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Should I evaluate my patient with atrial fibrillation for sleep apnea?

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Should I evaluate my patient with atrial fibrillation for sleep apnea?

Yes. The prevalence of sleep apnea is exceedingly high in patients with atrial fibrillation—50% to 80% compared with 30% to 60% in respective control groups.1–3 Conversely, atrial fibrillation is more prevalent in those with sleep-disordered breathing than in those without (4.8% vs 0.9%).4

Sleep-disordered breathing comprises obstructive sleep apnea and central sleep apnea. Obstructive sleep apnea, characterized by repetitive upper-airway obstruction during sleep, is accompanied by intermittent hypoxia, rises in carbon dioxide, autonomic nervous system fluctuations, and intrathoracic pressure alterations.5 Central sleep apnea may be neurally mediated and, in the setting of cardiac disease, is characterized by alterations in chemosensitivity and chemoresponsiveness, leading to a state of high loop gain—ie, a hypersensitive ventilatory control system leading to ventilatory drive oscillations.6

Both obstructive and central sleep apnea have been associated with atrial fibrillation. Experimental data implicate obstructive sleep apnea as a trigger of atrial arrhythmogenesis,7,8 and epidemiologic studies support an association between central sleep apnea, Cheyne-Stokes respiration, and incident atrial fibrillation.9

HOW SLEEP APNEA COULD LEAD TO ATRIAL FIBRILLATION

In experiments in animals, intermittent upper-airway obstruction led to forced inspiration, substantial negative intrathoracic pressure, subsequent left atrial distention, and increased susceptibility to atrial fibrillation.10 The autonomic nervous system may be a mediator of apnea-induced atrial fibrillation, as apnea-induced atrial fibrillation is suppressed with autonomic blockade.10

Emerging data also support the hypothesis that intermittent hypoxia7 and resolution of hypercapnia,8 as observed in obstructive sleep apnea, exert atrial electrophysiologic changes that increase vulnerability to atrial arrhythmogenesis.

In a case-crossover study,11 the odds of paroxysmal atrial fibrillation occurring after a respiratory disturbance were 17.9 times higher than after normal breathing (95% confidence interval [CI] 2.2–144.2), though the absolute rate of overall arrhythmia events (including both atrial fibrillation and nonsustained ventricular tachycardia) associated with respiratory disturbances was low (1 excess arrhythmia event per 40,000 respiratory disturbances).

EFFECT OF SLEEP APNEA ON ATRIAL FIBRILLATION MANAGEMENT

Sleep apnea also seems to affect the efficacy of a rhythm-control strategy for atrial fibrillation. For example, patients with obstructive sleep apnea have a higher risk of recurrent atrial fibrillation after cardioversion (82% vs 42% in controls)12 and up to a 25% greater risk of recurrence after catheter ablation compared with those without obstructive sleep apnea (risk ratio 1.25, 95% CI 1.08–1.45).13

Several observational studies showed a higher rate of atrial fibrillation after pulmonary vein isolation in obstructive sleep apnea patients who do not use continuous positive airway pressure (CPAP) than in those who do.14–17 CPAP therapy appears to exert beneficial effects on cardiac structural remodeling;  cardiac magnetic resonance imaging shows that patients with sleep apnea who received less than 4 hours of CPAP per night had larger left atrial dimensions and increased left ventricular mass compared with those who received more than 4 hours of CPAP at night.17 However, a need remains for high-quality, large randomized controlled trials to eliminate potential unmeasured biases due to differences that may exist between CPAP users and non-users, such as general adherence to medical therapy and healthcare interventions.

An additional consideration is that the overall utility and value of obtaining a diagnosis of obstructive sleep apnea strictly as it pertains to atrial fibrillation management is affected by whether a rhythm- or rate-control strategy is pursued. In other words, if a patient is deemed to be in permanent atrial fibrillation and a rhythm-control strategy is therefore not pursued, the potential effect of untreated obstructive sleep apnea on atrial fibrillation recurrence could be less important. In this case, however, the other beneficial cardiovascular and systemic effects of diagnosing and treating underlying obstructive sleep apnea would remain.

 

 

POPULATION STUDIES

Epidemiologic and clinic-based studies have supported an association between sleep apnea (mostly central, but also obstructive) and atrial fibrillation.4,18

Community-based studies such as the Sleep Heart Health Study4 and the Outcomes of Sleep Disorders in Older Men Study (MrOS Sleep),18 involving thousands of participants, have found the strongest cross-sectional associations of both obstructive and central sleep apnea with nocturnal atrial fibrillation. The findings included a 2 to 5 times higher odds of nocturnal atrial fibrillation, particularly in those with a moderate to severe degree of sleep-disordered breathing—even after adjusting for confounding influences (eg, obesity) and self-reported cardiac disease such as heart failure.

In MrOS Sleep, in an older male cohort, both obstructive and central sleep apnea were associated with nocturnal atrial fibrillation, though central sleep apnea and Cheyne-Stokes respirations had a stronger magnitude of association.18

Further insights can be drawn specifically from patients with heart failure. Sin et al,19 in a 1999 study, found that in 450 patients with systolic heart failure (85% men), the prevalence of sleep-disordered breathing was 25% to 33% (depending on the apnea-hypopnea index cutoff used) for central sleep apnea, and similarly 27% to 38% for obstructive sleep apnea. The prevalence of atrial fibrillation in this group was 10% in women and 15% in men. Atrial fibrillation was reported as a significant risk factor for central sleep apnea, but not for obstructive sleep apnea (for which only male sex and increasing body mass index were significant risk factors). Directionality was not clearly reported in this retrospective study in terms of timing of sleep studies and other assessments: ie, the report did not clearly state which came first, the atrial fibrillation or the sleep apnea. Therefore, the possibility that central sleep apnea is a predictor of atrial fibrillation cannot be excluded.  

Yumino et al,20 in a study published in 2009, evaluated 218 patients with heart failure (with a left ventricular ejection fraction of ≤ 45%) and reported a prevalence of moderate to severe sleep apnea of 21% for central sleep apnea and 26% for obstructive sleep apnea. In multivariate analysis, atrial fibrillation was independently associated with central sleep apnea but not obstructive sleep apnea.

In recent cohort studies, central sleep apnea was associated with 2 to 3 times higher odds of developing atrial fibrillation, while obstructive sleep apnea was not a predictor of incident atrial fibrillation.9,21

Although most available studies associate sleep apnea with atrial fibrillation, findings of a case-control study22 did not support a difference in the prevalence of sleep apnea syndrome (defined as apnea index ≥ 5 and apnea-hypopnea index ≥ 15, and the presence of sleep symptoms) in patients with lone atrial fibrillation (no evident cardiovascular disease) compared with controls matched for age, sex, and cardiovascular morbidity.

But observational studies are limited by the potential for residual unmeasured confounding factors and lack of objective cardiac structural data, such as left ventricular ejection fraction and atrial enlargement. Moreover, there can be significant differences in sleep apnea definitions among studies, thus limiting the ability to reach a definitive conclusion about the relationship between sleep apnea and atrial fibrillation.

SCREENING AND DIAGNOSIS

The 2014 joint guidelines of the American Heart Association, American College of Cardiology, and Heart Rhythm Society for the management of atrial fibrillation state that a sleep study may be useful if sleep apnea is suspected.23 The 2019 focused update of the 2014 guidelines24 state that for overweight and obese patients with atrial fibrillation, weight loss combined with risk-factor modification is recommended (class I recommendation, level of evidence B-R, ie, data derived from 1 or more randomized trials or meta-analysis of such studies). Risk-factor modification in this case includes assessment and treatment of underlying sleep apnea, hypertension, hyperlipidemia, glucose intolerance, and alcohol and tobacco use.

Table 1. Screening tools to identify increased risk of obstructive sleep apnea
Further study is needed to evaluate whether physicians should routinely use screening tools for sleep apnea in patients with atrial fibrillation. Standardized screening methods such as the Berlin questionnaire,25 STOP-Bang,26 and NoSAS27 (Table 1) are limited by lack of validation in patients with atrial fibrillation, particularly as the symptom profile may be different from that in patients who do not have atrial fibrillation.

Laboratory polysomnography has long been considered the gold standard for sleep apnea diagnosis. In one study,13 obstructive sleep apnea was a greater predictor of atrial fibrillation when diagnosed by polysomnography (risk ratio 1.40, 95% CI 1.16–1.68) compared with identification by screening using the Berlin questionnaire (risk ratio 1.07, 95% CI 0.91–1.27). However, a laboratory sleep study is associated with increased patient burden and limited availability.

Home sleep apnea testing is being increasingly used in the diagnostic evaluation of obstructive sleep apnea and may be a less costly, more available alternative. However, since a home sleep apnea test is less sensitive than polysomnography in detecting obstructive sleep apnea, the American Academy of Sleep Medicine guidelines28 state that if a single home sleep apnea test is negative or inconclusive, polysomnography should be done if there is clinical suspicion of sleep apnea. Moreover, current guidelines from this group recommend that patients with significant cardiorespiratory disease should be tested with polysomnography rather than home sleep apnea testing.22

Further study is needed to determine the optimal screening method for sleep apnea in patients with atrial fibrillation and to clarify the role of home sleep apnea testing. While keeping in mind the limitations of a screening questionnaire in this population, as a general approach it is reasonable to use a screening questionnaire for sleep apnea. And if the screen is positive, further evaluation with a sleep study is merited, whether by laboratory polysomnography, a home sleep apnea test, or referral to a sleep specialist.

MULTIDISCIPLINARY CARE MAY BE IDEAL

Overall, given the high prevalence of sleep apnea in patients with atrial fibrillation, the deleterious effects of sleep apnea in general, the influence of sleep apnea on atrial fibrillation, and the cardiovascular and other beneficial effects of adequate treatment of sleep apnea, patients with atrial fibrillation should be assessed for sleep apnea.

While the optimal strategy in evaluating for sleep apnea in these patients needs to be further defined, a multidisciplinary approach to care involving a primary care provider, cardiologist, and sleep specialist may be ideal.

