nebulizer and albuterol for use when JJ begins wheezing, which often happens when he has a cold, plays vigorously, or visits a friend who has cats.

JJ is one of approximately 6.7 million children—and 22.9 million US residents—who have asthma.1 To help guide the care of patients like JJ, the National Heart, Lung, and Blood Institute (NHLBI) and National Asthma Education and Prevention Program (NAEPP) released the third expert panel report (EPR-3) in 2007. Available at http://www.nhlbi.nih.gov/guidelines/asthma/asthgdln.htm, the EPR-3 provides the most comprehensive evidence-based guidance for the diagnosis and management of asthma to date.2

The guidelines were an invaluable resource for JJ’s family physician, who referred to them to categorize the severity of JJ’s asthma as “mild persistent.” In initiating treatment, JJ’s physician relied on specific recommendations for children 0 to 4 years of age to prescribe low-dose inhaled corticosteroids (ICS). Without the new guidelines, which underscore the safety of controller medication for young children, JJ’s physician would likely have been reluctant to place a 4-year-old on ICS.

This review highlights the EPR-3’s key recommendations to encourage widespread implementation by family physicians.

The EPR-3: What’s changed

The 2007 guidelines:
Recommend assessing asthma severity before starting treatment and assessing asthma control to guide adjustments in treatment.
Address both severity and control in terms of impairment and risk.
Feature 3 age breakdowns (0-4 years, 5-11 years, and ≥12 years) and a 6-step approach to asthma management.
Make it easier to individualize and adjust treatment.

What’s changed?

There’s a new paradigm

The 2007 update to guidelines released in 1997 and 2002 reflects a paradigm shift in the overall approach to asthma management. The change in focus addresses the highly variable nature of asthma2 and the recognition that asthma severity and asthma control are distinct concepts serving different functions in clinical practice.

Severity and control in 2 domains. Asthma severity—a measure of the intrinsic intensity of the disease process—is ideally assessed before initiating treatment. In contrast, asthma control is monitored over time to guide adjustments to therapy. The guidelines call for assessing severity and control within the domains of:

 

  • impairment, based on asthma symptoms (identified by patient or caregiver recall of the past 2-4 weeks), quality of life, and functional limitations; and
  • risk, of asthma exacerbations, progressive decline in pulmonary function (or reduced lung growth in children), or adverse events. Predictors of increased risk for exacerbations or death include persistent and/or severe airflow obstruction; at least 2 visits to the emergency department or hospitalizations for asthma within the past year; and a history of intubation or admission to intensive care, especially within the past 5 years.

 

FAST TRACK

Peak expiratory flow testing is not a reliable measure of asthma severity

The specific criteria for determining asthma severity and assessing asthma control are detailed in FIGURES 1 AND 2, respectively. Because treatment affects impairment and risk differently, this dual assessment helps ensure that therapeutic interventions minimize all manifestations of asthma as much as possible.

More steps and age-specific interventions. The EPR-3’s stepwise approach to asthma therapy has gone from 4 steps to 6, and the recommended treatments, as well as the levels of severity and criteria for assessing control that guide them, are now divided into 3 age groups: 0 to 4 years, 5 to 11 years, and ≥12 years (FIGURE 3). The previous guidelines, issued in 2002, divided treatment recommendations into 2 age groups: ≤5 years and >5 years. The EPR-3’s expansion makes it easier for physicians to initiate, individualize, and adjust treatment.

FIGURE 1
Classifying asthma severity and initiating therapy in children, adolescents, and adults


EIB, exercise-induced bronchospasm; FEV1, forced expiratory volume in 1 second; FVC, forced vital capacity; ICS, inhaled corticosteroids; NA, not applicable; OCS, oral corticosteroids; SABA, short-acting β2-adrenergic agonist.
*Normal FEV1/FVC values are defined according to age: 8–9 years (85%), 20–39 years (80%), 40–59 years (75%), 60–80 years (70%).
For treatment purposes, children with at least 2 exacerbations (eg, requiring urgent, unscheduled care; hospitalization; or intensive care unit admission) or adolescents/adults with at least 2 exacerbations requiring OCS in the past year may be considered the same as patients who have persistent asthma, even in the absence of impairment levels consistent with persistent asthma.
Adapted from: National Heart, Lung, and Blood Institute (NHLBI).2

FIGURE 2
Assessing asthma control and adjusting therapy


ACQ, Asthma Control Questionnaire; ACT, Asthma Control Test; ATAQ, Asthma Therapy Assessment Questionnaire; EIB, exercise-induced bronchospasm; FEV1, forced expiratory volume in 1 second; FVC, forced vital capacity; N/A, not applicable; OCS, oral corticosteroids; SABA, short-acting β2-adrenergic agonist.
*ACQ values of 0.76 to 1.4 are indeterminate regarding well-controlled asthma.
For treatment purposes, children with at least 2 exacerbations (eg, requiring urgent, unscheduled care; hospitalization; or intensive care unit admission) or adolescents/adults with at least 2 exacerbations requiring OCS in the past year may be considered the same as patients who have asthma that is not well controlled, even in the absence of impairment levels consistent with that classification.
Adapted from: National Heart, Lung, and Blood Institute (NHLBI).2

FIGURE 3
Stepwise approach for managing asthma


EIB, exercise-induced bronchospasm; ICS, inhaled corticosteroid; LABA, long-acting β2-adrenergic agonist; LTRA, leukotriene receptor antagonist; OCS, oral corticosteroid; PRN, as needed; SABA, short-acting β2-adrenergic agonist.
Adapted from: National Heart, Lung, and Blood Institute (NHLBI).2

 

 

Putting guidelines into practice begins with the history

A detailed medical history and a physical examination focusing on the upper respiratory tract, chest, and skin are needed to arrive at an asthma diagnosis. JJ’s physician asked his mother to describe recent symptoms and inquired about comorbid conditions that can aggravate asthma. He also identified viral respiratory infections, environmental causes, and activity as precipitating factors.

