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Bacterial Meningitis, Non-Specific Troponin Elevation, Antibiotics for ECOPD, VTE Update, and More

Treatment of Bacterial Meningitis with Vancomycin

Ricard JD, Wolff M, Lacherade JC, et al. Levels of vancomycin in cerebrospinal fluid of adult patients receiving adjunctive corticosteroids to treat pneumococcal meningitis: a prospective multicenter observational study. Clin Infect Dis. 2007 Jan 15;44(2):250-255. Epub 2006 Dec 15.

In 2002, van de Beek and de Gans published a study demonstrating that adjuvant dexamethasone decreased mortality and improved neurological disability when given to patients with bacterial meningitis. Their results changed our treatment paradigm for this disease but left us with several questions. At what point in the treatment course does giving corticosteroids become ineffective? Do their results apply to all bacterial pathogens? Can the results be applied to the use of vancomycin in treating penicillin-resistant strains of Streptococcus pneumoniae? This final question arises from the disturbing ability of vancomycin to penetrate the cerebrospinal fluid (CSF). Previous data support this concern; thus, bactericidal titers may be inadequate within the CSF. Because meningeal inflammation exerts a strong influence over whether or not vancomycin enters the CSF, administering steroids may decrease its ability to do so. This study brings some clarity to the issue.

In this observational open multicenter trial from France, 14 adults were admitted to intensive care units with suspected pneumococcal meningitis. They were treated with intravenous cefotaxime, vancomycin, and dexamethasone. The vancomycin was given as a loading dose of 15 mg per kg of body weight followed by administration of a continuous infusion of 60 mg per kg of body weight per day. The diagnosis of pneumococcal meningitis was made using a CSF pleocytosis as well as one or more of the following: a positive culture from either the blood or CSF, a Gram stain showing Gram-positive diplococci, or pneumococcal antigens in the CSF as demonstrated by latex agglutination. Patients had a second lumbar puncture on either day two or three to measure vancomycin levels—among other markers of disease activity—in the CSF. Serum levels of vancomycin were drawn simultaneously.

Thirteen of the 14 patients had pneumococcal meningitis; one patient was found to have meningitis from Neisseria meningitidis. Seven patients had pneumococcal strains resistant to penicillin. Ten of the 14 patients required mechanical intubation. The second lumbar puncture demonstrated marked improvements in leukocyte counts, protein levels, and glucose levels. All subsequent cultures from the CSF were negative. Three patients died, two had neurological sequelae, and the remainder were discharged from the hospital without complications. Vancomycin concentrations in the serum ranged from 14.2 to 39.0 mg/L, with a mean of 25.2 mg/L; concentrations in the CSF ranged from 3.1 to 22.3 mg/L, with a mean of 7.9 mg/L. There was a significant correlation between vancomycin levels in the serum and those in the CSF (r = 0.68; P = 0.01). The concentration of vancomycin in the CSF was between four and 10 times the mean inhibitory concentrations (MICs). A linear correlation exists between penetration of vancomycin into CSF and serum levels. No evidence of drug toxicities was observed.

The results demonstrate that a therapeutic concentration of vancomycin can be achieved in the CSF. The continuous infusion of vancomycin with a loading dose, which has not been standard practice, has previously been shown to achieve targeted serum levels more quickly than intermittent dosing. Levels of serum vancomycin were likely higher in this study than when troughs of 15-20 mg/L are the goal. This data strongly suggests, however, that this same treatment regimen can obtain adequate vancomycin levels in the CSF while treating pneumococcal meningitis with adjunctive steroids.

Though this is a retrospective trial, it provides guidance for a very common clinical scenario.
 

 

Nonspecific elevations in troponins

Alcalai R, Planer D, Culhaoqlu A, et al. Acute coronary syndrome vs nonspecific troponin elevation: clinical predictors and survival analysis. Arch Intern Med. 2007 Feb 12;167(3):276-281.

In 2000, the American College of Cardiology (ACC) and the European Society of Cardiology (ESC) jointly produced a recommendation for a new definition of myocardial infarction. This proposal based the diagnosis primarily on the elevation of biomarkers specific to cardiac tissue, troponin T and troponin I. Since that time, as use of these blood tests has escalated, it is apparent that elevations in these biomarkers do not always translate into thrombotic coronary artery occlusion. Instead, we have seen that they are positive in a variety of clinical settings. These include sepsis, renal failure, pulmonary embolism, and atrial fibrillation. This investigation attempts to characterize the differences among patients presenting with acute coronary syndrome (ACS) and nonthrombotic troponin elevation (NTTE), to report on outcomes for each, and to note the positive predictive values (PPV) for elevated troponins across clinical settings.

Two hospitals in Israel collected data on all adult patients who experienced an elevation in troponin T (defined as at least 0.1 ng/mL) at any time during their hospital stay. Six hundred and fifteen patients were evaluated by age, sex, cardiovascular risk factors, history of ischemic heart disease, left ventricular function (LVF) by echocardiogram, serum creatine phosphokinase (CPK), and creatinine levels, as well as by which hospital service each had been admitted under. The highest troponin T value was used in the analysis, along with the creatinine level taken on the same day. Two physicians, one a specialist in internal medicine and the other a specialist in cardiology, independently determined the principal diagnosis in accordance with the ACC/ESC guidelines for thrombotic ACS and used other diagnostic studies for alternative diagnosis for conditions known to cause NTTE.

Patients were followed up for causes of mortality for up to two-and-a-half years. Kappa (k) was calculated for physician agreement regarding the principal diagnosis. To assess independent odds ratios and their 95% confidence intervals (CIs) of predictor variables for ACS, an unconditional multiple logistic regression analysis was used. The PPV for troponin T in the diagnosis of ACS was calculated. In-house mortality rates were measured. Long-term risk of death was assessed using Cox proportional hazard models.

The diagnosis of ACS was made in only 53% (326) of the patients. Forty-one percent (254) had NTTE, and the diagnosis was not determined in 6% (35). The diagnoses comprising NTTE included—in order from most to least common—cardiac non-ischemic conditions, sepsis, pulmonary diseases, and neurologic diseases. Using the multivariate analysis, the diagnostic predictors for ACS were history of hypertension or ischemic heart disease, age between 40 and 70 years, higher troponin levels (greater than 1.0 ng/mL), and normal renal function. Extreme age and admission to a surgical team were negative predictors for ACS. Gender, presence of diabetes, and LVF did not appear to make a difference.

The PPV of an elevated troponin T for ACS among all patients was only 56% (95% CI, 52%-60%). It became lower (27%) in those older than 70 with abnormal renal function and higher (90%) in those with a troponin T greater than 1.0 ng/mL and normal renal function. In-house mortality for all patients was 8%; for those with ACS, it was 3%, while for those with NTTE, it was—at 21%—almost eight times higher than the ACS group (P<0.001). Patients were followed up for mortality for a median of 22 months. The long-term mortality was also significantly better (P<0.001) for those with a diagnosis of ACS than for those with NTTE.