References
  1. Braga B, Poyares D, Cintra F, et al. Sleep-disordered breathing and chronic atrial fibrillation. Sleep Med 2009; 10(2):212–216. doi:10.1016/j.sleep.2007.12.007
  2. Gami AS, Pressman G, Caples SM, et al. Association of atrial fibrillation and obstructive sleep apnea. Circulation 2004; 110(4):364–367. doi:10.1161/01.CIR.0000136587.68725.8E
  3. Stevenson IH, Teichtahl H, Cunnington D, Ciavarella S, Gordon I, Kalman JM. Prevalence of sleep disordered breathing in paroxysmal and persistent atrial fibrillation patients with normal left ventricular function. Eur Heart J 2008; 29(13):1662–1669. doi:10.1093/eurheartj/ehn214
  4. Mehra R, Benjamin EJ, Shahar E, et al. Association of nocturnal arrhythmias with sleep-disordered breathing: The Sleep Heart Health Study. Am J Respir Crit Care Med 2006; 173(8):910–916. doi:10.1164/rccm.200509-1442OC
  5. Cooper VL, Bowker CM, Pearson SB, Elliott MW, Hainsworth R. Effects of simulated obstructive sleep apnoea on the human carotid baroreceptor-vascular resistance reflex. J Physiol 2004; 557(pt 3):1055–1065. doi:10.1113/jphysiol.2004.062513
  6. Eckert DJ, Jordan AS, Merchia P, Malhotra A. Central sleep apnea: pathophysiology and treatment. Chest 2007; 131(2):595–607. doi:10.1378/chest.06.2287
  7. Lévy P, Pépin JL, Arnaud C, et al. Intermittent hypoxia and sleep-disordered breathing: current concepts and perspectives. Eur Respir J 2008; 32(4):1082–1095. doi:10.1183/09031936.00013308
  8. Stevenson IH, Roberts-Thomson KC, Kistler PM, et al. Atrial electrophysiology is altered by acute hypercapnia but not hypoxemia: implications for promotion of atrial fibrillation in pulmonary disease and sleep apnea. Heart Rhythm 2010; 7(9):1263–1270. doi:10.1016/j.hrthm.2010.03.020
  9. Tung P, Levitzky YS, Wang R, et al. Obstructive and central sleep apnea and the risk of incident atrial fibrillation in a community cohort of men and women. J Am Heart Assoc 2017; 6(7). doi:10.1161/JAHA.116.004500
  10. Iwasaki YK, Shi Y, Benito B, et al. Determinants of atrial fibrillation in an animal model of obesity and acute obstructive sleep apnea. Heart Rhythm 2012; 9(9):1409–1416.e1. doi:10.1016/j.hrthm.2012.03.024
  11. Monahan K, Storfer-Isser A, Mehra R, et al. Triggering of nocturnal arrhythmias by sleep-disordered breathing events. J Am Coll Cardiol 2009; 54(19):1797–1804. doi:10.1016/j.jacc.2009.06.038
  12. Kanagala R, Murali NS, Friedman PA, et al. Obstructive sleep apnea and the recurrence of atrial fibrillation. Circulation 2003; 107(20):2589–2594. doi:10.1161/01.CIR.0000068337.25994.21
  13. Ng CY, Liu T, Shehata M, Stevens S, Chugh SS, Wang X. Meta-analysis of obstructive sleep apnea as predictor of atrial fibrillation recurrence after catheter ablation. Am J Cardiol 2011; 108(1):47–51. doi:10.1016/j.amjcard.2011.02.343
  14. Naruse Y, Tada H, Satoh M, et al. Concomitant obstructive sleep apnea increases the recurrence of atrial fibrillation following radiofrequency catheter ablation of atrial fibrillation: clinical impact of continuous positive airway pressure therapy. Heart Rhythm 2013; 10(3):331–337. doi:10.1016/j.hrthm.2012.11.015
  15. Fein AS, Shvilkin A, Shah D, et al. Treatment of obstructive sleep apnea reduces the risk of atrial fibrillation recurrence after catheter ablation. J Am Coll Cardiol 2013; 62(4):300–305. doi:10.1016/j.jacc.2013.03.052
  16. Patel D, Mohanty P, Di Biase L, et al. Safety and efficacy of pulmonary vein antral isolation in patients with obstructive sleep apnea: the impact of continuous positive airway pressure. Circ Arrhythm Electrophysiol 2010; 3(5):445–451. doi:10.1161/CIRCEP.109.858381
  17. Neilan TG, Farhad H, Dodson JA, et al. Effect of sleep apnea and continuous positive airway pressure on cardiac structure and recurrence of atrial fibrillation. J Am Heart Assoc 2013; 2(6):e000421. doi:10.1161/JAHA.113.000421
  18. Mehra R, Stone KL, Varosy PD, et al. Nocturnal arrhythmias across a spectrum of obstructive and central sleep-disordered breathing in older men: outcomes of sleep disorders in older men (MrOS sleep) study. Arch Intern Med 2009; 169(12):1147–1155. doi:10.1001/archinternmed.2009.138
  19. Sin DD, Fitzgerald F, Parker JD, Newton G, Floras JS, Bradley TD. Risk factors for central and obstructive sleep apnea in 450 men and women with congestive heart failure. Am J Respir Crit Care Med 1999; 160(4):1101–1106. doi:10.1164/ajrccm.160.4.9903020
  20. Yumino D, Wang H, Floras JS, et al. Prevalence and physiological predictors of sleep apnea in patients with heart failure and systolic dysfunction. J Card Fail 2009; 15(4):279–285. doi:10.1016/j.cardfail.2008.11.015
  21. May AM, Blackwell T, Stone PH, et al; MrOS Sleep (Outcomes of Sleep Disorders in Older Men) Study Group. Central sleep-disordered breathing predicts incident atrial fibrillation in older men. Am J Respir Crit Care Med 2016; 193(7):783–791. doi:10.1164/rccm.201508-1523OC
  22. Porthan KM, Melin JH, Kupila JT, Venho KK, Partinen MM. Prevalence of sleep apnea syndrome in lone atrial fibrillation: a case-control study. Chest 2004; 125(3):879–885. doi:10.1378/chest.125.3.879
  23. January CT, Wann LS, Alpert JS, et al; ACC/AHA Task Force Members. 2014 AHA/ACC/HRS guideline for the management of patients with atrial fibrillation: a report of the American College of Cardiology/American Heart Association Task Force on practice guidelines and the Heart Rhythm Society. Circulation 2014; 130(23):e199–e267. doi:10.1161/CIR.0000000000000041
  24. Writing Group Members; January CT, Wann LS, Calkins H, et al. 2019 AHA/ACC/HRS focused update of the 2014 AHA/ACC/HRS guideline for the management of patients with atrial fibrillation: a report of the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines and the Heart Rhythm Society. Heart Rhythm. 2019; 16(8):e66–e93. doi:10.1016/j.hrthm.2019.01.024
  25. Netzer NC, Stoohs RA, Netzer CM, Clark K, Strohl KP. Using the Berlin Questionnaire to identify patients at risk for the sleep apnea syndrome. Ann Intern Med 1999; 131(7):485–491. doi:10.7326/0003-4819-131-7-199910050-00002
  26. Chung F, Abdullah HR, Liao P. STOP-bang questionnaire a practical approach to screen for obstructive sleep apnea. Chest 2016; 149(3):631–638. doi:10.1378/chest.15-0903
  27. Marti-Soler H, Hirotsu C, Marques-Vidal P, et al. The NoSAS score for screening of sleep-disordered breathing: a derivation and validation study. Lancet Respir Med 2016; 4(9):742–748. doi:10.1016/S2213-2600(16)30075-3
  28. Kapur VK, Auckley DH, Chowdhuri S, et al. Clinical practice guideline for diagnostic testing for adult obstructive sleep apnea: an American Academy of Sleep Medicine clinical practice guideline. J Clin Sleep Med 2017; 13(3):479–504. doi:10.5664/jcsm.6506
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Author and Disclosure Information

Mirna B. Ayache, MD, MPH
Department of Pulmonary, Sleep, and Critical Care Medicine, MetroHealth Medical Center; Assistant Professor of Medicine, Case Western Reserve University School of Medicine, Cleveland, OH

Reena Mehra, MD, MS, FCCP, FAASM
Director of Sleep Disorders Research, Sleep Neurologic Institute and Staff, Respiratory Institute, Heart and Vascular Institute, and Department of Molecular Cardiology of the Lerner Research Institute, Cleveland Clinic; Professor of Medicine, Cleveland Clinic Lerner College of Medicine of Case Western Reserve University, Cleveland, OH

Kenneth A. Mayuga, MD, FACC, FHRS
Section of Cardiac Electrophysiology and Pacing, Department of Cardiovascular Medicine, Cleveland Clinic; Assistant Professor of Medicine, Cleveland Clinic Lerner College of Medicine of Case Western Reserve University, Cleveland, OH

Address: Kenneth A. Mayuga, MD, FACC, FHRS, Section of Cardiac Electrophysiology and Pacing, Department of Cardiovascular Medicine, J2-2, Cleveland Clinic, 9500 Euclid Avenue, Cleveland, OH 44195; [email protected]

Dr. Mehra has disclosed teaching and speaking for the American Academy of Sleep Medicine; membership on advisory committee or review panel and research for Enhale; research or independent contracting for Inspire, the National Institutes of Health, Natus Neuro, Philips Respironics, and ResMed Corporation; consulting partnership with Respicardia Inc; and intellectual property rights with UpToDate.

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Cleveland Clinic Journal of Medicine - 86(11)
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709-712
Legacy Keywords
atrial fibrillation, sleep apnea, sleep-disordered breathing, obstructive sleep apnea, central sleep apnea, continuous positive airway pressure, CPAP, sleep study, polysomnography, STOP-Bang, Berlin questionnaire, NoSAS, Mirna Ayache, Reena Mehra, Kenneth Mayuga
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Author and Disclosure Information

Mirna B. Ayache, MD, MPH
Department of Pulmonary, Sleep, and Critical Care Medicine, MetroHealth Medical Center; Assistant Professor of Medicine, Case Western Reserve University School of Medicine, Cleveland, OH

Reena Mehra, MD, MS, FCCP, FAASM
Director of Sleep Disorders Research, Sleep Neurologic Institute and Staff, Respiratory Institute, Heart and Vascular Institute, and Department of Molecular Cardiology of the Lerner Research Institute, Cleveland Clinic; Professor of Medicine, Cleveland Clinic Lerner College of Medicine of Case Western Reserve University, Cleveland, OH

Kenneth A. Mayuga, MD, FACC, FHRS
Section of Cardiac Electrophysiology and Pacing, Department of Cardiovascular Medicine, Cleveland Clinic; Assistant Professor of Medicine, Cleveland Clinic Lerner College of Medicine of Case Western Reserve University, Cleveland, OH

Address: Kenneth A. Mayuga, MD, FACC, FHRS, Section of Cardiac Electrophysiology and Pacing, Department of Cardiovascular Medicine, J2-2, Cleveland Clinic, 9500 Euclid Avenue, Cleveland, OH 44195; [email protected]

Dr. Mehra has disclosed teaching and speaking for the American Academy of Sleep Medicine; membership on advisory committee or review panel and research for Enhale; research or independent contracting for Inspire, the National Institutes of Health, Natus Neuro, Philips Respironics, and ResMed Corporation; consulting partnership with Respicardia Inc; and intellectual property rights with UpToDate.

Author and Disclosure Information

Mirna B. Ayache, MD, MPH
Department of Pulmonary, Sleep, and Critical Care Medicine, MetroHealth Medical Center; Assistant Professor of Medicine, Case Western Reserve University School of Medicine, Cleveland, OH

Reena Mehra, MD, MS, FCCP, FAASM
Director of Sleep Disorders Research, Sleep Neurologic Institute and Staff, Respiratory Institute, Heart and Vascular Institute, and Department of Molecular Cardiology of the Lerner Research Institute, Cleveland Clinic; Professor of Medicine, Cleveland Clinic Lerner College of Medicine of Case Western Reserve University, Cleveland, OH

Kenneth A. Mayuga, MD, FACC, FHRS
Section of Cardiac Electrophysiology and Pacing, Department of Cardiovascular Medicine, Cleveland Clinic; Assistant Professor of Medicine, Cleveland Clinic Lerner College of Medicine of Case Western Reserve University, Cleveland, OH

Address: Kenneth A. Mayuga, MD, FACC, FHRS, Section of Cardiac Electrophysiology and Pacing, Department of Cardiovascular Medicine, J2-2, Cleveland Clinic, 9500 Euclid Avenue, Cleveland, OH 44195; [email protected]

Dr. Mehra has disclosed teaching and speaking for the American Academy of Sleep Medicine; membership on advisory committee or review panel and research for Enhale; research or independent contracting for Inspire, the National Institutes of Health, Natus Neuro, Philips Respironics, and ResMed Corporation; consulting partnership with Respicardia Inc; and intellectual property rights with UpToDate.

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Yes. The prevalence of sleep apnea is exceedingly high in patients with atrial fibrillation—50% to 80% compared with 30% to 60% in respective control groups.1–3 Conversely, atrial fibrillation is more prevalent in those with sleep-disordered breathing than in those without (4.8% vs 0.9%).4

Sleep-disordered breathing comprises obstructive sleep apnea and central sleep apnea. Obstructive sleep apnea, characterized by repetitive upper-airway obstruction during sleep, is accompanied by intermittent hypoxia, rises in carbon dioxide, autonomic nervous system fluctuations, and intrathoracic pressure alterations.5 Central sleep apnea may be neurally mediated and, in the setting of cardiac disease, is characterized by alterations in chemosensitivity and chemoresponsiveness, leading to a state of high loop gain—ie, a hypersensitive ventilatory control system leading to ventilatory drive oscillations.6

Both obstructive and central sleep apnea have been associated with atrial fibrillation. Experimental data implicate obstructive sleep apnea as a trigger of atrial arrhythmogenesis,7,8 and epidemiologic studies support an association between central sleep apnea, Cheyne-Stokes respiration, and incident atrial fibrillation.9

HOW SLEEP APNEA COULD LEAD TO ATRIAL FIBRILLATION

In experiments in animals, intermittent upper-airway obstruction led to forced inspiration, substantial negative intrathoracic pressure, subsequent left atrial distention, and increased susceptibility to atrial fibrillation.10 The autonomic nervous system may be a mediator of apnea-induced atrial fibrillation, as apnea-induced atrial fibrillation is suppressed with autonomic blockade.10

Emerging data also support the hypothesis that intermittent hypoxia7 and resolution of hypercapnia,8 as observed in obstructive sleep apnea, exert atrial electrophysiologic changes that increase vulnerability to atrial arrhythmogenesis.

In a case-crossover study,11 the odds of paroxysmal atrial fibrillation occurring after a respiratory disturbance were 17.9 times higher than after normal breathing (95% confidence interval [CI] 2.2–144.2), though the absolute rate of overall arrhythmia events (including both atrial fibrillation and nonsustained ventricular tachycardia) associated with respiratory disturbances was low (1 excess arrhythmia event per 40,000 respiratory disturbances).