In considering an asthma diagnosis, try to determine the presence of episodic symptoms of airflow obstruction or bronchial hyperresponsiveness, as well as airflow obstruction that is at least partly reversible (an increase in forced expiratory volume in 1 second [FEV1] of >200 mL and ≥12% from baseline or an increase of ≥10% of predicted FEV1), and to exclude alternative diagnoses.

EPR-3 emphasizes spirometry

Recognizing that patients’ perception of airflow obstruction is highly variable and that pulmonary function measures do not always correlate directly with symptoms,3,4 the EPR-3 recommends spirometry for patients ≥5 years of age, both before and after bronchodilation. In addition to helping to confirm an asthma diagnosis, spirometry is the preferred measure of pulmonary function in classifying severity, because peak expiratory flow (PEF) testing has not proven reliable.5,6

 

FAST TRACK

Low-dose inhaled corticosteroids are safe and effective for the youngest asthma patients

Objective measurement of pulmonary function is difficult to obtain in children <5 years of age. If diagnosis remains uncertain for patients in this age group, a therapeutic trial of medication is recommended. In JJ’s case, however, 3 courses of oral corticosteroids (OCS) in less than 6 months were indicative of persistent asthma.

Spirometry is often underutilized. For patients ≥5 years of age, spirometry is a vital tool, but often underutilized in family practice. A recent study by Yawn and colleagues found that family physicians made changes in the management of approximately half of the asthma patients who underwent spirometry.7 (Information about spirometry training is available through the National Institute for Occupational Safety and Health at http://www.cdc.gov/niosh.) Referral to a specialist is recommended if the physician has difficulty making a differential diagnosis or is unable to perform spirometry on a patient who presents with atypical signs and symptoms of asthma.

What is the patient’s level of severity?

In patients who are not yet receiving long-term controller therapy, severity level is based on an assessment of impairment and risk (FIGURE 1). For patients who are already receiving treatment, severity is determined by the minimum pharmacologic therapy needed to maintain asthma control.

The severity classification—intermittent asthma or persistent asthma that is mild, moderate, or severe—is determined by the most severe category in which any feature occurs. (In children, FEV1/FVC [forced vital capacity] ratio has been shown to be a more sensitive determinant of severity than FEV1,4 which may be more useful in predicting exacerbations.8)

Asthma management: Preferred and alternative Tx

The recommended stepwise interventions include both preferred therapies (evidence-based) and alternative treatments (listed alphabetically in FIGURE 3 because there is insufficient evidence to rank them). The additional steps and age categories support the goal of using the least possible medication needed to maintain good control and minimize the potential for adverse events.

In initiating treatment, select the step that corresponds to the level of severity in the bottom row of FIGURE 1; to adjust medications, determine the patient’s level of asthma control and follow the corresponding guidance in the bottom row of FIGURE 2.

Inhaled corticosteroids remain the bedrock of therapy

ICS, the most potent and consistently effective long-term controller therapy, remain the foundation of therapy for patients of all ages who have persistent asthma. (Evidence: A).

Several of the age-based recommendations follow, with a focus on preferred treatments:

Children 0 to 4 years of age

 

  • The guidelines recommend low-dose ICS at Step 2 (Evidence: A) and medium-dose ICS at Step 3 (Evidence: D), as inhaled corticosteroids have been shown to reduce impairment and risk in this age group.9-16 The potential risk is generally limited to a small reduction in growth velocity during the first year of treatment, and offset by the benefits of therapy.15,16
  • Add a long-acting β2-adrenergic agonist (LABA) or montelukast to medium-dose ICS therapy at Step 4 rather than increasing the ICS dose (Evidence: D) to avoid the risk of side effects associated with high-dose ICS. Montelukast has demonstrated efficacy in children 2 to 5 years of age with persistent asthma.17
  • Recommendations for preferred therapy at Steps 5 (high-dose ICS + LABA or montelukast) and 6 (Step 5 therapy + OCS) are based on expert panel judgment (Evidence: D). When severe persistent asthma warrants Step 6 therapy, start with a 2-week course of the lowest possible dose of OCS to confirm reversibility.
  • In this age group, a therapeutic trial with close monitoring is recommended for patients whose asthma is not well controlled. If there is no response in 4 to 6 weeks, consider alternative therapies or diagnoses (Evidence: D).
 

 

 

FAST TRACK

Spirometry testing, which is underused in family practice, often leads to adjustments in asthma therapy

Children 5 to 11 years of age

 

  • For Step 3 therapy, the guidelines recommend either low-dose ICS plus a LABA, leukotriene receptor antagonist (LTRA), or theophylline; or medium-dose ICS (Evidence: B). Treatment decisions at Step 3 depend on whether impairment or risk is the chief concern, as well as on safety considerations.
  • For Steps 4 and 5, ICS (medium dose for Step 5 and high dose for Step 6) plus a LABA is preferred, based on studies of patients ≥12 years of age (Evidence: B). Step 6 builds on Step 5, adding an OCS to the LABA/ICS combination (Evidence: D).
  • If theophylline is prescribed—a viable option if cost and adherence to inhaled medications are key concerns—serum levels must be closely monitored because of the risk of toxicity.
  • Closely monitor and be prepared to identify and respond to anaphylaxis in a child at Step 2, 3, or 4 who is receiving allergen immunotherapy.

Adolescents ≥12 years of age and adults

 

  • There are 2 preferred Step 3 treatments: Low-dose ICS plus a LABA, or medium-dose ICS. The combination therapy has shown greater improvement in impairment24,25 and risk24-26 compared with the higher dose of ICS.
  • Preferred treatments at Steps 4, 5, and 6 are the same as those for children ages 5 to 11 years, with one exception: Subcutaneous anti-IgE therapy (omalizumab) may be added to the regimen at Steps 5 and 6 for adolescents and adults with severe persistent allergic asthma to reduce the risk of exacerbations.27

 

FAST TRACK

If a step down is in order, reduce ICS dosing gradually, at a rate of about 25% to 50% every 3 months

Weigh the benefits and risks of therapy

Safety is a key consideration for all asthma patients. Carefully weigh the benefits and risks of therapy, including the rare but potential risk of life-threatening or fatal exacerbations with daily LABA therapy28 and systemic effects with higher doses of ICS.23 Patients who begin receiving oral corticosteroids require close monitoring, regardless of age.