 

 

Since the incorporation of the ACC/ESC guidelines, the diagnosis of ACS has substantially increased. It is critical to distinguish between ACS and NTTE when using these very sensitive biomarkers, because the underlying cause of NTTE usually requires a drastically different therapy than that of ACS; in addition, misdiagnosing a myocardial infarction may lead to potentially harmful diagnostic studies and therapies in the form of coronary angiography, antithrombotics, and antiplatelet agents. Hospitalists should look for ACS when troponin T levels exceed 1.0 ng/mL in the face of normal renal function. Based on their data, the authors present an algorithm for working up ACS and NTTE that takes into consideration the clinical presentation, age, renal function, electrocardiographic changes, and troponin T levels. Though this is a retrospective trial, it provides guidance for a very common clinical scenario. We should be concerned about a patient’s prognosis when we encounter an elevated troponin in a setting of NTTE.

Though recent literature suggests that antibiotic therapy during exacerbations reduces morbidity and mortality and reduces the lack of response to treatment, controversy remains as to whether or not this is applicable to all patients with this condition.

Guiding Antibiotic Therapy for COPD Exacerbations

Stolz D, Christ-Crain M, Bingisser R, et al. Antibiotic treatment of exacerbations of COPD: a randomized, controlled trial comparing procalcitonin-guidance with standard therapy. Chest. 2007 Jan;131(1):9-19.

Chronic obstructive pulmonary disease (COPD) is a leading cause of morbidity and mortality in the United States. Exacerbations of COPD (ECOPD) that require hospitalization are both common and costly. Though recent literature suggests that antibiotic therapy during exacerbations reduces morbidity and mortality and lowers the lack of response to treatment, controversy persists concerning whether or not these results are applicable to all patients with this condition. Procalcitonin is a protein not typically measurable in plasma. Levels of this protein rise with bacterial infections, but appear to be unaffected by inflammation from other etiologies such as autoimmune processes or viral infections. Measuring procalcitonin levels has already been shown to safely decrease the use of antibiotics in lower respiratory infections.

This single-center trial from Switzerland evaluated consecutive patients admitted from the emergency department with ECOPD. For 226 enrolled patients, symptoms were quantified, sputum was collected, spirometry was measured, and procalcitonin levels were evaluated. Attending physicians chose antibiotics, using current guidelines, for patients randomized to the standard therapy group. In the group randomized to procalcitonin guidance, antibiotics were given according to serum levels. No antibiotics were administered for levels below 0.1 micrograms (mcg)/L; antibiotics were encouraged for levels greater than 0.25 mcg/L. For levels between 0.1 and .25 mcg/L, antibiotics were encouraged or discouraged based on the clinical condition of the patient. The primary outcomes evaluated were total antibiotics used during hospitalization and up to six months following hospitalization. Secondary endpoints included clinical and laboratory data and six-month follow-up for exacerbation rate and time to the next ECOPD.

Procalcitonin guidance significantly decreased antibiotic administration compared with the standard-therapy arm (40% versus 72% respectively; P<0.0001) and antibiotic exposure (RR, 0.56; 95% CI, 0.43 to 0.73; P<0.0001). The absolute risk reduction was 31.5% (95% CI, 18.7 to 44.3%; p<0.0001). No difference in the mean time to the next exacerbation was noticed between the two groups. Clinical and laboratory measures at baseline and through the six-month follow-up demonstrated no significant differences.

Using procalcitonin levels to guide antibiotic therapy for ECOPD is a practice that is exciting and full of promise. Not only could costs be cut by omitting antibiotics for this treatment regimen in select patients, but some pressure will be relieved in terms of decreasing emerging bacterial resistance. Because procalcitonin levels have a lab turn-around time of approximately one hour, this test becomes even more attractive: decisions for treatment can be made while patients are still in the emergency department. On a cautionary note, there is more than one method of testing for procalcitonin levels, and this trial was done at only one center. Before widespread use of this test is applied, these results should be validated in a multicenter trial. In addition, one test should be used consistently for measuring procalcitonin levels.

 

 

Given the data presented, there is currently no way to consistently distinguish between CA-MRSA and CA-MSSA prior to culture results.

Community-Associated MRSA and MSSA: Clinical and Epidemiologic Characteristics

Miller LG, Perdreau-Remington F, Bayer AS, et al. Clinical and epidemiologic characteristics cannot distinguish community-associated methicillin-resistant Staphylococcus aureus infection from methicillin-susceptible S. aureus infection: a prospective investigation. Clin Infect Dis. 2007 Feb 15;44(4):471-482. Epub 2007 Jan 19.

Methicillin-susceptible Staphylococcus aureus (MSSA) was, until very recently, the predominant strain seen in community-associated (CA) S. aureus infections. Now methicillin-resistant S aureus (MRSA) is a concern around the world. Deciding whether or not to treat empirically for MRSA in those patients who do not have risk factors for healthcare-associated (HCA) infections is difficult.

Investigators at the University of California-Los Angeles Medical Center (Torrance) prospectively evaluated consecutive patients admitted to the county hospital with S. aureus infections. Daily cultures of wounds, urine, blood, and sputum were taken. An extensive questionnaire was completed by 280 patients who provided information on exposures, demographic characteristics, and clinical characteristics. CA infections were defined as those not having a positive culture from a surgical site in a patient who, in the past year, had not lived in an extended living facility, had any indwelling devices, visited an infusion center, or received dialysis.

Of those evaluated, 202 patients (78%) had CA S. aureus and 78 (28%) had HCA S. aureus. Of those with the CA infections, 108 (60%) had MRSA and 72 (40%) had MSSA. Sensitivity, specificity, predictive values, and likelihood ratios for the risk factors evaluated were unable to distinguish CA-MRSA from CA-MSSA. For example, the sensitivities for most MRSA risk factors were less than 30%, and all the positive likelihood ratios were lower than three.

This study has very important consequences. Given the data presented, there is currently no way to consistently distinguish between CA-MRSA and CA-MSSA prior to culture results. It would be very reasonable in this population to treat for MRSA empirically. One limitation is that the information comes from a single center in an area that has a very diverse patient population. Also, because this was done at a county hospital, the resources for treating patients who would be cared for in the outpatient arena at other centers might not otherwise be available, thus generalizing this data to potential outpatients. Because the morbidity and mortality from a delay in treatment of MRSA infections is significant, however, it appears sensible to treat CA S. aureus empirically in areas where CA-MRSA is common, regardless of patients’ risk factors.

Venous Thromboembolism Update

King CS, Holley AB, Jackson JL, et al. Twice vs three times daily heparin dosing for thromboembolism prophylaxis in the general medical population: a metaanalysis. Chest. 2007 Feb;131(2):507-516.

Nijkeuter M, Sohne M, Tick LW, et al. The natural course of hemodynamically stable pulmonary embolism: clinical outcome and risk factors in a large prospective cohort study. Chest. 2007 Feb;131(2):517-523.

Segal JB, Streiff MB, Hoffman LV, et al. Management of venous thromboembolism: a systematic review for a practice guideline. Ann Intern Med. 2007 Feb 6;146(3):211-222.

Snow V, Qaseem A, Barry P, et al. Management of venous thromboembolism: a clinical practice guideline from the American College of Physicians and the American Academy of Family Physicians. Ann Intern Med. 2007 Feb 6;146 (3):204-210. Epub 2007 Jan 29.

The prevention and treatment of venous thromboembolism (VTE) is a skill set required for all hospitalists given the prevalence of this condition in hospitalized patients as well as the significant morbidity and mortality associated with the condition. Several articles that help to guide our decisions in managing VTE have been published recently.