EFFECT OF SLEEP APNEA ON ATRIAL FIBRILLATION MANAGEMENT

Sleep apnea also seems to affect the efficacy of a rhythm-control strategy for atrial fibrillation. For example, patients with obstructive sleep apnea have a higher risk of recurrent atrial fibrillation after cardioversion (82% vs 42% in controls)12 and up to a 25% greater risk of recurrence after catheter ablation compared with those without obstructive sleep apnea (risk ratio 1.25, 95% CI 1.08–1.45).13

Several observational studies showed a higher rate of atrial fibrillation after pulmonary vein isolation in obstructive sleep apnea patients who do not use continuous positive airway pressure (CPAP) than in those who do.14–17 CPAP therapy appears to exert beneficial effects on cardiac structural remodeling;  cardiac magnetic resonance imaging shows that patients with sleep apnea who received less than 4 hours of CPAP per night had larger left atrial dimensions and increased left ventricular mass compared with those who received more than 4 hours of CPAP at night.17 However, a need remains for high-quality, large randomized controlled trials to eliminate potential unmeasured biases due to differences that may exist between CPAP users and non-users, such as general adherence to medical therapy and healthcare interventions.

An additional consideration is that the overall utility and value of obtaining a diagnosis of obstructive sleep apnea strictly as it pertains to atrial fibrillation management is affected by whether a rhythm- or rate-control strategy is pursued. In other words, if a patient is deemed to be in permanent atrial fibrillation and a rhythm-control strategy is therefore not pursued, the potential effect of untreated obstructive sleep apnea on atrial fibrillation recurrence could be less important. In this case, however, the other beneficial cardiovascular and systemic effects of diagnosing and treating underlying obstructive sleep apnea would remain.

 

 

POPULATION STUDIES

Epidemiologic and clinic-based studies have supported an association between sleep apnea (mostly central, but also obstructive) and atrial fibrillation.4,18

Community-based studies such as the Sleep Heart Health Study4 and the Outcomes of Sleep Disorders in Older Men Study (MrOS Sleep),18 involving thousands of participants, have found the strongest cross-sectional associations of both obstructive and central sleep apnea with nocturnal atrial fibrillation. The findings included a 2 to 5 times higher odds of nocturnal atrial fibrillation, particularly in those with a moderate to severe degree of sleep-disordered breathing—even after adjusting for confounding influences (eg, obesity) and self-reported cardiac disease such as heart failure.

In MrOS Sleep, in an older male cohort, both obstructive and central sleep apnea were associated with nocturnal atrial fibrillation, though central sleep apnea and Cheyne-Stokes respirations had a stronger magnitude of association.18

Further insights can be drawn specifically from patients with heart failure. Sin et al,19 in a 1999 study, found that in 450 patients with systolic heart failure (85% men), the prevalence of sleep-disordered breathing was 25% to 33% (depending on the apnea-hypopnea index cutoff used) for central sleep apnea, and similarly 27% to 38% for obstructive sleep apnea. The prevalence of atrial fibrillation in this group was 10% in women and 15% in men. Atrial fibrillation was reported as a significant risk factor for central sleep apnea, but not for obstructive sleep apnea (for which only male sex and increasing body mass index were significant risk factors). Directionality was not clearly reported in this retrospective study in terms of timing of sleep studies and other assessments: ie, the report did not clearly state which came first, the atrial fibrillation or the sleep apnea. Therefore, the possibility that central sleep apnea is a predictor of atrial fibrillation cannot be excluded.  

Yumino et al,20 in a study published in 2009, evaluated 218 patients with heart failure (with a left ventricular ejection fraction of ≤ 45%) and reported a prevalence of moderate to severe sleep apnea of 21% for central sleep apnea and 26% for obstructive sleep apnea. In multivariate analysis, atrial fibrillation was independently associated with central sleep apnea but not obstructive sleep apnea.

In recent cohort studies, central sleep apnea was associated with 2 to 3 times higher odds of developing atrial fibrillation, while obstructive sleep apnea was not a predictor of incident atrial fibrillation.9,21

Although most available studies associate sleep apnea with atrial fibrillation, findings of a case-control study22 did not support a difference in the prevalence of sleep apnea syndrome (defined as apnea index ≥ 5 and apnea-hypopnea index ≥ 15, and the presence of sleep symptoms) in patients with lone atrial fibrillation (no evident cardiovascular disease) compared with controls matched for age, sex, and cardiovascular morbidity.

But observational studies are limited by the potential for residual unmeasured confounding factors and lack of objective cardiac structural data, such as left ventricular ejection fraction and atrial enlargement. Moreover, there can be significant differences in sleep apnea definitions among studies, thus limiting the ability to reach a definitive conclusion about the relationship between sleep apnea and atrial fibrillation.

SCREENING AND DIAGNOSIS

The 2014 joint guidelines of the American Heart Association, American College of Cardiology, and Heart Rhythm Society for the management of atrial fibrillation state that a sleep study may be useful if sleep apnea is suspected.23 The 2019 focused update of the 2014 guidelines24 state that for overweight and obese patients with atrial fibrillation, weight loss combined with risk-factor modification is recommended (class I recommendation, level of evidence B-R, ie, data derived from 1 or more randomized trials or meta-analysis of such studies). Risk-factor modification in this case includes assessment and treatment of underlying sleep apnea, hypertension, hyperlipidemia, glucose intolerance, and alcohol and tobacco use.

Table 1. Screening tools to identify increased risk of obstructive sleep apnea
Further study is needed to evaluate whether physicians should routinely use screening tools for sleep apnea in patients with atrial fibrillation. Standardized screening methods such as the Berlin questionnaire,25 STOP-Bang,26 and NoSAS27 (Table 1) are limited by lack of validation in patients with atrial fibrillation, particularly as the symptom profile may be different from that in patients who do not have atrial fibrillation.

Laboratory polysomnography has long been considered the gold standard for sleep apnea diagnosis. In one study,13 obstructive sleep apnea was a greater predictor of atrial fibrillation when diagnosed by polysomnography (risk ratio 1.40, 95% CI 1.16–1.68) compared with identification by screening using the Berlin questionnaire (risk ratio 1.07, 95% CI 0.91–1.27). However, a laboratory sleep study is associated with increased patient burden and limited availability.

Home sleep apnea testing is being increasingly used in the diagnostic evaluation of obstructive sleep apnea and may be a less costly, more available alternative. However, since a home sleep apnea test is less sensitive than polysomnography in detecting obstructive sleep apnea, the American Academy of Sleep Medicine guidelines28 state that if a single home sleep apnea test is negative or inconclusive, polysomnography should be done if there is clinical suspicion of sleep apnea. Moreover, current guidelines from this group recommend that patients with significant cardiorespiratory disease should be tested with polysomnography rather than home sleep apnea testing.22

Further study is needed to determine the optimal screening method for sleep apnea in patients with atrial fibrillation and to clarify the role of home sleep apnea testing. While keeping in mind the limitations of a screening questionnaire in this population, as a general approach it is reasonable to use a screening questionnaire for sleep apnea. And if the screen is positive, further evaluation with a sleep study is merited, whether by laboratory polysomnography, a home sleep apnea test, or referral to a sleep specialist.

MULTIDISCIPLINARY CARE MAY BE IDEAL

Overall, given the high prevalence of sleep apnea in patients with atrial fibrillation, the deleterious effects of sleep apnea in general, the influence of sleep apnea on atrial fibrillation, and the cardiovascular and other beneficial effects of adequate treatment of sleep apnea, patients with atrial fibrillation should be assessed for sleep apnea.

While the optimal strategy in evaluating for sleep apnea in these patients needs to be further defined, a multidisciplinary approach to care involving a primary care provider, cardiologist, and sleep specialist may be ideal.

Yes. The prevalence of sleep apnea is exceedingly high in patients with atrial fibrillation—50% to 80% compared with 30% to 60% in respective control groups.1–3 Conversely, atrial fibrillation is more prevalent in those with sleep-disordered breathing than in those without (4.8% vs 0.9%).4

Sleep-disordered breathing comprises obstructive sleep apnea and central sleep apnea. Obstructive sleep apnea, characterized by repetitive upper-airway obstruction during sleep, is accompanied by intermittent hypoxia, rises in carbon dioxide, autonomic nervous system fluctuations, and intrathoracic pressure alterations.5 Central sleep apnea may be neurally mediated and, in the setting of cardiac disease, is characterized by alterations in chemosensitivity and chemoresponsiveness, leading to a state of high loop gain—ie, a hypersensitive ventilatory control system leading to ventilatory drive oscillations.6

Both obstructive and central sleep apnea have been associated with atrial fibrillation. Experimental data implicate obstructive sleep apnea as a trigger of atrial arrhythmogenesis,7,8 and epidemiologic studies support an association between central sleep apnea, Cheyne-Stokes respiration, and incident atrial fibrillation.9

HOW SLEEP APNEA COULD LEAD TO ATRIAL FIBRILLATION

In experiments in animals, intermittent upper-airway obstruction led to forced inspiration, substantial negative intrathoracic pressure, subsequent left atrial distention, and increased susceptibility to atrial fibrillation.10 The autonomic nervous system may be a mediator of apnea-induced atrial fibrillation, as apnea-induced atrial fibrillation is suppressed with autonomic blockade.10

Emerging data also support the hypothesis that intermittent hypoxia7 and resolution of hypercapnia,8 as observed in obstructive sleep apnea, exert atrial electrophysiologic changes that increase vulnerability to atrial arrhythmogenesis.

In a case-crossover study,11 the odds of paroxysmal atrial fibrillation occurring after a respiratory disturbance were 17.9 times higher than after normal breathing (95% confidence interval [CI] 2.2–144.2), though the absolute rate of overall arrhythmia events (including both atrial fibrillation and nonsustained ventricular tachycardia) associated with respiratory disturbances was low (1 excess arrhythmia event per 40,000 respiratory disturbances).

EFFECT OF SLEEP APNEA ON ATRIAL FIBRILLATION MANAGEMENT

Sleep apnea also seems to affect the efficacy of a rhythm-control strategy for atrial fibrillation. For example, patients with obstructive sleep apnea have a higher risk of recurrent atrial fibrillation after cardioversion (82% vs 42% in controls)12 and up to a 25% greater risk of recurrence after catheter ablation compared with those without obstructive sleep apnea (risk ratio 1.25, 95% CI 1.08–1.45).13

Several observational studies showed a higher rate of atrial fibrillation after pulmonary vein isolation in obstructive sleep apnea patients who do not use continuous positive airway pressure (CPAP) than in those who do.14–17 CPAP therapy appears to exert beneficial effects on cardiac structural remodeling;  cardiac magnetic resonance imaging shows that patients with sleep apnea who received less than 4 hours of CPAP per night had larger left atrial dimensions and increased left ventricular mass compared with those who received more than 4 hours of CPAP at night.17 However, a need remains for high-quality, large randomized controlled trials to eliminate potential unmeasured biases due to differences that may exist between CPAP users and non-users, such as general adherence to medical therapy and healthcare interventions.

An additional consideration is that the overall utility and value of obtaining a diagnosis of obstructive sleep apnea strictly as it pertains to atrial fibrillation management is affected by whether a rhythm- or rate-control strategy is pursued. In other words, if a patient is deemed to be in permanent atrial fibrillation and a rhythm-control strategy is therefore not pursued, the potential effect of untreated obstructive sleep apnea on atrial fibrillation recurrence could be less important. In this case, however, the other beneficial cardiovascular and systemic effects of diagnosing and treating underlying obstructive sleep apnea would remain.

 

 

POPULATION STUDIES

Epidemiologic and clinic-based studies have supported an association between sleep apnea (mostly central, but also obstructive) and atrial fibrillation.4,18

Community-based studies such as the Sleep Heart Health Study4 and the Outcomes of Sleep Disorders in Older Men Study (MrOS Sleep),18 involving thousands of participants, have found the strongest cross-sectional associations of both obstructive and central sleep apnea with nocturnal atrial fibrillation. The findings included a 2 to 5 times higher odds of nocturnal atrial fibrillation, particularly in those with a moderate to severe degree of sleep-disordered breathing—even after adjusting for confounding influences (eg, obesity) and self-reported cardiac disease such as heart failure.

In MrOS Sleep, in an older male cohort, both obstructive and central sleep apnea were associated with nocturnal atrial fibrillation, though central sleep apnea and Cheyne-Stokes respirations had a stronger magnitude of association.18

Further insights can be drawn specifically from patients with heart failure. Sin et al,19 in a 1999 study, found that in 450 patients with systolic heart failure (85% men), the prevalence of sleep-disordered breathing was 25% to 33% (depending on the apnea-hypopnea index cutoff used) for central sleep apnea, and similarly 27% to 38% for obstructive sleep apnea. The prevalence of atrial fibrillation in this group was 10% in women and 15% in men. Atrial fibrillation was reported as a significant risk factor for central sleep apnea, but not for obstructive sleep apnea (for which only male sex and increasing body mass index were significant risk factors). Directionality was not clearly reported in this retrospective study in terms of timing of sleep studies and other assessments: ie, the report did not clearly state which came first, the atrial fibrillation or the sleep apnea. Therefore, the possibility that central sleep apnea is a predictor of atrial fibrillation cannot be excluded.  