Regular reassessment and monitoring are critical

 

FAST TRACK

For a list of asthma education resources, see Table W1 online at www.jfponline.com

Schedule visits at 2- to 6-week intervals for those who are starting therapy or require a step up to achieve or regain asthma control. After control is achieved, reassess at least every 1 to 6 months. Measures of asthma control are the same as those used to assess severity, with the addition of validated multidimensional questionnaires (eg, Asthma Control Test [ACT])29 to gauge impairment.

JJ’s physician scheduled a follow-up visit in 4 weeks, at which time he did a reassessment based on a physical exam and symptom recall. Finding JJ’s asthma to be well controlled, the physician asked the boy’s mother to bring him back to the office in 2 months, or earlier if symptoms recurred.

TABLE W1
Asthma education resources

 

Allergy & Asthma Network Mothers of Asthmatics
2751 Prosperity Avenue, Suite 150
Fairfax, VA 22030
www.breatherville.org
(800) 878-4403 or (703) 641-9595		Asthma and Allergy Foundation of America
1233 20th Street, NW, Suite 402
Washington, DC 20036
www.aafa.org
(800) 727-8462
American Academy of Allergy,
Asthma, and Immunology
555 East Wells Street, Suite 1100
Milwaukee, WI 53202-3823
www.aaaai.org
(414) 272-6071		Centers for Disease Control and Prevention
1600 Clifton Road
Atlanta, GA 30333
www.cdc.gov
(800) 311-3435
American Association for Respiratory Care
9125 North macArthur boulevard, Suite 100
Irving, TX 75063
www.aarc.org
(972) 243-2272		Food Allergy & Anaphylaxis Network
11781 lee Jackson Highway, Suite 160
Fairfax, VA 22033
www.foodallergy.org
(800) 929-4040
American College of Allergy, Asthma, and Immunology
85 West Algonquin road, Suite 550
Arlington Heights, IL 60005
www.acaai.org
(800) 842-7777 or (847) 427-1200		National Heart, Lung, and Blood Institute Information Center
P.O. Box 30105
Bethesda, MD 20824-0105
www.nhlbi.nih.gov
(301) 592-8573
American Lung Association
61 Broadway
New York, NY 10006
www.lungusa.org
(800) 586-4872		National Jewish Medical and Research Center (Lung Line)
1400 Jackson Street
Denver, CO 80206
www.njc.org
(800) 222-lUNG
Association of Asthma Educators
1215 Anthony Avenue
Columbia, SC 29201
www.asthmaeducators.org
(888) 988-7747		US Environmental Protection Agency
National Center for Environmental Publications
P.O. Box 42419
Cincinnati, OH 45242-0419
www.airnow.gov
(800) 490-9198

Does your patient require a step down or step up?

A step down is recommended for patients whose asthma is well controlled for 3 months or more. Reduce the dose of ICS gradually, about 25% to 50% every 3 months, because deterioration in asthma control is highly variable. Review adherence and medication administration technique with patients whose asthma is not well controlled, and consider a step up in treatment. If an alternative treatment is used but does not result in an adequate response, it should be discontinued and the preferred treatment used before stepping up. Refer patients to an asthma specialist if their asthma does not respond to these adjustments.

 

 

Partner with patients for optimal care

The EPR-3 recommends the integration of patient education into all aspects of asthma care. To forge an active partnership, identify and address concerns about the condition and its treatment and involve the patient and family in developing treatment goals and making treatment decisions. If the patient is old enough, encourage self-monitoring and management.

The EPR-3 recommends that physicians give every patient a written asthma action plan that addresses individual symptoms and/or PEF measurements and includes instructions for self-management. Daily PEF monitoring can be useful in identifying early changes in the disease state and evaluating response to changes in therapy. It is ideal for those who have moderate to severe persistent asthma, difficulty recognizing signs of exacerbations, or a history of severe exacerbations.

Correspondence
Stuart W. Stoloff, MD, Clinical Professor, Department of Family and Community Medicine, University of Nevada–Reno, 1200 Mountain Street, Suite 220, Carson City, NV 89703; [email protected].

 

Practice recommendations

 

  • Assess asthma severity before initiating treatment; monitor asthma control to guide adjustments in therapy using measures of impairment (B) and risk (C) (National Heart, Lung, and Blood Institute [NHLBI] and National Asthma Education and Prevention Program [NAEPP] third expert panel report [EPR-3]).
  • Base treatment decisions on recommendations specific to each age group (0-4 years, 5-11 years, and ≥12 years) (A).
  • Use spirometry in patients ≥5 years of age to diagnose asthma, classify severity, and assess control (C).
  • Provide each patient with a written asthma action plan with instructions for daily disease management, as well as identification of, and response to, worsening symptoms (B).

EPR-3 evidence categories:

 

  1. Randomized, controlled trials (RCTs), rich body of data
  2. RCTs, limited body of data
  3. Nonrandomized trials and observational studies
  4. Panel consensus judgment

JJ, a 4-year-old boy, was taken to an urgent care clinic 3 times last winter for “recurrent bronchitis” and given a 7-day course of prednisone and antibiotics at each visit. His mother reports that “his colds always seem to go to his chest” and his skin is always dry. She was given a nebulizer and albuterol for use when JJ begins wheezing, which often happens when he has a cold, plays vigorously, or visits a friend who has cats.