 

 

We have no randomized controlled trials (RCT) comparing twice-daily (bid) with three-times-daily (tid) dosing of unfractionated heparin (UFH) for the prevention of VTE in medically ill patient populations. It is unlikely that such a study, involving an adequate number of patients, will ever be conducted. Though low molecular weight heparins (LMWH) are used more frequently for VTE prevention, many hospitalists still use UFH to prevent VTE in patients who are morbidly obese or who have profound renal insufficiency. King and colleagues have done a meta-analysis to find out whether or not tid dosing is superior to bid dosing for VTE prevention. Twelve studies, including almost 8,000 patients from 1966 to 2004, were reviewed. All patients were hospitalized for medical rather than surgical conditions.

Tid heparin significantly decreased the incidence of the combined outcome of pulmonary embolism (PE) and proximal deep vein thrombosis (DVT). There was a trend toward significance in decreasing the incidence of PE. There was a significant increase in the number of major bleeds with tid dosing compared with bid dosing. There are many limitations to this study: It is retrospective, the population is extremely heterogeneous, and varying methods have been employed to diagnosis VTE across the many studies from which data were pooled. This is likely the best data we will have for UFH in VTE prevention, however. In summary, tid dosing is preferred for high-risk patients, but bid dosing should be considered for those at risk for bleeding complications.

Data are limited for the clinical course of PE. Outpatient treatment of PE with LMWH is not uncommon in select patients, but choosing who is safe to treat in this arena is uncertain. Nijkeuter and colleagues assessed the incidence of recurrent VTE, hemorrhagic complications from therapy, mortality, risk factors for recurrence, and the course of these events from the time of diagnosis through a three-month follow-up period.

Six hundred and seventy-three patients completed the three-month follow-up. Twenty of them (3%) had recurrent VTE; 14 of these had recurrent PE. Recurrence predominantly transpired in the first three weeks of therapy. Of those with recurrent PE, 11 (79%) were fatal, and most of these occurred within the first week of diagnosis. Major bleeding occurred in 1.5% of the patients. Immobilization for more than three days was a significant risk factor for recurrence. Inpatient status, a diagnosis of COPD, and malignancy were independent risk factors for bleeding complications. Fifty-five patients (8.2%) died over the three-month period. Twenty percent died of fatal recurrent PE, while 4% suffered fatal hemorrhage.

Multivariate analysis revealed four characteristics as independent risk factors for mortality in patients with PE. These include age, inpatient status, immobilization for more than three days, and malignancy. It appears that the majority of recurrent and fatal PE occurs during the first week of therapy. Physicians should not discharge patients to home with LMWH for PE without considering these risk factors for hemorrhage, recurrence, and mortality.

Annals of Internal Medicine has published a systematic review of management issues in VTE to provide the framework for the American College of Physicians practice guidelines. These guidelines pool data from more than 100 randomized controlled trials and comment on six areas in VTE management. The following are quotes from this document.

Recommendation #1: Use low molecular-weight heparin (LMWH) rather than unfractionated heparin whenever possible for the initial inpatient treatment of deep vein thrombosis (DVT). Either unfractionated heparin or LMWH is appropriate for the initial treatment of pulmonary embolism.

Recommendation #2: Outpatient treatment of DVT, and possibly pulmonary embolism, with LMWH is safe and cost-effective for carefully selected patients and should be considered if the required support services are in place.

 

 

Recommendation #3: Compression stockings should be used routinely to prevent post-thrombotic syndrome, beginning within one month of diagnosis of proximal DVT and continuing for a minimum of one year after diagnosis.

Recommendation #4: There is insufficient evidence to make specific recommendations for types of anticoagulation management of VTE in pregnant women.

Recommendation #5: Anticoagulation should be maintained for three to six months for VTE secondary to transient risk factors and for more than 12 months for recurrent VTE. While the appropriate duration of anticoagulation for idiopathic or recurrent VTE is not definitively known, there is evidence of substantial benefit for extended-duration therapy.

Recommendation #6: LMWH is safe and efficacious for the long-term treatment of VTE in selected patients (and may be preferable for patients with cancer).

All of these seem reasonable and appropriate with a possible exception in the second recommendation. Using LMWH to treat patients diagnosed with PE in the outpatient setting is not well supported by data. The vast majority of trials involving the treatment of VTE with LMWH have been conducted on those with DVT; the number of patients in the trials with PE has been very small. The Food and Drug Administration has not approved LMWH for outpatient treatment of PE; LMWH is FDA approved in the outpatient setting only for the treatment of DVT. We know that the hemodynamic changes that can accompany PE may not occur for at least 24 hours. In addition, we now have data from the Nijkeuter study that point to dangers that may result from treating PE outside the hospital setting. At this time, we should treat PE with LMWH in the outpatient setting only with patients whose risk factors, clinical characteristics, and outpatient resources have been carefully scrutinized. TH

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Treatment of Bacterial Meningitis with Vancomycin

Ricard JD, Wolff M, Lacherade JC, et al. Levels of vancomycin in cerebrospinal fluid of adult patients receiving adjunctive corticosteroids to treat pneumococcal meningitis: a prospective multicenter observational study. Clin Infect Dis. 2007 Jan 15;44(2):250-255. Epub 2006 Dec 15.

In 2002, van de Beek and de Gans published a study demonstrating that adjuvant dexamethasone decreased mortality and improved neurological disability when given to patients with bacterial meningitis. Their results changed our treatment paradigm for this disease but left us with several questions. At what point in the treatment course does giving corticosteroids become ineffective? Do their results apply to all bacterial pathogens? Can the results be applied to the use of vancomycin in treating penicillin-resistant strains of Streptococcus pneumoniae? This final question arises from the disturbing ability of vancomycin to penetrate the cerebrospinal fluid (CSF). Previous data support this concern; thus, bactericidal titers may be inadequate within the CSF. Because meningeal inflammation exerts a strong influence over whether or not vancomycin enters the CSF, administering steroids may decrease its ability to do so. This study brings some clarity to the issue.

In this observational open multicenter trial from France, 14 adults were admitted to intensive care units with suspected pneumococcal meningitis. They were treated with intravenous cefotaxime, vancomycin, and dexamethasone. The vancomycin was given as a loading dose of 15 mg per kg of body weight followed by administration of a continuous infusion of 60 mg per kg of body weight per day. The diagnosis of pneumococcal meningitis was made using a CSF pleocytosis as well as one or more of the following: a positive culture from either the blood or CSF, a Gram stain showing Gram-positive diplococci, or pneumococcal antigens in the CSF as demonstrated by latex agglutination. Patients had a second lumbar puncture on either day two or three to measure vancomycin levels—among other markers of disease activity—in the CSF. Serum levels of vancomycin were drawn simultaneously.