Yumino et al,20 in a study published in 2009, evaluated 218 patients with heart failure (with a left ventricular ejection fraction of ≤ 45%) and reported a prevalence of moderate to severe sleep apnea of 21% for central sleep apnea and 26% for obstructive sleep apnea. In multivariate analysis, atrial fibrillation was independently associated with central sleep apnea but not obstructive sleep apnea.

In recent cohort studies, central sleep apnea was associated with 2 to 3 times higher odds of developing atrial fibrillation, while obstructive sleep apnea was not a predictor of incident atrial fibrillation.9,21

Although most available studies associate sleep apnea with atrial fibrillation, findings of a case-control study22 did not support a difference in the prevalence of sleep apnea syndrome (defined as apnea index ≥ 5 and apnea-hypopnea index ≥ 15, and the presence of sleep symptoms) in patients with lone atrial fibrillation (no evident cardiovascular disease) compared with controls matched for age, sex, and cardiovascular morbidity.

But observational studies are limited by the potential for residual unmeasured confounding factors and lack of objective cardiac structural data, such as left ventricular ejection fraction and atrial enlargement. Moreover, there can be significant differences in sleep apnea definitions among studies, thus limiting the ability to reach a definitive conclusion about the relationship between sleep apnea and atrial fibrillation.

SCREENING AND DIAGNOSIS

The 2014 joint guidelines of the American Heart Association, American College of Cardiology, and Heart Rhythm Society for the management of atrial fibrillation state that a sleep study may be useful if sleep apnea is suspected.23 The 2019 focused update of the 2014 guidelines24 state that for overweight and obese patients with atrial fibrillation, weight loss combined with risk-factor modification is recommended (class I recommendation, level of evidence B-R, ie, data derived from 1 or more randomized trials or meta-analysis of such studies). Risk-factor modification in this case includes assessment and treatment of underlying sleep apnea, hypertension, hyperlipidemia, glucose intolerance, and alcohol and tobacco use.

Table 1. Screening tools to identify increased risk of obstructive sleep apnea
Further study is needed to evaluate whether physicians should routinely use screening tools for sleep apnea in patients with atrial fibrillation. Standardized screening methods such as the Berlin questionnaire,25 STOP-Bang,26 and NoSAS27 (Table 1) are limited by lack of validation in patients with atrial fibrillation, particularly as the symptom profile may be different from that in patients who do not have atrial fibrillation.

Laboratory polysomnography has long been considered the gold standard for sleep apnea diagnosis. In one study,13 obstructive sleep apnea was a greater predictor of atrial fibrillation when diagnosed by polysomnography (risk ratio 1.40, 95% CI 1.16–1.68) compared with identification by screening using the Berlin questionnaire (risk ratio 1.07, 95% CI 0.91–1.27). However, a laboratory sleep study is associated with increased patient burden and limited availability.

Home sleep apnea testing is being increasingly used in the diagnostic evaluation of obstructive sleep apnea and may be a less costly, more available alternative. However, since a home sleep apnea test is less sensitive than polysomnography in detecting obstructive sleep apnea, the American Academy of Sleep Medicine guidelines28 state that if a single home sleep apnea test is negative or inconclusive, polysomnography should be done if there is clinical suspicion of sleep apnea. Moreover, current guidelines from this group recommend that patients with significant cardiorespiratory disease should be tested with polysomnography rather than home sleep apnea testing.22

Further study is needed to determine the optimal screening method for sleep apnea in patients with atrial fibrillation and to clarify the role of home sleep apnea testing. While keeping in mind the limitations of a screening questionnaire in this population, as a general approach it is reasonable to use a screening questionnaire for sleep apnea. And if the screen is positive, further evaluation with a sleep study is merited, whether by laboratory polysomnography, a home sleep apnea test, or referral to a sleep specialist.

MULTIDISCIPLINARY CARE MAY BE IDEAL

Overall, given the high prevalence of sleep apnea in patients with atrial fibrillation, the deleterious effects of sleep apnea in general, the influence of sleep apnea on atrial fibrillation, and the cardiovascular and other beneficial effects of adequate treatment of sleep apnea, patients with atrial fibrillation should be assessed for sleep apnea.

While the optimal strategy in evaluating for sleep apnea in these patients needs to be further defined, a multidisciplinary approach to care involving a primary care provider, cardiologist, and sleep specialist may be ideal.

References
  1. Braga B, Poyares D, Cintra F, et al. Sleep-disordered breathing and chronic atrial fibrillation. Sleep Med 2009; 10(2):212–216. doi:10.1016/j.sleep.2007.12.007
  2. Gami AS, Pressman G, Caples SM, et al. Association of atrial fibrillation and obstructive sleep apnea. Circulation 2004; 110(4):364–367. doi:10.1161/01.CIR.0000136587.68725.8E
  3. Stevenson IH, Teichtahl H, Cunnington D, Ciavarella S, Gordon I, Kalman JM. Prevalence of sleep disordered breathing in paroxysmal and persistent atrial fibrillation patients with normal left ventricular function. Eur Heart J 2008; 29(13):1662–1669. doi:10.1093/eurheartj/ehn214
  4. Mehra R, Benjamin EJ, Shahar E, et al. Association of nocturnal arrhythmias with sleep-disordered breathing: The Sleep Heart Health Study. Am J Respir Crit Care Med 2006; 173(8):910–916. doi:10.1164/rccm.200509-1442OC
  5. Cooper VL, Bowker CM, Pearson SB, Elliott MW, Hainsworth R. Effects of simulated obstructive sleep apnoea on the human carotid baroreceptor-vascular resistance reflex. J Physiol 2004; 557(pt 3):1055–1065. doi:10.1113/jphysiol.2004.062513
  6. Eckert DJ, Jordan AS, Merchia P, Malhotra A. Central sleep apnea: pathophysiology and treatment. Chest 2007; 131(2):595–607. doi:10.1378/chest.06.2287
  7. Lévy P, Pépin JL, Arnaud C, et al. Intermittent hypoxia and sleep-disordered breathing: current concepts and perspectives. Eur Respir J 2008; 32(4):1082–1095. doi:10.1183/09031936.00013308
  8. Stevenson IH, Roberts-Thomson KC, Kistler PM, et al. Atrial electrophysiology is altered by acute hypercapnia but not hypoxemia: implications for promotion of atrial fibrillation in pulmonary disease and sleep apnea. Heart Rhythm 2010; 7(9):1263–1270. doi:10.1016/j.hrthm.2010.03.020
  9. Tung P, Levitzky YS, Wang R, et al. Obstructive and central sleep apnea and the risk of incident atrial fibrillation in a community cohort of men and women. J Am Heart Assoc 2017; 6(7). doi:10.1161/JAHA.116.004500
  10. Iwasaki YK, Shi Y, Benito B, et al. Determinants of atrial fibrillation in an animal model of obesity and acute obstructive sleep apnea. Heart Rhythm 2012; 9(9):1409–1416.e1. doi:10.1016/j.hrthm.2012.03.024
  11. Monahan K, Storfer-Isser A, Mehra R, et al. Triggering of nocturnal arrhythmias by sleep-disordered breathing events. J Am Coll Cardiol 2009; 54(19):1797–1804. doi:10.1016/j.jacc.2009.06.038
  12. Kanagala R, Murali NS, Friedman PA, et al. Obstructive sleep apnea and the recurrence of atrial fibrillation. Circulation 2003; 107(20):2589–2594. doi:10.1161/01.CIR.0000068337.25994.21
  13. Ng CY, Liu T, Shehata M, Stevens S, Chugh SS, Wang X. Meta-analysis of obstructive sleep apnea as predictor of atrial fibrillation recurrence after catheter ablation. Am J Cardiol 2011; 108(1):47–51. doi:10.1016/j.amjcard.2011.02.343
  14. Naruse Y, Tada H, Satoh M, et al. Concomitant obstructive sleep apnea increases the recurrence of atrial fibrillation following radiofrequency catheter ablation of atrial fibrillation: clinical impact of continuous positive airway pressure therapy. Heart Rhythm 2013; 10(3):331–337. doi:10.1016/j.hrthm.2012.11.015
  15. Fein AS, Shvilkin A, Shah D, et al. Treatment of obstructive sleep apnea reduces the risk of atrial fibrillation recurrence after catheter ablation. J Am Coll Cardiol 2013; 62(4):300–305. doi:10.1016/j.jacc.2013.03.052
  16. Patel D, Mohanty P, Di Biase L, et al. Safety and efficacy of pulmonary vein antral isolation in patients with obstructive sleep apnea: the impact of continuous positive airway pressure. Circ Arrhythm Electrophysiol 2010; 3(5):445–451. doi:10.1161/CIRCEP.109.858381
  17. Neilan TG, Farhad H, Dodson JA, et al. Effect of sleep apnea and continuous positive airway pressure on cardiac structure and recurrence of atrial fibrillation. J Am Heart Assoc 2013; 2(6):e000421. doi:10.1161/JAHA.113.000421
  18. Mehra R, Stone KL, Varosy PD, et al. Nocturnal arrhythmias across a spectrum of obstructive and central sleep-disordered breathing in older men: outcomes of sleep disorders in older men (MrOS sleep) study. Arch Intern Med 2009; 169(12):1147–1155. doi:10.1001/archinternmed.2009.138
  19. Sin DD, Fitzgerald F, Parker JD, Newton G, Floras JS, Bradley TD. Risk factors for central and obstructive sleep apnea in 450 men and women with congestive heart failure. Am J Respir Crit Care Med 1999; 160(4):1101–1106. doi:10.1164/ajrccm.160.4.9903020
  20. Yumino D, Wang H, Floras JS, et al. Prevalence and physiological predictors of sleep apnea in patients with heart failure and systolic dysfunction. J Card Fail 2009; 15(4):279–285. doi:10.1016/j.cardfail.2008.11.015
  21. May AM, Blackwell T, Stone PH, et al; MrOS Sleep (Outcomes of Sleep Disorders in Older Men) Study Group. Central sleep-disordered breathing predicts incident atrial fibrillation in older men. Am J Respir Crit Care Med 2016; 193(7):783–791. doi:10.1164/rccm.201508-1523OC
  22. Porthan KM, Melin JH, Kupila JT, Venho KK, Partinen MM. Prevalence of sleep apnea syndrome in lone atrial fibrillation: a case-control study. Chest 2004; 125(3):879–885. doi:10.1378/chest.125.3.879
  23. January CT, Wann LS, Alpert JS, et al; ACC/AHA Task Force Members. 2014 AHA/ACC/HRS guideline for the management of patients with atrial fibrillation: a report of the American College of Cardiology/American Heart Association Task Force on practice guidelines and the Heart Rhythm Society. Circulation 2014; 130(23):e199–e267. doi:10.1161/CIR.0000000000000041
  24. Writing Group Members; January CT, Wann LS, Calkins H, et al. 2019 AHA/ACC/HRS focused update of the 2014 AHA/ACC/HRS guideline for the management of patients with atrial fibrillation: a report of the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines and the Heart Rhythm Society. Heart Rhythm. 2019; 16(8):e66–e93. doi:10.1016/j.hrthm.2019.01.024
  25. Netzer NC, Stoohs RA, Netzer CM, Clark K, Strohl KP. Using the Berlin Questionnaire to identify patients at risk for the sleep apnea syndrome. Ann Intern Med 1999; 131(7):485–491. doi:10.7326/0003-4819-131-7-199910050-00002
  26. Chung F, Abdullah HR, Liao P. STOP-bang questionnaire a practical approach to screen for obstructive sleep apnea. Chest 2016; 149(3):631–638. doi:10.1378/chest.15-0903
  27. Marti-Soler H, Hirotsu C, Marques-Vidal P, et al. The NoSAS score for screening of sleep-disordered breathing: a derivation and validation study. Lancet Respir Med 2016; 4(9):742–748. doi:10.1016/S2213-2600(16)30075-3
  28. Kapur VK, Auckley DH, Chowdhuri S, et al. Clinical practice guideline for diagnostic testing for adult obstructive sleep apnea: an American Academy of Sleep Medicine clinical practice guideline. J Clin Sleep Med 2017; 13(3):479–504. doi:10.5664/jcsm.6506
References
  1. Braga B, Poyares D, Cintra F, et al. Sleep-disordered breathing and chronic atrial fibrillation. Sleep Med 2009; 10(2):212–216. doi:10.1016/j.sleep.2007.12.007
  2. Gami AS, Pressman G, Caples SM, et al. Association of atrial fibrillation and obstructive sleep apnea. Circulation 2004; 110(4):364–367. doi:10.1161/01.CIR.0000136587.68725.8E
  3. Stevenson IH, Teichtahl H, Cunnington D, Ciavarella S, Gordon I, Kalman JM. Prevalence of sleep disordered breathing in paroxysmal and persistent atrial fibrillation patients with normal left ventricular function. Eur Heart J 2008; 29(13):1662–1669. doi:10.1093/eurheartj/ehn214
  4. Mehra R, Benjamin EJ, Shahar E, et al. Association of nocturnal arrhythmias with sleep-disordered breathing: The Sleep Heart Health Study. Am J Respir Crit Care Med 2006; 173(8):910–916. doi:10.1164/rccm.200509-1442OC
  5. Cooper VL, Bowker CM, Pearson SB, Elliott MW, Hainsworth R. Effects of simulated obstructive sleep apnoea on the human carotid baroreceptor-vascular resistance reflex. J Physiol 2004; 557(pt 3):1055–1065. doi:10.1113/jphysiol.2004.062513
  6. Eckert DJ, Jordan AS, Merchia P, Malhotra A. Central sleep apnea: pathophysiology and treatment. Chest 2007; 131(2):595–607. doi:10.1378/chest.06.2287
  7. Lévy P, Pépin JL, Arnaud C, et al. Intermittent hypoxia and sleep-disordered breathing: current concepts and perspectives. Eur Respir J 2008; 32(4):1082–1095. doi:10.1183/09031936.00013308
  8. Stevenson IH, Roberts-Thomson KC, Kistler PM, et al. Atrial electrophysiology is altered by acute hypercapnia but not hypoxemia: implications for promotion of atrial fibrillation in pulmonary disease and sleep apnea. Heart Rhythm 2010; 7(9):1263–1270. doi:10.1016/j.hrthm.2010.03.020
  9. Tung P, Levitzky YS, Wang R, et al. Obstructive and central sleep apnea and the risk of incident atrial fibrillation in a community cohort of men and women. J Am Heart Assoc 2017; 6(7). doi:10.1161/JAHA.116.004500
  10. Iwasaki YK, Shi Y, Benito B, et al. Determinants of atrial fibrillation in an animal model of obesity and acute obstructive sleep apnea. Heart Rhythm 2012; 9(9):1409–1416.e1. doi:10.1016/j.hrthm.2012.03.024
  11. Monahan K, Storfer-Isser A, Mehra R, et al. Triggering of nocturnal arrhythmias by sleep-disordered breathing events. J Am Coll Cardiol 2009; 54(19):1797–1804. doi:10.1016/j.jacc.2009.06.038
  12. Kanagala R, Murali NS, Friedman PA, et al. Obstructive sleep apnea and the recurrence of atrial fibrillation. Circulation 2003; 107(20):2589–2594. doi:10.1161/01.CIR.0000068337.25994.21
  13. Ng CY, Liu T, Shehata M, Stevens S, Chugh SS, Wang X. Meta-analysis of obstructive sleep apnea as predictor of atrial fibrillation recurrence after catheter ablation. Am J Cardiol 2011; 108(1):47–51. doi:10.1016/j.amjcard.2011.02.343
  14. Naruse Y, Tada H, Satoh M, et al. Concomitant obstructive sleep apnea increases the recurrence of atrial fibrillation following radiofrequency catheter ablation of atrial fibrillation: clinical impact of continuous positive airway pressure therapy. Heart Rhythm 2013; 10(3):331–337. doi:10.1016/j.hrthm.2012.11.015
  15. Fein AS, Shvilkin A, Shah D, et al. Treatment of obstructive sleep apnea reduces the risk of atrial fibrillation recurrence after catheter ablation. J Am Coll Cardiol 2013; 62(4):300–305. doi:10.1016/j.jacc.2013.03.052
  16. Patel D, Mohanty P, Di Biase L, et al. Safety and efficacy of pulmonary vein antral isolation in patients with obstructive sleep apnea: the impact of continuous positive airway pressure. Circ Arrhythm Electrophysiol 2010; 3(5):445–451. doi:10.1161/CIRCEP.109.858381
  17. Neilan TG, Farhad H, Dodson JA, et al. Effect of sleep apnea and continuous positive airway pressure on cardiac structure and recurrence of atrial fibrillation. J Am Heart Assoc 2013; 2(6):e000421. doi:10.1161/JAHA.113.000421
  18. Mehra R, Stone KL, Varosy PD, et al. Nocturnal arrhythmias across a spectrum of obstructive and central sleep-disordered breathing in older men: outcomes of sleep disorders in older men (MrOS sleep) study. Arch Intern Med 2009; 169(12):1147–1155. doi:10.1001/archinternmed.2009.138
  19. Sin DD, Fitzgerald F, Parker JD, Newton G, Floras JS, Bradley TD. Risk factors for central and obstructive sleep apnea in 450 men and women with congestive heart failure. Am J Respir Crit Care Med 1999; 160(4):1101–1106. doi:10.1164/ajrccm.160.4.9903020
  20. Yumino D, Wang H, Floras JS, et al. Prevalence and physiological predictors of sleep apnea in patients with heart failure and systolic dysfunction. J Card Fail 2009; 15(4):279–285. doi:10.1016/j.cardfail.2008.11.015
  21. May AM, Blackwell T, Stone PH, et al; MrOS Sleep (Outcomes of Sleep Disorders in Older Men) Study Group. Central sleep-disordered breathing predicts incident atrial fibrillation in older men. Am J Respir Crit Care Med 2016; 193(7):783–791. doi:10.1164/rccm.201508-1523OC
  22. Porthan KM, Melin JH, Kupila JT, Venho KK, Partinen MM. Prevalence of sleep apnea syndrome in lone atrial fibrillation: a case-control study. Chest 2004; 125(3):879–885. doi:10.1378/chest.125.3.879
  23. January CT, Wann LS, Alpert JS, et al; ACC/AHA Task Force Members. 2014 AHA/ACC/HRS guideline for the management of patients with atrial fibrillation: a report of the American College of Cardiology/American Heart Association Task Force on practice guidelines and the Heart Rhythm Society. Circulation 2014; 130(23):e199–e267. doi:10.1161/CIR.0000000000000041
  24. Writing Group Members; January CT, Wann LS, Calkins H, et al. 2019 AHA/ACC/HRS focused update of the 2014 AHA/ACC/HRS guideline for the management of patients with atrial fibrillation: a report of the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines and the Heart Rhythm Society. Heart Rhythm. 2019; 16(8):e66–e93. doi:10.1016/j.hrthm.2019.01.024
  25. Netzer NC, Stoohs RA, Netzer CM, Clark K, Strohl KP. Using the Berlin Questionnaire to identify patients at risk for the sleep apnea syndrome. Ann Intern Med 1999; 131(7):485–491. doi:10.7326/0003-4819-131-7-199910050-00002
  26. Chung F, Abdullah HR, Liao P. STOP-bang questionnaire a practical approach to screen for obstructive sleep apnea. Chest 2016; 149(3):631–638. doi:10.1378/chest.15-0903
  27. Marti-Soler H, Hirotsu C, Marques-Vidal P, et al. The NoSAS score for screening of sleep-disordered breathing: a derivation and validation study. Lancet Respir Med 2016; 4(9):742–748. doi:10.1016/S2213-2600(16)30075-3
  28. Kapur VK, Auckley DH, Chowdhuri S, et al. Clinical practice guideline for diagnostic testing for adult obstructive sleep apnea: an American Academy of Sleep Medicine clinical practice guideline. J Clin Sleep Med 2017; 13(3):479–504. doi:10.5664/jcsm.6506
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What are the risks to inpatients during hospital construction or renovation?