JJ is one of approximately 6.7 million children—and 22.9 million US residents—who have asthma.1 To help guide the care of patients like JJ, the National Heart, Lung, and Blood Institute (NHLBI) and National Asthma Education and Prevention Program (NAEPP) released the third expert panel report (EPR-3) in 2007. Available at http://www.nhlbi.nih.gov/guidelines/asthma/asthgdln.htm, the EPR-3 provides the most comprehensive evidence-based guidance for the diagnosis and management of asthma to date.2

The guidelines were an invaluable resource for JJ’s family physician, who referred to them to categorize the severity of JJ’s asthma as “mild persistent.” In initiating treatment, JJ’s physician relied on specific recommendations for children 0 to 4 years of age to prescribe low-dose inhaled corticosteroids (ICS). Without the new guidelines, which underscore the safety of controller medication for young children, JJ’s physician would likely have been reluctant to place a 4-year-old on ICS.

This review highlights the EPR-3’s key recommendations to encourage widespread implementation by family physicians.

The EPR-3: What’s changed

The 2007 guidelines:
Recommend assessing asthma severity before starting treatment and assessing asthma control to guide adjustments in treatment.
Address both severity and control in terms of impairment and risk.
Feature 3 age breakdowns (0-4 years, 5-11 years, and ≥12 years) and a 6-step approach to asthma management.
Make it easier to individualize and adjust treatment.

What’s changed?

There’s a new paradigm

The 2007 update to guidelines released in 1997 and 2002 reflects a paradigm shift in the overall approach to asthma management. The change in focus addresses the highly variable nature of asthma2 and the recognition that asthma severity and asthma control are distinct concepts serving different functions in clinical practice.

Severity and control in 2 domains. Asthma severity—a measure of the intrinsic intensity of the disease process—is ideally assessed before initiating treatment. In contrast, asthma control is monitored over time to guide adjustments to therapy. The guidelines call for assessing severity and control within the domains of:

 

  • impairment, based on asthma symptoms (identified by patient or caregiver recall of the past 2-4 weeks), quality of life, and functional limitations; and
  • risk, of asthma exacerbations, progressive decline in pulmonary function (or reduced lung growth in children), or adverse events. Predictors of increased risk for exacerbations or death include persistent and/or severe airflow obstruction; at least 2 visits to the emergency department or hospitalizations for asthma within the past year; and a history of intubation or admission to intensive care, especially within the past 5 years.

 

FAST TRACK

Peak expiratory flow testing is not a reliable measure of asthma severity

The specific criteria for determining asthma severity and assessing asthma control are detailed in FIGURES 1 AND 2, respectively. Because treatment affects impairment and risk differently, this dual assessment helps ensure that therapeutic interventions minimize all manifestations of asthma as much as possible.

More steps and age-specific interventions. The EPR-3’s stepwise approach to asthma therapy has gone from 4 steps to 6, and the recommended treatments, as well as the levels of severity and criteria for assessing control that guide them, are now divided into 3 age groups: 0 to 4 years, 5 to 11 years, and ≥12 years (FIGURE 3). The previous guidelines, issued in 2002, divided treatment recommendations into 2 age groups: ≤5 years and >5 years. The EPR-3’s expansion makes it easier for physicians to initiate, individualize, and adjust treatment.

FIGURE 1
Classifying asthma severity and initiating therapy in children, adolescents, and adults


EIB, exercise-induced bronchospasm; FEV1, forced expiratory volume in 1 second; FVC, forced vital capacity; ICS, inhaled corticosteroids; NA, not applicable; OCS, oral corticosteroids; SABA, short-acting β2-adrenergic agonist.
*Normal FEV1/FVC values are defined according to age: 8–9 years (85%), 20–39 years (80%), 40–59 years (75%), 60–80 years (70%).
For treatment purposes, children with at least 2 exacerbations (eg, requiring urgent, unscheduled care; hospitalization; or intensive care unit admission) or adolescents/adults with at least 2 exacerbations requiring OCS in the past year may be considered the same as patients who have persistent asthma, even in the absence of impairment levels consistent with persistent asthma.
Adapted from: National Heart, Lung, and Blood Institute (NHLBI).2

FIGURE 2
Assessing asthma control and adjusting therapy


ACQ, Asthma Control Questionnaire; ACT, Asthma Control Test; ATAQ, Asthma Therapy Assessment Questionnaire; EIB, exercise-induced bronchospasm; FEV1, forced expiratory volume in 1 second; FVC, forced vital capacity; N/A, not applicable; OCS, oral corticosteroids; SABA, short-acting β2-adrenergic agonist.
*ACQ values of 0.76 to 1.4 are indeterminate regarding well-controlled asthma.
For treatment purposes, children with at least 2 exacerbations (eg, requiring urgent, unscheduled care; hospitalization; or intensive care unit admission) or adolescents/adults with at least 2 exacerbations requiring OCS in the past year may be considered the same as patients who have asthma that is not well controlled, even in the absence of impairment levels consistent with that classification.
Adapted from: National Heart, Lung, and Blood Institute (NHLBI).2

FIGURE 3
Stepwise approach for managing asthma


EIB, exercise-induced bronchospasm; ICS, inhaled corticosteroid; LABA, long-acting β2-adrenergic agonist; LTRA, leukotriene receptor antagonist; OCS, oral corticosteroid; PRN, as needed; SABA, short-acting β2-adrenergic agonist.
Adapted from: National Heart, Lung, and Blood Institute (NHLBI).2

 

 

Putting guidelines into practice begins with the history

A detailed medical history and a physical examination focusing on the upper respiratory tract, chest, and skin are needed to arrive at an asthma diagnosis. JJ’s physician asked his mother to describe recent symptoms and inquired about comorbid conditions that can aggravate asthma. He also identified viral respiratory infections, environmental causes, and activity as precipitating factors.