Thirteen of the 14 patients had pneumococcal meningitis; one patient was found to have meningitis from Neisseria meningitidis. Seven patients had pneumococcal strains resistant to penicillin. Ten of the 14 patients required mechanical intubation. The second lumbar puncture demonstrated marked improvements in leukocyte counts, protein levels, and glucose levels. All subsequent cultures from the CSF were negative. Three patients died, two had neurological sequelae, and the remainder were discharged from the hospital without complications. Vancomycin concentrations in the serum ranged from 14.2 to 39.0 mg/L, with a mean of 25.2 mg/L; concentrations in the CSF ranged from 3.1 to 22.3 mg/L, with a mean of 7.9 mg/L. There was a significant correlation between vancomycin levels in the serum and those in the CSF (r = 0.68; P = 0.01). The concentration of vancomycin in the CSF was between four and 10 times the mean inhibitory concentrations (MICs). A linear correlation exists between penetration of vancomycin into CSF and serum levels. No evidence of drug toxicities was observed.

The results demonstrate that a therapeutic concentration of vancomycin can be achieved in the CSF. The continuous infusion of vancomycin with a loading dose, which has not been standard practice, has previously been shown to achieve targeted serum levels more quickly than intermittent dosing. Levels of serum vancomycin were likely higher in this study than when troughs of 15-20 mg/L are the goal. This data strongly suggests, however, that this same treatment regimen can obtain adequate vancomycin levels in the CSF while treating pneumococcal meningitis with adjunctive steroids.

Though this is a retrospective trial, it provides guidance for a very common clinical scenario.
 

 

Nonspecific elevations in troponins

Alcalai R, Planer D, Culhaoqlu A, et al. Acute coronary syndrome vs nonspecific troponin elevation: clinical predictors and survival analysis. Arch Intern Med. 2007 Feb 12;167(3):276-281.

In 2000, the American College of Cardiology (ACC) and the European Society of Cardiology (ESC) jointly produced a recommendation for a new definition of myocardial infarction. This proposal based the diagnosis primarily on the elevation of biomarkers specific to cardiac tissue, troponin T and troponin I. Since that time, as use of these blood tests has escalated, it is apparent that elevations in these biomarkers do not always translate into thrombotic coronary artery occlusion. Instead, we have seen that they are positive in a variety of clinical settings. These include sepsis, renal failure, pulmonary embolism, and atrial fibrillation. This investigation attempts to characterize the differences among patients presenting with acute coronary syndrome (ACS) and nonthrombotic troponin elevation (NTTE), to report on outcomes for each, and to note the positive predictive values (PPV) for elevated troponins across clinical settings.

Two hospitals in Israel collected data on all adult patients who experienced an elevation in troponin T (defined as at least 0.1 ng/mL) at any time during their hospital stay. Six hundred and fifteen patients were evaluated by age, sex, cardiovascular risk factors, history of ischemic heart disease, left ventricular function (LVF) by echocardiogram, serum creatine phosphokinase (CPK), and creatinine levels, as well as by which hospital service each had been admitted under. The highest troponin T value was used in the analysis, along with the creatinine level taken on the same day. Two physicians, one a specialist in internal medicine and the other a specialist in cardiology, independently determined the principal diagnosis in accordance with the ACC/ESC guidelines for thrombotic ACS and used other diagnostic studies for alternative diagnosis for conditions known to cause NTTE.

Patients were followed up for causes of mortality for up to two-and-a-half years. Kappa (k) was calculated for physician agreement regarding the principal diagnosis. To assess independent odds ratios and their 95% confidence intervals (CIs) of predictor variables for ACS, an unconditional multiple logistic regression analysis was used. The PPV for troponin T in the diagnosis of ACS was calculated. In-house mortality rates were measured. Long-term risk of death was assessed using Cox proportional hazard models.

The diagnosis of ACS was made in only 53% (326) of the patients. Forty-one percent (254) had NTTE, and the diagnosis was not determined in 6% (35). The diagnoses comprising NTTE included—in order from most to least common—cardiac non-ischemic conditions, sepsis, pulmonary diseases, and neurologic diseases. Using the multivariate analysis, the diagnostic predictors for ACS were history of hypertension or ischemic heart disease, age between 40 and 70 years, higher troponin levels (greater than 1.0 ng/mL), and normal renal function. Extreme age and admission to a surgical team were negative predictors for ACS. Gender, presence of diabetes, and LVF did not appear to make a difference.

The PPV of an elevated troponin T for ACS among all patients was only 56% (95% CI, 52%-60%). It became lower (27%) in those older than 70 with abnormal renal function and higher (90%) in those with a troponin T greater than 1.0 ng/mL and normal renal function. In-house mortality for all patients was 8%; for those with ACS, it was 3%, while for those with NTTE, it was—at 21%—almost eight times higher than the ACS group (P<0.001). Patients were followed up for mortality for a median of 22 months. The long-term mortality was also significantly better (P<0.001) for those with a diagnosis of ACS than for those with NTTE.

 

 

Since the incorporation of the ACC/ESC guidelines, the diagnosis of ACS has substantially increased. It is critical to distinguish between ACS and NTTE when using these very sensitive biomarkers, because the underlying cause of NTTE usually requires a drastically different therapy than that of ACS; in addition, misdiagnosing a myocardial infarction may lead to potentially harmful diagnostic studies and therapies in the form of coronary angiography, antithrombotics, and antiplatelet agents. Hospitalists should look for ACS when troponin T levels exceed 1.0 ng/mL in the face of normal renal function. Based on their data, the authors present an algorithm for working up ACS and NTTE that takes into consideration the clinical presentation, age, renal function, electrocardiographic changes, and troponin T levels. Though this is a retrospective trial, it provides guidance for a very common clinical scenario. We should be concerned about a patient’s prognosis when we encounter an elevated troponin in a setting of NTTE.

Though recent literature suggests that antibiotic therapy during exacerbations reduces morbidity and mortality and reduces the lack of response to treatment, controversy remains as to whether or not this is applicable to all patients with this condition.

Guiding Antibiotic Therapy for COPD Exacerbations

Stolz D, Christ-Crain M, Bingisser R, et al. Antibiotic treatment of exacerbations of COPD: a randomized, controlled trial comparing procalcitonin-guidance with standard therapy. Chest. 2007 Jan;131(1):9-19.

Chronic obstructive pulmonary disease (COPD) is a leading cause of morbidity and mortality in the United States. Exacerbations of COPD (ECOPD) that require hospitalization are both common and costly. Though recent literature suggests that antibiotic therapy during exacerbations reduces morbidity and mortality and lowers the lack of response to treatment, controversy persists concerning whether or not these results are applicable to all patients with this condition. Procalcitonin is a protein not typically measurable in plasma. Levels of this protein rise with bacterial infections, but appear to be unaffected by inflammation from other etiologies such as autoimmune processes or viral infections. Measuring procalcitonin levels has already been shown to safely decrease the use of antibiotics in lower respiratory infections.

This single-center trial from Switzerland evaluated consecutive patients admitted from the emergency department with ECOPD. For 226 enrolled patients, symptoms were quantified, sputum was collected, spirometry was measured, and procalcitonin levels were evaluated. Attending physicians chose antibiotics, using current guidelines, for patients randomized to the standard therapy group. In the group randomized to procalcitonin guidance, antibiotics were given according to serum levels. No antibiotics were administered for levels below 0.1 micrograms (mcg)/L; antibiotics were encouraged for levels greater than 0.25 mcg/L. For levels between 0.1 and .25 mcg/L, antibiotics were encouraged or discouraged based on the clinical condition of the patient. The primary outcomes evaluated were total antibiotics used during hospitalization and up to six months following hospitalization. Secondary endpoints included clinical and laboratory data and six-month follow-up for exacerbation rate and time to the next ECOPD.