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What are the risks to inpatients during hospital construction or renovation?

Hospital-acquired infections related to construction and renovation activities account for more than 5,000 deaths per year across the United States.1

Hospital construction, renovation, and demolition projects ultimately serve the interests of patients, but they also can put inpatients at risk of mold infection, Legionnaires disease, sleep deprivation, exacerbation of lung disease, and in rare cases, physical injury.

Hospitals are in a continuous state of transformation to meet the needs of medical and technologic advances and an increasing patient population,1 and in the last 10 years, more than $200 billion has been spent on construction projects at US healthcare facilities. Therefore, constant attention is needed to reduce the risks to the health of hospitalized patients during these projects.

HOSPITAL-ACQUIRED INFECTIONS

Mold infections

Construction can cause substantial dust contamination and scatter large amounts of fungal spores. An analysis conducted during a period of excavation at a hospital campus showed a significant association between excavation activities and hospital-acquired mold infections (hazard ratio [HR] 2.8, P = .01) but not yeast infections (HR 0.75, P = .78).2

Aspergillus species have been the organisms most commonly involved in hospital-acquired mold infection. In a review of 53 studies including 458 patients,3A fumigatus was identified in 154 patients, and A flavus was identified in 101 patients. A niger, A terreus, A nidulans, Zygomycetes, and other fungi were also identified, but to a much lesser extent. Hematologic malignancies were the predominant underlying morbidity in 299 patients. Half of the sources of healthcare-associated Aspergillus outbreaks were estimated to result from construction and renovation activities within or surrounding the hospital.3

Heavy demolition and transportation of wreckage have been found to cause the greatest concentrations of Aspergillus species,1 but even small concentrations may be sufficient to cause infection in high-risk hospitalized patients.3 Invasive pulmonary aspergillosis is the mold infection most commonly associated with these activities, particularly in immunocompromised and critically ill patients. It is characterized by invasion of lung tissue by Aspergillus hyphae. Hematogenous dissemination occurs in about 25% of patients, and the death rate often exceeds 50%.4

A review of cases of fungal infection during hospital construction, renovation, and demolition projects from 1976 to 2014 identified 372 infected patients, of whom 180 died.5 The majority of infections were due to Aspergillus. Other fungi included Rhizopus, Candida, and Fusarium. Infections occurred mainly in patients with hematologic malignancies and patients who had undergone stem cell transplant (76%), followed by patients with other malignancies or transplant (19%). Rarely affected were patients in the intensive care unit or patients with rheumatologic diseases or on hemodialysis.5

Legionnaires disease

Legionnaires disease is a form of atypical pneumonia caused by the bacterium Legionella, often associated with differing degrees of gastrointestinal symptoms. Legionella species are the bacteria most often associated with construction in hospitals, as construction and demolition often result in collections of stagnant water.

The primary mode of transmission is inhalation of contaminated mist or aerosols. Legionella species can also colonize newly constructed hospital buildings within weeks of installation of water fixtures.

In a large university-affiliated hospital, 2 cases of nosocomial legionellosis were identified during a period of major construction.6 An epidemiologic investigation traced the source to a widespread contamination of potable water within the hospital. One patient’s isolate was similar to that of a water sample from the faucet in his room, and an association between Legionnaires disease and construction was postulated.

Another institution’s newly constructed hematology-oncology unit identified 10 cases of Legionnaires disease over a 12-week period in patients and visitors with exposure to the unit during and within the incubation period.7 A clinical and environmental assessment found 3 clinical isolates of Legionella identical to environmental isolates found from the unit, strongly implicating the potable water system as the likely source.7

In Ohio, 11 cases of hospital-acquired Legionnaires disease were identified in patients moved to a newly constructed 12-story addition to a hospital, and 1 of those died.8

Legionella infections appear to be less common than mold infections when reviewing the available literature on patients exposed to hospital construction, renovation, or demolition activities. Yet unlike mold infections, which occur mostly in immunocompromised patients, Legionella also affects people with normal immunity.1

 

 

NONCOMMUNICABLE ILLNESSES

Sleep deprivation

Noise in hospitals has been linked to sleep disturbances in inpatients. A study using noise dosimeters in a university hospital found a mean continuous noise level of 63.5 dBA (A-weighting of decibels indicates risk of hearing loss) over a 24-hour period, a level more than 2 times higher than the recommended 30 dBA.9 The same study also found a significant correlation between sleep disturbance in inpatients and increasing noise levels, in a dose-response manner.

Common sources of noise during construction may include power generators, welding and cutting equipment, and transport of materials. While construction activities themselves have yet to be directly linked to sleep deprivation in patients, construction is inevitably accompanied by noise.

Noise is the most common factor interfering with sleep reported by hospitalized patients. Other effects of noise on patients include a rise in heart rate and blood pressure, increased cholesterol and triglyceride levels, increased use of sedatives, and longer length of stay.9,10 Although construction is rarely done at night, patients generally take naps during the day, so the noise is disruptive.