In considering an asthma diagnosis, try to determine the presence of episodic symptoms of airflow obstruction or bronchial hyperresponsiveness, as well as airflow obstruction that is at least partly reversible (an increase in forced expiratory volume in 1 second [FEV1] of >200 mL and ≥12% from baseline or an increase of ≥10% of predicted FEV1), and to exclude alternative diagnoses.

EPR-3 emphasizes spirometry

Recognizing that patients’ perception of airflow obstruction is highly variable and that pulmonary function measures do not always correlate directly with symptoms,3,4 the EPR-3 recommends spirometry for patients ≥5 years of age, both before and after bronchodilation. In addition to helping to confirm an asthma diagnosis, spirometry is the preferred measure of pulmonary function in classifying severity, because peak expiratory flow (PEF) testing has not proven reliable.5,6

 

FAST TRACK

Low-dose inhaled corticosteroids are safe and effective for the youngest asthma patients

Objective measurement of pulmonary function is difficult to obtain in children <5 years of age. If diagnosis remains uncertain for patients in this age group, a therapeutic trial of medication is recommended. In JJ’s case, however, 3 courses of oral corticosteroids (OCS) in less than 6 months were indicative of persistent asthma.

Spirometry is often underutilized. For patients ≥5 years of age, spirometry is a vital tool, but often underutilized in family practice. A recent study by Yawn and colleagues found that family physicians made changes in the management of approximately half of the asthma patients who underwent spirometry.7 (Information about spirometry training is available through the National Institute for Occupational Safety and Health at http://www.cdc.gov/niosh.) Referral to a specialist is recommended if the physician has difficulty making a differential diagnosis or is unable to perform spirometry on a patient who presents with atypical signs and symptoms of asthma.

What is the patient’s level of severity?

In patients who are not yet receiving long-term controller therapy, severity level is based on an assessment of impairment and risk (FIGURE 1). For patients who are already receiving treatment, severity is determined by the minimum pharmacologic therapy needed to maintain asthma control.

The severity classification—intermittent asthma or persistent asthma that is mild, moderate, or severe—is determined by the most severe category in which any feature occurs. (In children, FEV1/FVC [forced vital capacity] ratio has been shown to be a more sensitive determinant of severity than FEV1,4 which may be more useful in predicting exacerbations.8)

Asthma management: Preferred and alternative Tx

The recommended stepwise interventions include both preferred therapies (evidence-based) and alternative treatments (listed alphabetically in FIGURE 3 because there is insufficient evidence to rank them). The additional steps and age categories support the goal of using the least possible medication needed to maintain good control and minimize the potential for adverse events.

In initiating treatment, select the step that corresponds to the level of severity in the bottom row of FIGURE 1; to adjust medications, determine the patient’s level of asthma control and follow the corresponding guidance in the bottom row of FIGURE 2.

Inhaled corticosteroids remain the bedrock of therapy

ICS, the most potent and consistently effective long-term controller therapy, remain the foundation of therapy for patients of all ages who have persistent asthma. (Evidence: A).

Several of the age-based recommendations follow, with a focus on preferred treatments:

Children 0 to 4 years of age

 

  • The guidelines recommend low-dose ICS at Step 2 (Evidence: A) and medium-dose ICS at Step 3 (Evidence: D), as inhaled corticosteroids have been shown to reduce impairment and risk in this age group.9-16 The potential risk is generally limited to a small reduction in growth velocity during the first year of treatment, and offset by the benefits of therapy.15,16
  • Add a long-acting β2-adrenergic agonist (LABA) or montelukast to medium-dose ICS therapy at Step 4 rather than increasing the ICS dose (Evidence: D) to avoid the risk of side effects associated with high-dose ICS. Montelukast has demonstrated efficacy in children 2 to 5 years of age with persistent asthma.17
  • Recommendations for preferred therapy at Steps 5 (high-dose ICS + LABA or montelukast) and 6 (Step 5 therapy + OCS) are based on expert panel judgment (Evidence: D). When severe persistent asthma warrants Step 6 therapy, start with a 2-week course of the lowest possible dose of OCS to confirm reversibility.
  • In this age group, a therapeutic trial with close monitoring is recommended for patients whose asthma is not well controlled. If there is no response in 4 to 6 weeks, consider alternative therapies or diagnoses (Evidence: D).
 

 

 

FAST TRACK

Spirometry testing, which is underused in family practice, often leads to adjustments in asthma therapy

Children 5 to 11 years of age

 

  • For Step 3 therapy, the guidelines recommend either low-dose ICS plus a LABA, leukotriene receptor antagonist (LTRA), or theophylline; or medium-dose ICS (Evidence: B). Treatment decisions at Step 3 depend on whether impairment or risk is the chief concern, as well as on safety considerations.
  • For Steps 4 and 5, ICS (medium dose for Step 5 and high dose for Step 6) plus a LABA is preferred, based on studies of patients ≥12 years of age (Evidence: B). Step 6 builds on Step 5, adding an OCS to the LABA/ICS combination (Evidence: D).
  • If theophylline is prescribed—a viable option if cost and adherence to inhaled medications are key concerns—serum levels must be closely monitored because of the risk of toxicity.
  • Closely monitor and be prepared to identify and respond to anaphylaxis in a child at Step 2, 3, or 4 who is receiving allergen immunotherapy.

Adolescents ≥12 years of age and adults

 

  • There are 2 preferred Step 3 treatments: Low-dose ICS plus a LABA, or medium-dose ICS. The combination therapy has shown greater improvement in impairment24,25 and risk24-26 compared with the higher dose of ICS.
  • Preferred treatments at Steps 4, 5, and 6 are the same as those for children ages 5 to 11 years, with one exception: Subcutaneous anti-IgE therapy (omalizumab) may be added to the regimen at Steps 5 and 6 for adolescents and adults with severe persistent allergic asthma to reduce the risk of exacerbations.27

 

FAST TRACK

If a step down is in order, reduce ICS dosing gradually, at a rate of about 25% to 50% every 3 months

Weigh the benefits and risks of therapy

Safety is a key consideration for all asthma patients. Carefully weigh the benefits and risks of therapy, including the rare but potential risk of life-threatening or fatal exacerbations with daily LABA therapy28 and systemic effects with higher doses of ICS.23 Patients who begin receiving oral corticosteroids require close monitoring, regardless of age.