Procalcitonin guidance significantly decreased antibiotic administration compared with the standard-therapy arm (40% versus 72% respectively; P<0.0001) and antibiotic exposure (RR, 0.56; 95% CI, 0.43 to 0.73; P<0.0001). The absolute risk reduction was 31.5% (95% CI, 18.7 to 44.3%; p<0.0001). No difference in the mean time to the next exacerbation was noticed between the two groups. Clinical and laboratory measures at baseline and through the six-month follow-up demonstrated no significant differences.

Using procalcitonin levels to guide antibiotic therapy for ECOPD is a practice that is exciting and full of promise. Not only could costs be cut by omitting antibiotics for this treatment regimen in select patients, but some pressure will be relieved in terms of decreasing emerging bacterial resistance. Because procalcitonin levels have a lab turn-around time of approximately one hour, this test becomes even more attractive: decisions for treatment can be made while patients are still in the emergency department. On a cautionary note, there is more than one method of testing for procalcitonin levels, and this trial was done at only one center. Before widespread use of this test is applied, these results should be validated in a multicenter trial. In addition, one test should be used consistently for measuring procalcitonin levels.

 

 

Given the data presented, there is currently no way to consistently distinguish between CA-MRSA and CA-MSSA prior to culture results.

Community-Associated MRSA and MSSA: Clinical and Epidemiologic Characteristics

Miller LG, Perdreau-Remington F, Bayer AS, et al. Clinical and epidemiologic characteristics cannot distinguish community-associated methicillin-resistant Staphylococcus aureus infection from methicillin-susceptible S. aureus infection: a prospective investigation. Clin Infect Dis. 2007 Feb 15;44(4):471-482. Epub 2007 Jan 19.

Methicillin-susceptible Staphylococcus aureus (MSSA) was, until very recently, the predominant strain seen in community-associated (CA) S. aureus infections. Now methicillin-resistant S aureus (MRSA) is a concern around the world. Deciding whether or not to treat empirically for MRSA in those patients who do not have risk factors for healthcare-associated (HCA) infections is difficult.

Investigators at the University of California-Los Angeles Medical Center (Torrance) prospectively evaluated consecutive patients admitted to the county hospital with S. aureus infections. Daily cultures of wounds, urine, blood, and sputum were taken. An extensive questionnaire was completed by 280 patients who provided information on exposures, demographic characteristics, and clinical characteristics. CA infections were defined as those not having a positive culture from a surgical site in a patient who, in the past year, had not lived in an extended living facility, had any indwelling devices, visited an infusion center, or received dialysis.

Of those evaluated, 202 patients (78%) had CA S. aureus and 78 (28%) had HCA S. aureus. Of those with the CA infections, 108 (60%) had MRSA and 72 (40%) had MSSA. Sensitivity, specificity, predictive values, and likelihood ratios for the risk factors evaluated were unable to distinguish CA-MRSA from CA-MSSA. For example, the sensitivities for most MRSA risk factors were less than 30%, and all the positive likelihood ratios were lower than three.

This study has very important consequences. Given the data presented, there is currently no way to consistently distinguish between CA-MRSA and CA-MSSA prior to culture results. It would be very reasonable in this population to treat for MRSA empirically. One limitation is that the information comes from a single center in an area that has a very diverse patient population. Also, because this was done at a county hospital, the resources for treating patients who would be cared for in the outpatient arena at other centers might not otherwise be available, thus generalizing this data to potential outpatients. Because the morbidity and mortality from a delay in treatment of MRSA infections is significant, however, it appears sensible to treat CA S. aureus empirically in areas where CA-MRSA is common, regardless of patients’ risk factors.

Venous Thromboembolism Update

King CS, Holley AB, Jackson JL, et al. Twice vs three times daily heparin dosing for thromboembolism prophylaxis in the general medical population: a metaanalysis. Chest. 2007 Feb;131(2):507-516.

Nijkeuter M, Sohne M, Tick LW, et al. The natural course of hemodynamically stable pulmonary embolism: clinical outcome and risk factors in a large prospective cohort study. Chest. 2007 Feb;131(2):517-523.

Segal JB, Streiff MB, Hoffman LV, et al. Management of venous thromboembolism: a systematic review for a practice guideline. Ann Intern Med. 2007 Feb 6;146(3):211-222.

Snow V, Qaseem A, Barry P, et al. Management of venous thromboembolism: a clinical practice guideline from the American College of Physicians and the American Academy of Family Physicians. Ann Intern Med. 2007 Feb 6;146 (3):204-210. Epub 2007 Jan 29.

The prevention and treatment of venous thromboembolism (VTE) is a skill set required for all hospitalists given the prevalence of this condition in hospitalized patients as well as the significant morbidity and mortality associated with the condition. Several articles that help to guide our decisions in managing VTE have been published recently.

 

 

We have no randomized controlled trials (RCT) comparing twice-daily (bid) with three-times-daily (tid) dosing of unfractionated heparin (UFH) for the prevention of VTE in medically ill patient populations. It is unlikely that such a study, involving an adequate number of patients, will ever be conducted. Though low molecular weight heparins (LMWH) are used more frequently for VTE prevention, many hospitalists still use UFH to prevent VTE in patients who are morbidly obese or who have profound renal insufficiency. King and colleagues have done a meta-analysis to find out whether or not tid dosing is superior to bid dosing for VTE prevention. Twelve studies, including almost 8,000 patients from 1966 to 2004, were reviewed. All patients were hospitalized for medical rather than surgical conditions.

Tid heparin significantly decreased the incidence of the combined outcome of pulmonary embolism (PE) and proximal deep vein thrombosis (DVT). There was a trend toward significance in decreasing the incidence of PE. There was a significant increase in the number of major bleeds with tid dosing compared with bid dosing. There are many limitations to this study: It is retrospective, the population is extremely heterogeneous, and varying methods have been employed to diagnosis VTE across the many studies from which data were pooled. This is likely the best data we will have for UFH in VTE prevention, however. In summary, tid dosing is preferred for high-risk patients, but bid dosing should be considered for those at risk for bleeding complications.

Data are limited for the clinical course of PE. Outpatient treatment of PE with LMWH is not uncommon in select patients, but choosing who is safe to treat in this arena is uncertain. Nijkeuter and colleagues assessed the incidence of recurrent VTE, hemorrhagic complications from therapy, mortality, risk factors for recurrence, and the course of these events from the time of diagnosis through a three-month follow-up period.

Six hundred and seventy-three patients completed the three-month follow-up. Twenty of them (3%) had recurrent VTE; 14 of these had recurrent PE. Recurrence predominantly transpired in the first three weeks of therapy. Of those with recurrent PE, 11 (79%) were fatal, and most of these occurred within the first week of diagnosis. Major bleeding occurred in 1.5% of the patients. Immobilization for more than three days was a significant risk factor for recurrence. Inpatient status, a diagnosis of COPD, and malignancy were independent risk factors for bleeding complications. Fifty-five patients (8.2%) died over the three-month period. Twenty percent died of fatal recurrent PE, while 4% suffered fatal hemorrhage.