Physical injuries

Hospitalized patients rarely suffer injuries related to hospital construction. However, these incidents may be underreported. Few cases of physical injury in patients exposed to construction or renovation in healthcare facilities can be found through a Web search.11,12

Exacerbation of lung disease

Inhalation of indoor air pollutants exposed during renovation can directly trigger an inflammatory response and cause exacerbation in patients with chronic lung diseases such as asthma and chronic obstructive pulmonary disease. No study has specifically examined the effect of hospital construction or renovation on exacerbation of chronic lung diseases in hospitalized patients. Nevertheless, dust and indoor air pollutants from building renovation have often been reported as agents associated with work-related asthma.13

THE MESSAGE

Although the risks to inpatients during hospital construction projects appear minimal, their effect can at times be detrimental, especially to the immunocompromised. Hospitals should adhere to infection control risk assessment protocols during construction events. The small number of outbreaks of construction-related infections can make the diagnosis of nosocomial origin of these infections challenging; a high index of suspicion is needed.

Currently in the United States, there is no standard regarding acceptable levels of airborne mold concentrations, and data to support routine hospital air sampling or validation of available air samplers are inadequate. This remains an area for future research.14,15

Certain measures have been shown to significantly decrease the risk of mold infections and other nosocomial infections during construction projects, including16:

  • Effective dust control through containment units and barriers
  • Consistent use of high-efficiency particulate air filters in hospital units that care for immunocompromised and critically ill patients
  • Routine surveillance.

Noise and vibration can be reduced by temporary walls and careful tool selection and scheduling. Similarly, temporary walls and other barriers help protect healthcare employees and patients from the risk of direct physical injury.

Preconstruction risk assessments that address infection control, safety, noise, and air quality are crucial, and the Joint Commission generally requires such assessments. Further, education of hospital staff and members of the construction team about the potential detrimental effects of hospital construction and renovation is essential to secure a safe environment.        

References
  1. Clair JD, Colatrella S. Opening Pandora’s (tool) box: health care construction and associated risk for nosocomial infection. Infect Disord Drug Targets 2013; 13(3):177–183. pmid:23961740
  2. Pokala HR, Leonard D, Cox J, et al. Association of hospital construction with the development of healthcare associated environmental mold infections (HAEMI) in pediatric patients with leukemia. Pediatr Blood Cancer 2014; 61(2):276–280. doi:10.1002/pbc.24685
  3. Vonberg RP, Gastmeier P. Nosocomial aspergillosis in outbreak settings. J Hosp Infect 2006; 63(3):246–254. doi:10.1016/j.jhin.2006.02.014
  4. Kanj A, Abdallah N, Soubani AO. The spectrum of pulmonary aspergillosis. Respir Med 2018; 141:121–131. doi:10.1016/j.rmed.2018.06.029
  5. Kanamori H, Rutala WA, Sickbert-Bennett EE, Weber DJ. Review of fungal outbreaks and infection prevention in healthcare settings during construction and renovation. Clin Infect Dis 2015; 61(3):433–444. doi:10.1093/cid/civ297
  6. Perola O, Kauppinen J, Kusnetsov J, Heikkinen J, Jokinen C, Katila ML. Nosocomial Legionella pneumophila serogroup 5 outbreak associated with persistent colonization of a hospital water system. APMIS 2002; 110(12):863–868. pmid:12645664
  7. Francois Watkins LK, Toews KE, Harris AM, et al. Lessons from an outbreak of Legionnaires disease on a hematology-oncology unit. Infect Control Hosp Epidemiol 2017; 38(3):306–313. doi:10.1017/ice.2016.281
  8. Lin YE, Stout JE, Yu VL. Prevention of hospital-acquired legionellosis. Curr Opin Infect Dis 2011; 24(4):350–356. doi:10.1097/QCO.0b013e3283486c6e
  9. Park MJ, Yoo JH, Cho BW, Kim KT, Jeong WC, Ha M. Noise in hospital rooms and sleep disturbance in hospitalized medical patients. Environ Health Toxicol 2014; 29:e2014006. doi:10.5620/eht.2014.29.e2014006
  10. Buxton OM, Ellenbogen JM, Wang W, et al. Sleep disruption due to hospital noises: a prospective evaluation. Ann Intern Med 2012; 157(3):170–179. doi:10.7326/0003-4819-157-3-201208070-00472
  11. Heldt D; The Gazette. Accident will delay University of Iowa Hospitals construction work for several days. www.thegazette.com/2013/03/08/university-of-iowa-hospitals-patient-injured-by-falling-construction-debris. Accessed July 22, 2019.
  12. Darrah N; Fox News. Texas hospital explosion kills 1, leaves 12 injured. www.foxnews.com/us/texas-hospital-explosion-kills-1-leaves-12-injured. Accessed July 22, 2019.
  13. Centers for Disease Control and Prevention (CDC). Work-related asthma: most frequently reported agents associated with work-related asthma cases by state, 2009–2012. wwwn.cdc.gov/eworld/Data/926. Accessed July 22, 2019.
  14. Patterson TF, Thompson GR 3rd, Denning DW, et al. Practice guidelines for the diagnosis and management of Aspergillosis: 2016 update by the Infectious Diseases Society of America. Clin Infect Dis 2016; 63(4):e1–e60. doi:10.1093/cid/ciw326
  15. Chang CC, Athan E, Morrissey CO, Slavin MA. Preventing invasive fungal infection during hospital building works. Intern Med J 2008; 38(6b):538–541. doi:10.1111/j.1445-5994.2008.01727.x
  16. Oren I, Haddad N, Finkelstein R, Rowe JM. Invasive pulmonary aspergillosis in neutropenic patients during hospital construction: before and after chemoprophylaxis and institution of HEPA filters. Am J Hematol 2001; 66(4):257–262. doi:10.1002/ajh.1054
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Amjad Kanj, MD
Department of Medicine, Wayne State University School of Medicine, Detroit, MI

Yuqing Gao, MD
Department of Medicine, Wayne State University School of Medicine, Detroit, MI

Ayman O. Soubani, MD
Division of Pulmonary, Critical Care, and Sleep Medicine, Wayne State University School of Medicine; Professor of Medicine, Wayne State University School of Medicine; Medical Director, Medical ICU, Harper University Hospital; Service Chief, Pulmonary and Critical Care, and Medical Director, Critical Care Service, Karmanos Cancer Center, Detroit, MI

Address: Ayman O. Soubani, MD, Wayne State University School of Medicine, 3990 John R-3 Hudson, Detroit, MI 48201; [email protected]

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Ayman O. Soubani, MD
Division of Pulmonary, Critical Care, and Sleep Medicine, Wayne State University School of Medicine; Professor of Medicine, Wayne State University School of Medicine; Medical Director, Medical ICU, Harper University Hospital; Service Chief, Pulmonary and Critical Care, and Medical Director, Critical Care Service, Karmanos Cancer Center, Detroit, MI

Address: Ayman O. Soubani, MD, Wayne State University School of Medicine, 3990 John R-3 Hudson, Detroit, MI 48201; [email protected]

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Department of Medicine, Wayne State University School of Medicine, Detroit, MI

Yuqing Gao, MD
Department of Medicine, Wayne State University School of Medicine, Detroit, MI

Ayman O. Soubani, MD
Division of Pulmonary, Critical Care, and Sleep Medicine, Wayne State University School of Medicine; Professor of Medicine, Wayne State University School of Medicine; Medical Director, Medical ICU, Harper University Hospital; Service Chief, Pulmonary and Critical Care, and Medical Director, Critical Care Service, Karmanos Cancer Center, Detroit, MI

Address: Ayman O. Soubani, MD, Wayne State University School of Medicine, 3990 John R-3 Hudson, Detroit, MI 48201; [email protected]

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Related Articles

Hospital-acquired infections related to construction and renovation activities account for more than 5,000 deaths per year across the United States.1

Hospital construction, renovation, and demolition projects ultimately serve the interests of patients, but they also can put inpatients at risk of mold infection, Legionnaires disease, sleep deprivation, exacerbation of lung disease, and in rare cases, physical injury.

Hospitals are in a continuous state of transformation to meet the needs of medical and technologic advances and an increasing patient population,1 and in the last 10 years, more than $200 billion has been spent on construction projects at US healthcare facilities. Therefore, constant attention is needed to reduce the risks to the health of hospitalized patients during these projects.

HOSPITAL-ACQUIRED INFECTIONS

Mold infections

Construction can cause substantial dust contamination and scatter large amounts of fungal spores. An analysis conducted during a period of excavation at a hospital campus showed a significant association between excavation activities and hospital-acquired mold infections (hazard ratio [HR] 2.8, P = .01) but not yeast infections (HR 0.75, P = .78).2

Aspergillus species have been the organisms most commonly involved in hospital-acquired mold infection. In a review of 53 studies including 458 patients,3A fumigatus was identified in 154 patients, and A flavus was identified in 101 patients. A niger, A terreus, A nidulans, Zygomycetes, and other fungi were also identified, but to a much lesser extent. Hematologic malignancies were the predominant underlying morbidity in 299 patients. Half of the sources of healthcare-associated Aspergillus outbreaks were estimated to result from construction and renovation activities within or surrounding the hospital.3

Heavy demolition and transportation of wreckage have been found to cause the greatest concentrations of Aspergillus species,1 but even small concentrations may be sufficient to cause infection in high-risk hospitalized patients.3 Invasive pulmonary aspergillosis is the mold infection most commonly associated with these activities, particularly in immunocompromised and critically ill patients. It is characterized by invasion of lung tissue by Aspergillus hyphae. Hematogenous dissemination occurs in about 25% of patients, and the death rate often exceeds 50%.4

A review of cases of fungal infection during hospital construction, renovation, and demolition projects from 1976 to 2014 identified 372 infected patients, of whom 180 died.5 The majority of infections were due to Aspergillus. Other fungi included Rhizopus, Candida, and Fusarium. Infections occurred mainly in patients with hematologic malignancies and patients who had undergone stem cell transplant (76%), followed by patients with other malignancies or transplant (19%). Rarely affected were patients in the intensive care unit or patients with rheumatologic diseases or on hemodialysis.5

Legionnaires disease

Legionnaires disease is a form of atypical pneumonia caused by the bacterium Legionella, often associated with differing degrees of gastrointestinal symptoms. Legionella species are the bacteria most often associated with construction in hospitals, as construction and demolition often result in collections of stagnant water.

The primary mode of transmission is inhalation of contaminated mist or aerosols. Legionella species can also colonize newly constructed hospital buildings within weeks of installation of water fixtures.

In a large university-affiliated hospital, 2 cases of nosocomial legionellosis were identified during a period of major construction.6 An epidemiologic investigation traced the source to a widespread contamination of potable water within the hospital. One patient’s isolate was similar to that of a water sample from the faucet in his room, and an association between Legionnaires disease and construction was postulated.

Another institution’s newly constructed hematology-oncology unit identified 10 cases of Legionnaires disease over a 12-week period in patients and visitors with exposure to the unit during and within the incubation period.7 A clinical and environmental assessment found 3 clinical isolates of Legionella identical to environmental isolates found from the unit, strongly implicating the potable water system as the likely source.7

In Ohio, 11 cases of hospital-acquired Legionnaires disease were identified in patients moved to a newly constructed 12-story addition to a hospital, and 1 of those died.8

Legionella infections appear to be less common than mold infections when reviewing the available literature on patients exposed to hospital construction, renovation, or demolition activities. Yet unlike mold infections, which occur mostly in immunocompromised patients, Legionella also affects people with normal immunity.1

 

 

NONCOMMUNICABLE ILLNESSES

Sleep deprivation

Noise in hospitals has been linked to sleep disturbances in inpatients. A study using noise dosimeters in a university hospital found a mean continuous noise level of 63.5 dBA (A-weighting of decibels indicates risk of hearing loss) over a 24-hour period, a level more than 2 times higher than the recommended 30 dBA.9 The same study also found a significant correlation between sleep disturbance in inpatients and increasing noise levels, in a dose-response manner.

Common sources of noise during construction may include power generators, welding and cutting equipment, and transport of materials. While construction activities themselves have yet to be directly linked to sleep deprivation in patients, construction is inevitably accompanied by noise.

Noise is the most common factor interfering with sleep reported by hospitalized patients. Other effects of noise on patients include a rise in heart rate and blood pressure, increased cholesterol and triglyceride levels, increased use of sedatives, and longer length of stay.9,10 Although construction is rarely done at night, patients generally take naps during the day, so the noise is disruptive.