Regular reassessment and monitoring are critical

 

FAST TRACK

For a list of asthma education resources, see Table W1 online at www.jfponline.com

Schedule visits at 2- to 6-week intervals for those who are starting therapy or require a step up to achieve or regain asthma control. After control is achieved, reassess at least every 1 to 6 months. Measures of asthma control are the same as those used to assess severity, with the addition of validated multidimensional questionnaires (eg, Asthma Control Test [ACT])29 to gauge impairment.

JJ’s physician scheduled a follow-up visit in 4 weeks, at which time he did a reassessment based on a physical exam and symptom recall. Finding JJ’s asthma to be well controlled, the physician asked the boy’s mother to bring him back to the office in 2 months, or earlier if symptoms recurred.

TABLE W1
Asthma education resources

 

Allergy & Asthma Network Mothers of Asthmatics
2751 Prosperity Avenue, Suite 150
Fairfax, VA 22030
www.breatherville.org
(800) 878-4403 or (703) 641-9595		Asthma and Allergy Foundation of America
1233 20th Street, NW, Suite 402
Washington, DC 20036
www.aafa.org
(800) 727-8462
American Academy of Allergy,
Asthma, and Immunology
555 East Wells Street, Suite 1100
Milwaukee, WI 53202-3823
www.aaaai.org
(414) 272-6071		Centers for Disease Control and Prevention
1600 Clifton Road
Atlanta, GA 30333
www.cdc.gov
(800) 311-3435
American Association for Respiratory Care
9125 North macArthur boulevard, Suite 100
Irving, TX 75063
www.aarc.org
(972) 243-2272		Food Allergy & Anaphylaxis Network
11781 lee Jackson Highway, Suite 160
Fairfax, VA 22033
www.foodallergy.org
(800) 929-4040
American College of Allergy, Asthma, and Immunology
85 West Algonquin road, Suite 550
Arlington Heights, IL 60005
www.acaai.org
(800) 842-7777 or (847) 427-1200		National Heart, Lung, and Blood Institute Information Center
P.O. Box 30105
Bethesda, MD 20824-0105
www.nhlbi.nih.gov
(301) 592-8573
American Lung Association
61 Broadway
New York, NY 10006
www.lungusa.org
(800) 586-4872		National Jewish Medical and Research Center (Lung Line)
1400 Jackson Street
Denver, CO 80206
www.njc.org
(800) 222-lUNG
Association of Asthma Educators
1215 Anthony Avenue
Columbia, SC 29201
www.asthmaeducators.org
(888) 988-7747		US Environmental Protection Agency
National Center for Environmental Publications
P.O. Box 42419
Cincinnati, OH 45242-0419
www.airnow.gov
(800) 490-9198

Does your patient require a step down or step up?

A step down is recommended for patients whose asthma is well controlled for 3 months or more. Reduce the dose of ICS gradually, about 25% to 50% every 3 months, because deterioration in asthma control is highly variable. Review adherence and medication administration technique with patients whose asthma is not well controlled, and consider a step up in treatment. If an alternative treatment is used but does not result in an adequate response, it should be discontinued and the preferred treatment used before stepping up. Refer patients to an asthma specialist if their asthma does not respond to these adjustments.

 

 

Partner with patients for optimal care

The EPR-3 recommends the integration of patient education into all aspects of asthma care. To forge an active partnership, identify and address concerns about the condition and its treatment and involve the patient and family in developing treatment goals and making treatment decisions. If the patient is old enough, encourage self-monitoring and management.

The EPR-3 recommends that physicians give every patient a written asthma action plan that addresses individual symptoms and/or PEF measurements and includes instructions for self-management. Daily PEF monitoring can be useful in identifying early changes in the disease state and evaluating response to changes in therapy. It is ideal for those who have moderate to severe persistent asthma, difficulty recognizing signs of exacerbations, or a history of severe exacerbations.

Correspondence
Stuart W. Stoloff, MD, Clinical Professor, Department of Family and Community Medicine, University of Nevada–Reno, 1200 Mountain Street, Suite 220, Carson City, NV 89703; [email protected].

References

 

1. National Center for Health Statistics. Fast stats A to Z. Available at: www.cdc.gov/nchs/fastats/asthma.htm. Accessed August 1, 2008.

2. National Heart, Lung, and Blood Institute (NHLBI). National Asthma Education and Prevention Program Expert Panel Report 3: Guidelines for the Diagnosis and Management of Asthma. Full Report 2007. Bethesda, MD: NHLBI; August 2007. NIH publication no. 07-4051. Available at: http://www.nhlbi.nih.gov/guidelines/asthma/asthgdln.htm. Accessed July 17, 2008.

3. Stout JW, Visness CM, Enright P, et al. Classification of asthma severity in children: the contribution of pulmonary function testing. Arch Pediatr Adolesc Med. 2006;160:844-850.

4. Bacharier LB, Strunk RC, Mauger D, et al. Classifying asthma severity in children: mismatch between symptoms, medication use, and lung function. Am J Respir Crit Care Med. 2004;170:426-432.

5. Eid N, Yandell B, Howell L, Eddy M, Sheikh S. Can children with asthma? Pediatrics. 2000;105:354-358.

6. Llewellin P, Sawyer G, Lewis S, et al. The relationship between FEV1 and PEF in the assessment of the severity of airways obstruction. Respirology. 2002;7:333-337.

7. Yawn BP, Enright PL, Lemanske RF, Jr, et al. Spirometry can be done in family physicians’ offices and alters clinical decisions in management of asthma and COPD. Chest. 2007;132:1162-1168.