Multivariate analysis revealed four characteristics as independent risk factors for mortality in patients with PE. These include age, inpatient status, immobilization for more than three days, and malignancy. It appears that the majority of recurrent and fatal PE occurs during the first week of therapy. Physicians should not discharge patients to home with LMWH for PE without considering these risk factors for hemorrhage, recurrence, and mortality.

Annals of Internal Medicine has published a systematic review of management issues in VTE to provide the framework for the American College of Physicians practice guidelines. These guidelines pool data from more than 100 randomized controlled trials and comment on six areas in VTE management. The following are quotes from this document.

Recommendation #1: Use low molecular-weight heparin (LMWH) rather than unfractionated heparin whenever possible for the initial inpatient treatment of deep vein thrombosis (DVT). Either unfractionated heparin or LMWH is appropriate for the initial treatment of pulmonary embolism.

Recommendation #2: Outpatient treatment of DVT, and possibly pulmonary embolism, with LMWH is safe and cost-effective for carefully selected patients and should be considered if the required support services are in place.

 

 

Recommendation #3: Compression stockings should be used routinely to prevent post-thrombotic syndrome, beginning within one month of diagnosis of proximal DVT and continuing for a minimum of one year after diagnosis.

Recommendation #4: There is insufficient evidence to make specific recommendations for types of anticoagulation management of VTE in pregnant women.

Recommendation #5: Anticoagulation should be maintained for three to six months for VTE secondary to transient risk factors and for more than 12 months for recurrent VTE. While the appropriate duration of anticoagulation for idiopathic or recurrent VTE is not definitively known, there is evidence of substantial benefit for extended-duration therapy.

Recommendation #6: LMWH is safe and efficacious for the long-term treatment of VTE in selected patients (and may be preferable for patients with cancer).

All of these seem reasonable and appropriate with a possible exception in the second recommendation. Using LMWH to treat patients diagnosed with PE in the outpatient setting is not well supported by data. The vast majority of trials involving the treatment of VTE with LMWH have been conducted on those with DVT; the number of patients in the trials with PE has been very small. The Food and Drug Administration has not approved LMWH for outpatient treatment of PE; LMWH is FDA approved in the outpatient setting only for the treatment of DVT. We know that the hemodynamic changes that can accompany PE may not occur for at least 24 hours. In addition, we now have data from the Nijkeuter study that point to dangers that may result from treating PE outside the hospital setting. At this time, we should treat PE with LMWH in the outpatient setting only with patients whose risk factors, clinical characteristics, and outpatient resources have been carefully scrutinized. TH

Treatment of Bacterial Meningitis with Vancomycin

Ricard JD, Wolff M, Lacherade JC, et al. Levels of vancomycin in cerebrospinal fluid of adult patients receiving adjunctive corticosteroids to treat pneumococcal meningitis: a prospective multicenter observational study. Clin Infect Dis. 2007 Jan 15;44(2):250-255. Epub 2006 Dec 15.

In 2002, van de Beek and de Gans published a study demonstrating that adjuvant dexamethasone decreased mortality and improved neurological disability when given to patients with bacterial meningitis. Their results changed our treatment paradigm for this disease but left us with several questions. At what point in the treatment course does giving corticosteroids become ineffective? Do their results apply to all bacterial pathogens? Can the results be applied to the use of vancomycin in treating penicillin-resistant strains of Streptococcus pneumoniae? This final question arises from the disturbing ability of vancomycin to penetrate the cerebrospinal fluid (CSF). Previous data support this concern; thus, bactericidal titers may be inadequate within the CSF. Because meningeal inflammation exerts a strong influence over whether or not vancomycin enters the CSF, administering steroids may decrease its ability to do so. This study brings some clarity to the issue.

In this observational open multicenter trial from France, 14 adults were admitted to intensive care units with suspected pneumococcal meningitis. They were treated with intravenous cefotaxime, vancomycin, and dexamethasone. The vancomycin was given as a loading dose of 15 mg per kg of body weight followed by administration of a continuous infusion of 60 mg per kg of body weight per day. The diagnosis of pneumococcal meningitis was made using a CSF pleocytosis as well as one or more of the following: a positive culture from either the blood or CSF, a Gram stain showing Gram-positive diplococci, or pneumococcal antigens in the CSF as demonstrated by latex agglutination. Patients had a second lumbar puncture on either day two or three to measure vancomycin levels—among other markers of disease activity—in the CSF. Serum levels of vancomycin were drawn simultaneously.

Thirteen of the 14 patients had pneumococcal meningitis; one patient was found to have meningitis from Neisseria meningitidis. Seven patients had pneumococcal strains resistant to penicillin. Ten of the 14 patients required mechanical intubation. The second lumbar puncture demonstrated marked improvements in leukocyte counts, protein levels, and glucose levels. All subsequent cultures from the CSF were negative. Three patients died, two had neurological sequelae, and the remainder were discharged from the hospital without complications. Vancomycin concentrations in the serum ranged from 14.2 to 39.0 mg/L, with a mean of 25.2 mg/L; concentrations in the CSF ranged from 3.1 to 22.3 mg/L, with a mean of 7.9 mg/L. There was a significant correlation between vancomycin levels in the serum and those in the CSF (r = 0.68; P = 0.01). The concentration of vancomycin in the CSF was between four and 10 times the mean inhibitory concentrations (MICs). A linear correlation exists between penetration of vancomycin into CSF and serum levels. No evidence of drug toxicities was observed.

The results demonstrate that a therapeutic concentration of vancomycin can be achieved in the CSF. The continuous infusion of vancomycin with a loading dose, which has not been standard practice, has previously been shown to achieve targeted serum levels more quickly than intermittent dosing. Levels of serum vancomycin were likely higher in this study than when troughs of 15-20 mg/L are the goal. This data strongly suggests, however, that this same treatment regimen can obtain adequate vancomycin levels in the CSF while treating pneumococcal meningitis with adjunctive steroids.

Though this is a retrospective trial, it provides guidance for a very common clinical scenario.
 

 

Nonspecific elevations in troponins

Alcalai R, Planer D, Culhaoqlu A, et al. Acute coronary syndrome vs nonspecific troponin elevation: clinical predictors and survival analysis. Arch Intern Med. 2007 Feb 12;167(3):276-281.

In 2000, the American College of Cardiology (ACC) and the European Society of Cardiology (ESC) jointly produced a recommendation for a new definition of myocardial infarction. This proposal based the diagnosis primarily on the elevation of biomarkers specific to cardiac tissue, troponin T and troponin I. Since that time, as use of these blood tests has escalated, it is apparent that elevations in these biomarkers do not always translate into thrombotic coronary artery occlusion. Instead, we have seen that they are positive in a variety of clinical settings. These include sepsis, renal failure, pulmonary embolism, and atrial fibrillation. This investigation attempts to characterize the differences among patients presenting with acute coronary syndrome (ACS) and nonthrombotic troponin elevation (NTTE), to report on outcomes for each, and to note the positive predictive values (PPV) for elevated troponins across clinical settings.