Physical injuries

Hospitalized patients rarely suffer injuries related to hospital construction. However, these incidents may be underreported. Few cases of physical injury in patients exposed to construction or renovation in healthcare facilities can be found through a Web search.11,12

Exacerbation of lung disease

Inhalation of indoor air pollutants exposed during renovation can directly trigger an inflammatory response and cause exacerbation in patients with chronic lung diseases such as asthma and chronic obstructive pulmonary disease. No study has specifically examined the effect of hospital construction or renovation on exacerbation of chronic lung diseases in hospitalized patients. Nevertheless, dust and indoor air pollutants from building renovation have often been reported as agents associated with work-related asthma.13

THE MESSAGE

Although the risks to inpatients during hospital construction projects appear minimal, their effect can at times be detrimental, especially to the immunocompromised. Hospitals should adhere to infection control risk assessment protocols during construction events. The small number of outbreaks of construction-related infections can make the diagnosis of nosocomial origin of these infections challenging; a high index of suspicion is needed.

Currently in the United States, there is no standard regarding acceptable levels of airborne mold concentrations, and data to support routine hospital air sampling or validation of available air samplers are inadequate. This remains an area for future research.14,15

Certain measures have been shown to significantly decrease the risk of mold infections and other nosocomial infections during construction projects, including16:

  • Effective dust control through containment units and barriers
  • Consistent use of high-efficiency particulate air filters in hospital units that care for immunocompromised and critically ill patients
  • Routine surveillance.

Noise and vibration can be reduced by temporary walls and careful tool selection and scheduling. Similarly, temporary walls and other barriers help protect healthcare employees and patients from the risk of direct physical injury.

Preconstruction risk assessments that address infection control, safety, noise, and air quality are crucial, and the Joint Commission generally requires such assessments. Further, education of hospital staff and members of the construction team about the potential detrimental effects of hospital construction and renovation is essential to secure a safe environment.        

Hospital-acquired infections related to construction and renovation activities account for more than 5,000 deaths per year across the United States.1

Hospital construction, renovation, and demolition projects ultimately serve the interests of patients, but they also can put inpatients at risk of mold infection, Legionnaires disease, sleep deprivation, exacerbation of lung disease, and in rare cases, physical injury.

Hospitals are in a continuous state of transformation to meet the needs of medical and technologic advances and an increasing patient population,1 and in the last 10 years, more than $200 billion has been spent on construction projects at US healthcare facilities. Therefore, constant attention is needed to reduce the risks to the health of hospitalized patients during these projects.

HOSPITAL-ACQUIRED INFECTIONS

Mold infections

Construction can cause substantial dust contamination and scatter large amounts of fungal spores. An analysis conducted during a period of excavation at a hospital campus showed a significant association between excavation activities and hospital-acquired mold infections (hazard ratio [HR] 2.8, P = .01) but not yeast infections (HR 0.75, P = .78).2

Aspergillus species have been the organisms most commonly involved in hospital-acquired mold infection. In a review of 53 studies including 458 patients,3A fumigatus was identified in 154 patients, and A flavus was identified in 101 patients. A niger, A terreus, A nidulans, Zygomycetes, and other fungi were also identified, but to a much lesser extent. Hematologic malignancies were the predominant underlying morbidity in 299 patients. Half of the sources of healthcare-associated Aspergillus outbreaks were estimated to result from construction and renovation activities within or surrounding the hospital.3

Heavy demolition and transportation of wreckage have been found to cause the greatest concentrations of Aspergillus species,1 but even small concentrations may be sufficient to cause infection in high-risk hospitalized patients.3 Invasive pulmonary aspergillosis is the mold infection most commonly associated with these activities, particularly in immunocompromised and critically ill patients. It is characterized by invasion of lung tissue by Aspergillus hyphae. Hematogenous dissemination occurs in about 25% of patients, and the death rate often exceeds 50%.4

A review of cases of fungal infection during hospital construction, renovation, and demolition projects from 1976 to 2014 identified 372 infected patients, of whom 180 died.5 The majority of infections were due to Aspergillus. Other fungi included Rhizopus, Candida, and Fusarium. Infections occurred mainly in patients with hematologic malignancies and patients who had undergone stem cell transplant (76%), followed by patients with other malignancies or transplant (19%). Rarely affected were patients in the intensive care unit or patients with rheumatologic diseases or on hemodialysis.5

Legionnaires disease

Legionnaires disease is a form of atypical pneumonia caused by the bacterium Legionella, often associated with differing degrees of gastrointestinal symptoms. Legionella species are the bacteria most often associated with construction in hospitals, as construction and demolition often result in collections of stagnant water.

The primary mode of transmission is inhalation of contaminated mist or aerosols. Legionella species can also colonize newly constructed hospital buildings within weeks of installation of water fixtures.

In a large university-affiliated hospital, 2 cases of nosocomial legionellosis were identified during a period of major construction.6 An epidemiologic investigation traced the source to a widespread contamination of potable water within the hospital. One patient’s isolate was similar to that of a water sample from the faucet in his room, and an association between Legionnaires disease and construction was postulated.

Another institution’s newly constructed hematology-oncology unit identified 10 cases of Legionnaires disease over a 12-week period in patients and visitors with exposure to the unit during and within the incubation period.7 A clinical and environmental assessment found 3 clinical isolates of Legionella identical to environmental isolates found from the unit, strongly implicating the potable water system as the likely source.7

In Ohio, 11 cases of hospital-acquired Legionnaires disease were identified in patients moved to a newly constructed 12-story addition to a hospital, and 1 of those died.8

Legionella infections appear to be less common than mold infections when reviewing the available literature on patients exposed to hospital construction, renovation, or demolition activities. Yet unlike mold infections, which occur mostly in immunocompromised patients, Legionella also affects people with normal immunity.1

 

 

NONCOMMUNICABLE ILLNESSES

Sleep deprivation

Noise in hospitals has been linked to sleep disturbances in inpatients. A study using noise dosimeters in a university hospital found a mean continuous noise level of 63.5 dBA (A-weighting of decibels indicates risk of hearing loss) over a 24-hour period, a level more than 2 times higher than the recommended 30 dBA.9 The same study also found a significant correlation between sleep disturbance in inpatients and increasing noise levels, in a dose-response manner.

Common sources of noise during construction may include power generators, welding and cutting equipment, and transport of materials. While construction activities themselves have yet to be directly linked to sleep deprivation in patients, construction is inevitably accompanied by noise.

Noise is the most common factor interfering with sleep reported by hospitalized patients. Other effects of noise on patients include a rise in heart rate and blood pressure, increased cholesterol and triglyceride levels, increased use of sedatives, and longer length of stay.9,10 Although construction is rarely done at night, patients generally take naps during the day, so the noise is disruptive.

Physical injuries

Hospitalized patients rarely suffer injuries related to hospital construction. However, these incidents may be underreported. Few cases of physical injury in patients exposed to construction or renovation in healthcare facilities can be found through a Web search.11,12

Exacerbation of lung disease

Inhalation of indoor air pollutants exposed during renovation can directly trigger an inflammatory response and cause exacerbation in patients with chronic lung diseases such as asthma and chronic obstructive pulmonary disease. No study has specifically examined the effect of hospital construction or renovation on exacerbation of chronic lung diseases in hospitalized patients. Nevertheless, dust and indoor air pollutants from building renovation have often been reported as agents associated with work-related asthma.13

THE MESSAGE

Although the risks to inpatients during hospital construction projects appear minimal, their effect can at times be detrimental, especially to the immunocompromised. Hospitals should adhere to infection control risk assessment protocols during construction events. The small number of outbreaks of construction-related infections can make the diagnosis of nosocomial origin of these infections challenging; a high index of suspicion is needed.

Currently in the United States, there is no standard regarding acceptable levels of airborne mold concentrations, and data to support routine hospital air sampling or validation of available air samplers are inadequate. This remains an area for future research.14,15

Certain measures have been shown to significantly decrease the risk of mold infections and other nosocomial infections during construction projects, including16:

  • Effective dust control through containment units and barriers
  • Consistent use of high-efficiency particulate air filters in hospital units that care for immunocompromised and critically ill patients
  • Routine surveillance.

Noise and vibration can be reduced by temporary walls and careful tool selection and scheduling. Similarly, temporary walls and other barriers help protect healthcare employees and patients from the risk of direct physical injury.

Preconstruction risk assessments that address infection control, safety, noise, and air quality are crucial, and the Joint Commission generally requires such assessments. Further, education of hospital staff and members of the construction team about the potential detrimental effects of hospital construction and renovation is essential to secure a safe environment.        

References
  1. Clair JD, Colatrella S. Opening Pandora’s (tool) box: health care construction and associated risk for nosocomial infection. Infect Disord Drug Targets 2013; 13(3):177–183. pmid:23961740
  2. Pokala HR, Leonard D, Cox J, et al. Association of hospital construction with the development of healthcare associated environmental mold infections (HAEMI) in pediatric patients with leukemia. Pediatr Blood Cancer 2014; 61(2):276–280. doi:10.1002/pbc.24685
  3. Vonberg RP, Gastmeier P. Nosocomial aspergillosis in outbreak settings. J Hosp Infect 2006; 63(3):246–254. doi:10.1016/j.jhin.2006.02.014
  4. Kanj A, Abdallah N, Soubani AO. The spectrum of pulmonary aspergillosis. Respir Med 2018; 141:121–131. doi:10.1016/j.rmed.2018.06.029
  5. Kanamori H, Rutala WA, Sickbert-Bennett EE, Weber DJ. Review of fungal outbreaks and infection prevention in healthcare settings during construction and renovation. Clin Infect Dis 2015; 61(3):433–444. doi:10.1093/cid/civ297
  6. Perola O, Kauppinen J, Kusnetsov J, Heikkinen J, Jokinen C, Katila ML. Nosocomial Legionella pneumophila serogroup 5 outbreak associated with persistent colonization of a hospital water system. APMIS 2002; 110(12):863–868. pmid:12645664
  7. Francois Watkins LK, Toews KE, Harris AM, et al. Lessons from an outbreak of Legionnaires disease on a hematology-oncology unit. Infect Control Hosp Epidemiol 2017; 38(3):306–313. doi:10.1017/ice.2016.281
  8. Lin YE, Stout JE, Yu VL. Prevention of hospital-acquired legionellosis. Curr Opin Infect Dis 2011; 24(4):350–356. doi:10.1097/QCO.0b013e3283486c6e
  9. Park MJ, Yoo JH, Cho BW, Kim KT, Jeong WC, Ha M. Noise in hospital rooms and sleep disturbance in hospitalized medical patients. Environ Health Toxicol 2014; 29:e2014006. doi:10.5620/eht.2014.29.e2014006
  10. Buxton OM, Ellenbogen JM, Wang W, et al. Sleep disruption due to hospital noises: a prospective evaluation. Ann Intern Med 2012; 157(3):170–179. doi:10.7326/0003-4819-157-3-201208070-00472
  11. Heldt D; The Gazette. Accident will delay University of Iowa Hospitals construction work for several days. www.thegazette.com/2013/03/08/university-of-iowa-hospitals-patient-injured-by-falling-construction-debris. Accessed July 22, 2019.
  12. Darrah N; Fox News. Texas hospital explosion kills 1, leaves 12 injured. www.foxnews.com/us/texas-hospital-explosion-kills-1-leaves-12-injured. Accessed July 22, 2019.
  13. Centers for Disease Control and Prevention (CDC). Work-related asthma: most frequently reported agents associated with work-related asthma cases by state, 2009–2012. wwwn.cdc.gov/eworld/Data/926. Accessed July 22, 2019.
  14. Patterson TF, Thompson GR 3rd, Denning DW, et al. Practice guidelines for the diagnosis and management of Aspergillosis: 2016 update by the Infectious Diseases Society of America. Clin Infect Dis 2016; 63(4):e1–e60. doi:10.1093/cid/ciw326
  15. Chang CC, Athan E, Morrissey CO, Slavin MA. Preventing invasive fungal infection during hospital building works. Intern Med J 2008; 38(6b):538–541. doi:10.1111/j.1445-5994.2008.01727.x
  16. Oren I, Haddad N, Finkelstein R, Rowe JM. Invasive pulmonary aspergillosis in neutropenic patients during hospital construction: before and after chemoprophylaxis and institution of HEPA filters. Am J Hematol 2001; 66(4):257–262. doi:10.1002/ajh.1054
References
  1. Clair JD, Colatrella S. Opening Pandora’s (tool) box: health care construction and associated risk for nosocomial infection. Infect Disord Drug Targets 2013; 13(3):177–183. pmid:23961740
  2. Pokala HR, Leonard D, Cox J, et al. Association of hospital construction with the development of healthcare associated environmental mold infections (HAEMI) in pediatric patients with leukemia. Pediatr Blood Cancer 2014; 61(2):276–280. doi:10.1002/pbc.24685
  3. Vonberg RP, Gastmeier P. Nosocomial aspergillosis in outbreak settings. J Hosp Infect 2006; 63(3):246–254. doi:10.1016/j.jhin.2006.02.014
  4. Kanj A, Abdallah N, Soubani AO. The spectrum of pulmonary aspergillosis. Respir Med 2018; 141:121–131. doi:10.1016/j.rmed.2018.06.029
  5. Kanamori H, Rutala WA, Sickbert-Bennett EE, Weber DJ. Review of fungal outbreaks and infection prevention in healthcare settings during construction and renovation. Clin Infect Dis 2015; 61(3):433–444. doi:10.1093/cid/civ297
  6. Perola O, Kauppinen J, Kusnetsov J, Heikkinen J, Jokinen C, Katila ML. Nosocomial Legionella pneumophila serogroup 5 outbreak associated with persistent colonization of a hospital water system. APMIS 2002; 110(12):863–868. pmid:12645664
  7. Francois Watkins LK, Toews KE, Harris AM, et al. Lessons from an outbreak of Legionnaires disease on a hematology-oncology unit. Infect Control Hosp Epidemiol 2017; 38(3):306–313. doi:10.1017/ice.2016.281
  8. Lin YE, Stout JE, Yu VL. Prevention of hospital-acquired legionellosis. Curr Opin Infect Dis 2011; 24(4):350–356. doi:10.1097/QCO.0b013e3283486c6e
  9. Park MJ, Yoo JH, Cho BW, Kim KT, Jeong WC, Ha M. Noise in hospital rooms and sleep disturbance in hospitalized medical patients. Environ Health Toxicol 2014; 29:e2014006. doi:10.5620/eht.2014.29.e2014006
  10. Buxton OM, Ellenbogen JM, Wang W, et al. Sleep disruption due to hospital noises: a prospective evaluation. Ann Intern Med 2012; 157(3):170–179. doi:10.7326/0003-4819-157-3-201208070-00472
  11. Heldt D; The Gazette. Accident will delay University of Iowa Hospitals construction work for several days. www.thegazette.com/2013/03/08/university-of-iowa-hospitals-patient-injured-by-falling-construction-debris. Accessed July 22, 2019.
  12. Darrah N; Fox News. Texas hospital explosion kills 1, leaves 12 injured. www.foxnews.com/us/texas-hospital-explosion-kills-1-leaves-12-injured. Accessed July 22, 2019.
  13. Centers for Disease Control and Prevention (CDC). Work-related asthma: most frequently reported agents associated with work-related asthma cases by state, 2009–2012. wwwn.cdc.gov/eworld/Data/926. Accessed July 22, 2019.
  14. Patterson TF, Thompson GR 3rd, Denning DW, et al. Practice guidelines for the diagnosis and management of Aspergillosis: 2016 update by the Infectious Diseases Society of America. Clin Infect Dis 2016; 63(4):e1–e60. doi:10.1093/cid/ciw326
  15. Chang CC, Athan E, Morrissey CO, Slavin MA. Preventing invasive fungal infection during hospital building works. Intern Med J 2008; 38(6b):538–541. doi:10.1111/j.1445-5994.2008.01727.x
  16. Oren I, Haddad N, Finkelstein R, Rowe JM. Invasive pulmonary aspergillosis in neutropenic patients during hospital construction: before and after chemoprophylaxis and institution of HEPA filters. Am J Hematol 2001; 66(4):257–262. doi:10.1002/ajh.1054
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Does my patient need maintenance fluids?