8. Fuhlbrigge AL, Kitch BT, Paltiel AD, et al. FEV1 is associated with risk of asthma attacks in a pediatric population. J Allergy Clin Immunol. 2001;107:61-67.

9. Roorda RJ, Mezei G, Bisgaard H, Maden C. Response of preschool children with asthma symptoms to fluticasone propionate. J Allergy Clin Immunol. 2001;108:540-546.

10. Baker JW, Mellon M, Wald J, Welch M, Cruz-Rivera M, Walton-Bowen K. A multiple-dosing, placebo-controlled study of budesonide inhalation suspension given once or twice daily for treatment of persistent asthma in young children and infants. Pediatrics. 1999;103:414-421.

11. Kemp JP, Skoner DP, Szefler SJ, Walton-Bowen K, Cruz-Rivera M, Smith JA. Once-daily budesonide inhalation suspension for the treatment of persistent asthma in infants and young children. Ann Allergy Asthma Immunol. 1999;83:231-239.

12. Shapiro G, Mendelson L, Kraemer MJ, Cruz-Rivera M, Walton-Bowen K, Smith JA. Efficacy and safety of budesonide inhalation suspension (Pulmicort Respules) in young children with inhaled steroid-dependent, persistent asthma. J Allergy Clin Immunol. 1998;102:789-796.

13. Bisgaard H, Gillies J, Groenewald M, Maden C. The effect of inhaled fluticasone propionate in the treatment of young asthmatic children: a dose comparison study. Am J Respir Crit Care Med. 1999;160:126-131.

14. Szefler SJ, Eigen H. Budesonide inhalation suspension: a nebulized corticosteroid for persistent asthma. J Allergy Clin Immunol. 2002;109:730-742.

15. Guilbert TW, Morgan WJ, Zeiger RS, et al. Long-term inhaled corticosteroids in preschool children at high risk for asthma. N Engl J Med. 2006;354:1985-1997.

16. Bisgaard H, Allen D, Milanowski J, Kalev I, Willits L, Davies P. Twelve-month safety and efficacy of inhaled fluticasone propionate in children aged 1 to 3 years with recurrent wheezing. Pediatrics. 2004;113:e87-e94.

17. Knorr B, Franchi LM, Bisgaard H, et al. Montelukast, a leukotriene receptor antagonist, for the treatment of persistent asthma in children aged 2 to 5 years. Pediatrics 2001;108:e48.-

18. Russell G, Williams DA, Weller P, Price JF. Salmeterol xinafoate in children on high dose inhaled steroids. Ann Allergy Asthma Immunol. 1995;75:423-428.

19. Zimmerman B, D’Urzo A, Bérubé D. Efficacy and safety of formoterol Turbuhaler when added to inhaled corticosteroid treatment in children with asthma. Pediatr Pulmonol. 2004;37:122-127.

20. Simons FE, Villa JR, Lee BW, et al. Montelukast added to budesonide in children with persistent asthma: a randomized, double-blind, crossover study. J Pediatr. 2001;138:694-698.

21. Shapiro G, Bronsky EA, LaForce CF, et al. Dose-related efficacy of budesonide administered via a dry powder inhaler in the treatment of children with moderate to severe persistent asthma. J Pediatr. 1998;132:976-982.

22. Pauwels RA, Lofdahl C-G, Postma DS, et al. for the Formoterol and Corticosteroids Establishing Therapy (FACET) International Study Group. Effect of inhaled formoterol and budesonide on exacerbations of asthma. N Engl J Med. 1997;337:1405-1411.

23. Tattersfield AE, Harrison TW, Hubbard RB, Mortimer K. Safety of inhaled corticosteroids. Proc Am Thorac Soc. 2004;1:171-175.

24. Bateman ED, Boushey HA, Bousquet J, et al. For the GOAL Investigators Group. Can guideline-defined asthma control be achieved? The Gaining Optimal Asthma ControL study. Am J Respir Crit Care Med. 2004;170:836-844.

25. O’Byrne PM, Barnes PJ, Rodriguez-Roisin R, et al. Low dose inhaled budesonide and formoterol in mild persistent asthma: the OPTIMA randomized trial. Am J Respir Crit Care Med. 2001;164:1392-1397.

26. Masoli M, Weatherall M, Holt S, Beasley R. Moderate dose inhaled corticosteroids plus salmeterol versus higher doses of inhaled corticosteroids in symptomatic asthma. Thorax. 2005;60:730-734.

27. Bousquet J, Wenzel S, Holgate S, Lumry W, Freeman P, Fox H. Predicting response to omalizumab, an anti-IgE antibody, in patients with allergic asthma. Chest. 2004;125:1378-1386.

28. Nelson HS, Weiss ST, Bleecker ER, Yancey SW, Dorinsky PM. For the SMART Study Group. The Salmeterol Multicenter Asthma Research Trial: a comparison of usual pharmacotherapy for asthma or usual pharmacotherapy plus salmeterol. Chest. 2006;129:15-26.

29. Nathan RA, Sorkness CA, Kosinski M, et al. Development of the asthma control test: a survey for assessing asthma control. J Allergy Clin Immunol. 2004;113:59-65.

References

 

1. National Center for Health Statistics. Fast stats A to Z. Available at: www.cdc.gov/nchs/fastats/asthma.htm. Accessed August 1, 2008.

2. National Heart, Lung, and Blood Institute (NHLBI). National Asthma Education and Prevention Program Expert Panel Report 3: Guidelines for the Diagnosis and Management of Asthma. Full Report 2007. Bethesda, MD: NHLBI; August 2007. NIH publication no. 07-4051. Available at: http://www.nhlbi.nih.gov/guidelines/asthma/asthgdln.htm. Accessed July 17, 2008.

3. Stout JW, Visness CM, Enright P, et al. Classification of asthma severity in children: the contribution of pulmonary function testing. Arch Pediatr Adolesc Med. 2006;160:844-850.