Two hospitals in Israel collected data on all adult patients who experienced an elevation in troponin T (defined as at least 0.1 ng/mL) at any time during their hospital stay. Six hundred and fifteen patients were evaluated by age, sex, cardiovascular risk factors, history of ischemic heart disease, left ventricular function (LVF) by echocardiogram, serum creatine phosphokinase (CPK), and creatinine levels, as well as by which hospital service each had been admitted under. The highest troponin T value was used in the analysis, along with the creatinine level taken on the same day. Two physicians, one a specialist in internal medicine and the other a specialist in cardiology, independently determined the principal diagnosis in accordance with the ACC/ESC guidelines for thrombotic ACS and used other diagnostic studies for alternative diagnosis for conditions known to cause NTTE.

Patients were followed up for causes of mortality for up to two-and-a-half years. Kappa (k) was calculated for physician agreement regarding the principal diagnosis. To assess independent odds ratios and their 95% confidence intervals (CIs) of predictor variables for ACS, an unconditional multiple logistic regression analysis was used. The PPV for troponin T in the diagnosis of ACS was calculated. In-house mortality rates were measured. Long-term risk of death was assessed using Cox proportional hazard models.

The diagnosis of ACS was made in only 53% (326) of the patients. Forty-one percent (254) had NTTE, and the diagnosis was not determined in 6% (35). The diagnoses comprising NTTE included—in order from most to least common—cardiac non-ischemic conditions, sepsis, pulmonary diseases, and neurologic diseases. Using the multivariate analysis, the diagnostic predictors for ACS were history of hypertension or ischemic heart disease, age between 40 and 70 years, higher troponin levels (greater than 1.0 ng/mL), and normal renal function. Extreme age and admission to a surgical team were negative predictors for ACS. Gender, presence of diabetes, and LVF did not appear to make a difference.

The PPV of an elevated troponin T for ACS among all patients was only 56% (95% CI, 52%-60%). It became lower (27%) in those older than 70 with abnormal renal function and higher (90%) in those with a troponin T greater than 1.0 ng/mL and normal renal function. In-house mortality for all patients was 8%; for those with ACS, it was 3%, while for those with NTTE, it was—at 21%—almost eight times higher than the ACS group (P<0.001). Patients were followed up for mortality for a median of 22 months. The long-term mortality was also significantly better (P<0.001) for those with a diagnosis of ACS than for those with NTTE.

 

 

Since the incorporation of the ACC/ESC guidelines, the diagnosis of ACS has substantially increased. It is critical to distinguish between ACS and NTTE when using these very sensitive biomarkers, because the underlying cause of NTTE usually requires a drastically different therapy than that of ACS; in addition, misdiagnosing a myocardial infarction may lead to potentially harmful diagnostic studies and therapies in the form of coronary angiography, antithrombotics, and antiplatelet agents. Hospitalists should look for ACS when troponin T levels exceed 1.0 ng/mL in the face of normal renal function. Based on their data, the authors present an algorithm for working up ACS and NTTE that takes into consideration the clinical presentation, age, renal function, electrocardiographic changes, and troponin T levels. Though this is a retrospective trial, it provides guidance for a very common clinical scenario. We should be concerned about a patient’s prognosis when we encounter an elevated troponin in a setting of NTTE.

Though recent literature suggests that antibiotic therapy during exacerbations reduces morbidity and mortality and reduces the lack of response to treatment, controversy remains as to whether or not this is applicable to all patients with this condition.

Guiding Antibiotic Therapy for COPD Exacerbations

Stolz D, Christ-Crain M, Bingisser R, et al. Antibiotic treatment of exacerbations of COPD: a randomized, controlled trial comparing procalcitonin-guidance with standard therapy. Chest. 2007 Jan;131(1):9-19.

Chronic obstructive pulmonary disease (COPD) is a leading cause of morbidity and mortality in the United States. Exacerbations of COPD (ECOPD) that require hospitalization are both common and costly. Though recent literature suggests that antibiotic therapy during exacerbations reduces morbidity and mortality and lowers the lack of response to treatment, controversy persists concerning whether or not these results are applicable to all patients with this condition. Procalcitonin is a protein not typically measurable in plasma. Levels of this protein rise with bacterial infections, but appear to be unaffected by inflammation from other etiologies such as autoimmune processes or viral infections. Measuring procalcitonin levels has already been shown to safely decrease the use of antibiotics in lower respiratory infections.

This single-center trial from Switzerland evaluated consecutive patients admitted from the emergency department with ECOPD. For 226 enrolled patients, symptoms were quantified, sputum was collected, spirometry was measured, and procalcitonin levels were evaluated. Attending physicians chose antibiotics, using current guidelines, for patients randomized to the standard therapy group. In the group randomized to procalcitonin guidance, antibiotics were given according to serum levels. No antibiotics were administered for levels below 0.1 micrograms (mcg)/L; antibiotics were encouraged for levels greater than 0.25 mcg/L. For levels between 0.1 and .25 mcg/L, antibiotics were encouraged or discouraged based on the clinical condition of the patient. The primary outcomes evaluated were total antibiotics used during hospitalization and up to six months following hospitalization. Secondary endpoints included clinical and laboratory data and six-month follow-up for exacerbation rate and time to the next ECOPD.

Procalcitonin guidance significantly decreased antibiotic administration compared with the standard-therapy arm (40% versus 72% respectively; P<0.0001) and antibiotic exposure (RR, 0.56; 95% CI, 0.43 to 0.73; P<0.0001). The absolute risk reduction was 31.5% (95% CI, 18.7 to 44.3%; p<0.0001). No difference in the mean time to the next exacerbation was noticed between the two groups. Clinical and laboratory measures at baseline and through the six-month follow-up demonstrated no significant differences.

Using procalcitonin levels to guide antibiotic therapy for ECOPD is a practice that is exciting and full of promise. Not only could costs be cut by omitting antibiotics for this treatment regimen in select patients, but some pressure will be relieved in terms of decreasing emerging bacterial resistance. Because procalcitonin levels have a lab turn-around time of approximately one hour, this test becomes even more attractive: decisions for treatment can be made while patients are still in the emergency department. On a cautionary note, there is more than one method of testing for procalcitonin levels, and this trial was done at only one center. Before widespread use of this test is applied, these results should be validated in a multicenter trial. In addition, one test should be used consistently for measuring procalcitonin levels.

 

 

Given the data presented, there is currently no way to consistently distinguish between CA-MRSA and CA-MSSA prior to culture results.

Community-Associated MRSA and MSSA: Clinical and Epidemiologic Characteristics

Miller LG, Perdreau-Remington F, Bayer AS, et al. Clinical and epidemiologic characteristics cannot distinguish community-associated methicillin-resistant Staphylococcus aureus infection from methicillin-susceptible S. aureus infection: a prospective investigation. Clin Infect Dis. 2007 Feb 15;44(4):471-482. Epub 2007 Jan 19.

Methicillin-susceptible Staphylococcus aureus (MSSA) was, until very recently, the predominant strain seen in community-associated (CA) S. aureus infections. Now methicillin-resistant S aureus (MRSA) is a concern around the world. Deciding whether or not to treat empirically for MRSA in those patients who do not have risk factors for healthcare-associated (HCA) infections is difficult.

Investigators at the University of California-Los Angeles Medical Center (Torrance) prospectively evaluated consecutive patients admitted to the county hospital with S. aureus infections. Daily cultures of wounds, urine, blood, and sputum were taken. An extensive questionnaire was completed by 280 patients who provided information on exposures, demographic characteristics, and clinical characteristics. CA infections were defined as those not having a positive culture from a surgical site in a patient who, in the past year, had not lived in an extended living facility, had any indwelling devices, visited an infusion center, or received dialysis.

Of those evaluated, 202 patients (78%) had CA S. aureus and 78 (28%) had HCA S. aureus. Of those with the CA infections, 108 (60%) had MRSA and 72 (40%) had MSSA. Sensitivity, specificity, predictive values, and likelihood ratios for the risk factors evaluated were unable to distinguish CA-MRSA from CA-MSSA. For example, the sensitivities for most MRSA risk factors were less than 30%, and all the positive likelihood ratios were lower than three.

This study has very important consequences. Given the data presented, there is currently no way to consistently distinguish between CA-MRSA and CA-MSSA prior to culture results. It would be very reasonable in this population to treat for MRSA empirically. One limitation is that the information comes from a single center in an area that has a very diverse patient population. Also, because this was done at a county hospital, the resources for treating patients who would be cared for in the outpatient arena at other centers might not otherwise be available, thus generalizing this data to potential outpatients. Because the morbidity and mortality from a delay in treatment of MRSA infections is significant, however, it appears sensible to treat CA S. aureus empirically in areas where CA-MRSA is common, regardless of patients’ risk factors.

Venous Thromboembolism Update

King CS, Holley AB, Jackson JL, et al. Twice vs three times daily heparin dosing for thromboembolism prophylaxis in the general medical population: a metaanalysis. Chest. 2007 Feb;131(2):507-516.

Nijkeuter M, Sohne M, Tick LW, et al. The natural course of hemodynamically stable pulmonary embolism: clinical outcome and risk factors in a large prospective cohort study. Chest. 2007 Feb;131(2):517-523.

Segal JB, Streiff MB, Hoffman LV, et al. Management of venous thromboembolism: a systematic review for a practice guideline. Ann Intern Med. 2007 Feb 6;146(3):211-222.

Snow V, Qaseem A, Barry P, et al. Management of venous thromboembolism: a clinical practice guideline from the American College of Physicians and the American Academy of Family Physicians. Ann Intern Med. 2007 Feb 6;146 (3):204-210. Epub 2007 Jan 29.

The prevention and treatment of venous thromboembolism (VTE) is a skill set required for all hospitalists given the prevalence of this condition in hospitalized patients as well as the significant morbidity and mortality associated with the condition. Several articles that help to guide our decisions in managing VTE have been published recently.

 

 

We have no randomized controlled trials (RCT) comparing twice-daily (bid) with three-times-daily (tid) dosing of unfractionated heparin (UFH) for the prevention of VTE in medically ill patient populations. It is unlikely that such a study, involving an adequate number of patients, will ever be conducted. Though low molecular weight heparins (LMWH) are used more frequently for VTE prevention, many hospitalists still use UFH to prevent VTE in patients who are morbidly obese or who have profound renal insufficiency. King and colleagues have done a meta-analysis to find out whether or not tid dosing is superior to bid dosing for VTE prevention. Twelve studies, including almost 8,000 patients from 1966 to 2004, were reviewed. All patients were hospitalized for medical rather than surgical conditions.

Tid heparin significantly decreased the incidence of the combined outcome of pulmonary embolism (PE) and proximal deep vein thrombosis (DVT). There was a trend toward significance in decreasing the incidence of PE. There was a significant increase in the number of major bleeds with tid dosing compared with bid dosing. There are many limitations to this study: It is retrospective, the population is extremely heterogeneous, and varying methods have been employed to diagnosis VTE across the many studies from which data were pooled. This is likely the best data we will have for UFH in VTE prevention, however. In summary, tid dosing is preferred for high-risk patients, but bid dosing should be considered for those at risk for bleeding complications.

Data are limited for the clinical course of PE. Outpatient treatment of PE with LMWH is not uncommon in select patients, but choosing who is safe to treat in this arena is uncertain. Nijkeuter and colleagues assessed the incidence of recurrent VTE, hemorrhagic complications from therapy, mortality, risk factors for recurrence, and the course of these events from the time of diagnosis through a three-month follow-up period.

Six hundred and seventy-three patients completed the three-month follow-up. Twenty of them (3%) had recurrent VTE; 14 of these had recurrent PE. Recurrence predominantly transpired in the first three weeks of therapy. Of those with recurrent PE, 11 (79%) were fatal, and most of these occurred within the first week of diagnosis. Major bleeding occurred in 1.5% of the patients. Immobilization for more than three days was a significant risk factor for recurrence. Inpatient status, a diagnosis of COPD, and malignancy were independent risk factors for bleeding complications. Fifty-five patients (8.2%) died over the three-month period. Twenty percent died of fatal recurrent PE, while 4% suffered fatal hemorrhage.

Multivariate analysis revealed four characteristics as independent risk factors for mortality in patients with PE. These include age, inpatient status, immobilization for more than three days, and malignancy. It appears that the majority of recurrent and fatal PE occurs during the first week of therapy. Physicians should not discharge patients to home with LMWH for PE without considering these risk factors for hemorrhage, recurrence, and mortality.

Annals of Internal Medicine has published a systematic review of management issues in VTE to provide the framework for the American College of Physicians practice guidelines. These guidelines pool data from more than 100 randomized controlled trials and comment on six areas in VTE management. The following are quotes from this document.

Recommendation #1: Use low molecular-weight heparin (LMWH) rather than unfractionated heparin whenever possible for the initial inpatient treatment of deep vein thrombosis (DVT). Either unfractionated heparin or LMWH is appropriate for the initial treatment of pulmonary embolism.

Recommendation #2: Outpatient treatment of DVT, and possibly pulmonary embolism, with LMWH is safe and cost-effective for carefully selected patients and should be considered if the required support services are in place.

 

 

Recommendation #3: Compression stockings should be used routinely to prevent post-thrombotic syndrome, beginning within one month of diagnosis of proximal DVT and continuing for a minimum of one year after diagnosis.

Recommendation #4: There is insufficient evidence to make specific recommendations for types of anticoagulation management of VTE in pregnant women.

Recommendation #5: Anticoagulation should be maintained for three to six months for VTE secondary to transient risk factors and for more than 12 months for recurrent VTE. While the appropriate duration of anticoagulation for idiopathic or recurrent VTE is not definitively known, there is evidence of substantial benefit for extended-duration therapy.

Recommendation #6: LMWH is safe and efficacious for the long-term treatment of VTE in selected patients (and may be preferable for patients with cancer).

All of these seem reasonable and appropriate with a possible exception in the second recommendation. Using LMWH to treat patients diagnosed with PE in the outpatient setting is not well supported by data. The vast majority of trials involving the treatment of VTE with LMWH have been conducted on those with DVT; the number of patients in the trials with PE has been very small. The Food and Drug Administration has not approved LMWH for outpatient treatment of PE; LMWH is FDA approved in the outpatient setting only for the treatment of DVT. We know that the hemodynamic changes that can accompany PE may not occur for at least 24 hours. In addition, we now have data from the Nijkeuter study that point to dangers that may result from treating PE outside the hospital setting. At this time, we should treat PE with LMWH in the outpatient setting only with patients whose risk factors, clinical characteristics, and outpatient resources have been carefully scrutinized. TH

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