4. Bacharier LB, Strunk RC, Mauger D, et al. Classifying asthma severity in children: mismatch between symptoms, medication use, and lung function. Am J Respir Crit Care Med. 2004;170:426-432.

5. Eid N, Yandell B, Howell L, Eddy M, Sheikh S. Can children with asthma? Pediatrics. 2000;105:354-358.

6. Llewellin P, Sawyer G, Lewis S, et al. The relationship between FEV1 and PEF in the assessment of the severity of airways obstruction. Respirology. 2002;7:333-337.

7. Yawn BP, Enright PL, Lemanske RF, Jr, et al. Spirometry can be done in family physicians’ offices and alters clinical decisions in management of asthma and COPD. Chest. 2007;132:1162-1168.

8. Fuhlbrigge AL, Kitch BT, Paltiel AD, et al. FEV1 is associated with risk of asthma attacks in a pediatric population. J Allergy Clin Immunol. 2001;107:61-67.

9. Roorda RJ, Mezei G, Bisgaard H, Maden C. Response of preschool children with asthma symptoms to fluticasone propionate. J Allergy Clin Immunol. 2001;108:540-546.

10. Baker JW, Mellon M, Wald J, Welch M, Cruz-Rivera M, Walton-Bowen K. A multiple-dosing, placebo-controlled study of budesonide inhalation suspension given once or twice daily for treatment of persistent asthma in young children and infants. Pediatrics. 1999;103:414-421.

11. Kemp JP, Skoner DP, Szefler SJ, Walton-Bowen K, Cruz-Rivera M, Smith JA. Once-daily budesonide inhalation suspension for the treatment of persistent asthma in infants and young children. Ann Allergy Asthma Immunol. 1999;83:231-239.

12. Shapiro G, Mendelson L, Kraemer MJ, Cruz-Rivera M, Walton-Bowen K, Smith JA. Efficacy and safety of budesonide inhalation suspension (Pulmicort Respules) in young children with inhaled steroid-dependent, persistent asthma. J Allergy Clin Immunol. 1998;102:789-796.

13. Bisgaard H, Gillies J, Groenewald M, Maden C. The effect of inhaled fluticasone propionate in the treatment of young asthmatic children: a dose comparison study. Am J Respir Crit Care Med. 1999;160:126-131.

14. Szefler SJ, Eigen H. Budesonide inhalation suspension: a nebulized corticosteroid for persistent asthma. J Allergy Clin Immunol. 2002;109:730-742.

15. Guilbert TW, Morgan WJ, Zeiger RS, et al. Long-term inhaled corticosteroids in preschool children at high risk for asthma. N Engl J Med. 2006;354:1985-1997.

16. Bisgaard H, Allen D, Milanowski J, Kalev I, Willits L, Davies P. Twelve-month safety and efficacy of inhaled fluticasone propionate in children aged 1 to 3 years with recurrent wheezing. Pediatrics. 2004;113:e87-e94.

17. Knorr B, Franchi LM, Bisgaard H, et al. Montelukast, a leukotriene receptor antagonist, for the treatment of persistent asthma in children aged 2 to 5 years. Pediatrics 2001;108:e48.-

18. Russell G, Williams DA, Weller P, Price JF. Salmeterol xinafoate in children on high dose inhaled steroids. Ann Allergy Asthma Immunol. 1995;75:423-428.

19. Zimmerman B, D’Urzo A, Bérubé D. Efficacy and safety of formoterol Turbuhaler when added to inhaled corticosteroid treatment in children with asthma. Pediatr Pulmonol. 2004;37:122-127.

20. Simons FE, Villa JR, Lee BW, et al. Montelukast added to budesonide in children with persistent asthma: a randomized, double-blind, crossover study. J Pediatr. 2001;138:694-698.

21. Shapiro G, Bronsky EA, LaForce CF, et al. Dose-related efficacy of budesonide administered via a dry powder inhaler in the treatment of children with moderate to severe persistent asthma. J Pediatr. 1998;132:976-982.

22. Pauwels RA, Lofdahl C-G, Postma DS, et al. for the Formoterol and Corticosteroids Establishing Therapy (FACET) International Study Group. Effect of inhaled formoterol and budesonide on exacerbations of asthma. N Engl J Med. 1997;337:1405-1411.

23. Tattersfield AE, Harrison TW, Hubbard RB, Mortimer K. Safety of inhaled corticosteroids. Proc Am Thorac Soc. 2004;1:171-175.

24. Bateman ED, Boushey HA, Bousquet J, et al. For the GOAL Investigators Group. Can guideline-defined asthma control be achieved? The Gaining Optimal Asthma ControL study. Am J Respir Crit Care Med. 2004;170:836-844.

25. O’Byrne PM, Barnes PJ, Rodriguez-Roisin R, et al. Low dose inhaled budesonide and formoterol in mild persistent asthma: the OPTIMA randomized trial. Am J Respir Crit Care Med. 2001;164:1392-1397.

26. Masoli M, Weatherall M, Holt S, Beasley R. Moderate dose inhaled corticosteroids plus salmeterol versus higher doses of inhaled corticosteroids in symptomatic asthma. Thorax. 2005;60:730-734.

27. Bousquet J, Wenzel S, Holgate S, Lumry W, Freeman P, Fox H. Predicting response to omalizumab, an anti-IgE antibody, in patients with allergic asthma. Chest. 2004;125:1378-1386.

28. Nelson HS, Weiss ST, Bleecker ER, Yancey SW, Dorinsky PM. For the SMART Study Group. The Salmeterol Multicenter Asthma Research Trial: a comparison of usual pharmacotherapy for asthma or usual pharmacotherapy plus salmeterol. Chest. 2006;129:15-26.

29. Nathan RA, Sorkness CA, Kosinski M, et al. Development of the asthma control test: a survey for assessing asthma control. J Allergy Clin Immunol. 2004;113:59-65.

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The Journal of Family Practice - 57(9)
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The Journal of Family Practice - 57(9)
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