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Does my patient need maintenance fluids?

My adult nonacutely ill patient, weighing 70 kg with a glomerular filtration rate (GFR) greater than 60 mL/min/1.73 m2, is admitted to the general medical service. She is to receive nothing by mouth for at least the next 24 hours for testing. Do I need to provide maintenance fluids intravenously?

The question seems like it should have an easy answer. However, there is no consensus either on the type of fluids or the need for them at all.

Mortiz and Ayus1 have described the role of maintenance intravenous (IV) fluids in acutely ill patients and made the case for isotonic saline (0.9% NaCl) to minimize the risk of hyponatremia, while acknowledging that it provides 7 to 10 g of sodium per day.

Recommendations for IV fluids for nonacutely ill hospitalized patients range from isotonic solutions such as 0.9% NaCl and lactated Ringer’s, to hypotonic fluids such as 5% dextrose in water (D5W) in 0.45% NaCl and D5W in 0.2% NaCl.2–5

The 2013 guidelines of the UK National Institute for Health and Care Excellence (NICE) recommend hypotonic fluids to provide 25 to 30 mL/kg/day of water with 1 mmol/kg/day of sodium. For a 70-kg patient (body surface area 1.7 m2), this would be 1,750 to 2,000 mL of water, with a maximum of 70 mEq/L of sodium (35 mEq/L).5 An option would be D5W in 0.2% NaCl, which has 34 mEq/L of sodium.

When choosing maintenance IV fluids, we need to consider the following questions:

  • What is my patient’s volume status?
  • What is the baseline serum sodium and renal function?
  • Are there comorbid conditions that may affect antidiuretic hormone (ADH) status such as physiologic stimulation from volume depletion, drugs, pathologic medical conditions, or syndrome of inappropriate ADH stimulation?
  • Will my patient be receiving strictly nothing by mouth?
  • Are there unusual fluid losses?

SCENARIO 1: ‘USUAL’ MAINTENANCE

If the patient is euvolemic, with a normal serum osmolality, a GFR more than 60 mL/min/1.73 m2, no stimuli for ADH secretion, and no unusual fluid losses, “usual” maintenance would be expected. The usual volume for this patient can be estimated by the following formulas:

  • Maintenance volume: 2,550 mL (1,500 mL × 1.7 m2 body surface area)
  • Holliday-Segar method6: 2,500 mL (1,500 mL plus 20 mL/kg for every kilogram over 20 kg).

The usual sodium can be also estimated by the following formulas:

  • 2 g Na/day = 2,000 mg/day = 87 mEq/day
  • Holliday-Segar6: 3 mEq Na/100 mL and 2 mEq K/100 mL of maintenance fluid.

Maintenance IV fluids for our nonacutely ill adult patient could be:

  • NICE guideline5: D5W in 0.2% NaCl with 20 mEq KCl, to run at 75 mL/hour
  • Holliday-Segar method6: D5W in 0.2% NaCl with 20 mEq KCl, to run at 100 mL/hour.

Twenty-four hours later, assuming no unusual fluid losses or stimulation of ADH secretion, our patient would weigh the same and would have no significant change in serum osmolality.

OTHER OPTIONS

What if I provide 0.9% NaCl instead?

Each 1 L of normal saline provides 154 mEq of sodium, equivalent to 3.5 g of sodium. Thus, for the 24 hours, with administration of 2 to 2.5 L, the patient would receive a sodium load of 7 to 8.75 g. The consequences of this can be debated, but for 24 hours, more than likely, nothing will happen or be noticeable. The kidneys have a wonderful ability to “dump” excess sodium ingested in the diet, as evidenced by the average Western diet with a sodium load in the range of 4 g per day.7,8

What if I provide 0.45% NaCl instead?

Each liter provides 50% of the sodium load of 0.9% NaCl. With the 24-hour administration of 2 to 2.5 L of D5W in 0.45% NaCl, the sodium load would be 3.5 to 4.8 g, and the kidneys would dump the excess sodium.

What if I provide ‘catch-up’ fluids after 24 hours, not maintenance fluids?

Assuming only usual losses and no unusual ADH stimulation except for the physiologic stimuli from volume depletion for 24 hours, our patient would lose 2 kg (1 L fluid loss = 1 kg weight loss) and 87 mEq of sodium. This is approximately 4.5% dehydration; thus, other than increased thirst, no physical findings of volume depletion would be clinically evident.

Table 1. Scenario 1: 24 hours without fluids.

However, serum osmolality and sodium would increase. After 24 hours of nothing by mouth with usual fluid losses, there would be a rise in serum osmolality of 13.5 mOsm/L (a rise in sodium of 6 to 7 mEq/L), which would stimulate ADH in an attempt to minimize further urinary losses. There would be an intracellular volume loss of 1.3 L (Table 1). Clinically, just as with the administration of 0.9% sodium, these changes would not likely be of any clinical consequence in the first 24 hours.

 

 

SCENARIO 2: IMPAIRED WATER EXCRETION, AND FLUIDS GIVEN

Table 2. Scenario 2: Antidiuretic hormone stimulation and 2L of 0.2% NaCl in 24 hours.

If the patient is euvolemic but has or is at risk for ADH stimulation,1,9 providing maintenance IV fluids according to the NICE or Holliday-Segar recommendations (a total of 2 L of 0.2% NaCl = 34 mEq Na/L = 68 mOsm/L) would result in an excess of free water, as an increase in ADH secretion impairs free water clearance. A potential scenario with impaired water excretion is shown in Table 2.

After 24 hours, the patient’s serum osmolality would drop by about 7 mOsm/L, and the serum sodium would decrease by 3 or 4 mEq. The consequence of the intracellular fluid shift would be seen by the expansion of the intracellular volume from 28 to 28.7 L.

If this patient were to have received 2 L of 0.9% NaCl (308 mOsm/L × 2 L = 616 Osm) as suggested by Moritz and Ayus,1 the result would be a serum osmolality of 284 mOsm/L, thus avoiding hyponatremia and intracellular fluid shifts.

THE BOTTOM LINE

Know your patient, answer the clinical questions noted above, and decide.

For a euvolemic patient with normal serum sodium, GFR greater than 60 mL/1.73 m2, and no ADH stimulation, for 24 hours it probably doesn’t matter that much, but a daily reassessment of the continued need for and type of intravenous fluids is critical.

For patients not meeting the criteria noted above such as a patient with systolic or diastolic heart failure, advanced or end-stage renal disease puts the patient at risk for early potential complications of either hyponatremia or sodium overload. For these patients, maintenance intravenous fluids need to be chosen wisely. Daily weights, examinations, and laboratory testing will let you know if something is not right and will allow for early detection and treatment.

References
  1. Mortiz ML, Ayus JC. Maintenance intravenous fluids in acutely ill patients. N Engl J Med 2015; 373(14):1350–1360. doi:10.1056/NEJMra1412877
  2. Feld LG, Neuspiel DR, Foster BA, et al; Subcommittee on Fluid and Electrolyte Therapy. Clinical practice guideline: maintenance intravenous fluids in children. Pediatrics 2018;142(6). doi:10.1542/peds.2018-3083
  3. Sterns RH. Maintenance and replacement fluid therapy in adults. www.uptodate.com/contents/maintenance-and-replacement-fluid-therapy-in-adults. Accessed August 21, 2019.
  4. Shafiee MA, Bohn D, Hoorn EJ, Halperin ML. How to select optimal maintenance intravenous fluid therapy. QJM 2003; 96(8):601–610. doi:10.1093/qjmed/hcg101
  5. National Institute for Health and Care Excellence (NICE). Intravenous fluid therapy in adults in hospital. www.nice.org.uk/guidance/cg174. Accessed August 21, 2019.
  6. Holliday MA, Segar WE. The maintenance need for water in parenteral fluid therapy. Pediatrics 1957; 19(5):823–832. pmid:13431307
  7. Appel LJ, Foti K. Sources of dietary sodium: implications for patients, physicians, and policy. Circulation 2017; 135(19):1784–1787. doi:10.1161/CIRCULATIONAHA.117.027933
  8. Harnack LJ, Cogswell ME, Shikany JM, et al. Sources of sodium in US adults from 3 geographic regions. Circulation 2017; 135(19):1775–1783. doi:10.1161/CIRCULATIONAHA.116.024446
  9. Sterns RH. Pathophysiology and etiology of the syndrome of inappropriate antidiuretic hormone secretion (SIADH). www.uptodate.com/contents/pathophysiology-and-etiology-of-the-syndrome-of-inappropriate-antidiuretic-hormone-secretion-siadh. Accessed August 21, 2019.
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Related Articles

My adult nonacutely ill patient, weighing 70 kg with a glomerular filtration rate (GFR) greater than 60 mL/min/1.73 m2, is admitted to the general medical service. She is to receive nothing by mouth for at least the next 24 hours for testing. Do I need to provide maintenance fluids intravenously?

The question seems like it should have an easy answer. However, there is no consensus either on the type of fluids or the need for them at all.

Mortiz and Ayus1 have described the role of maintenance intravenous (IV) fluids in acutely ill patients and made the case for isotonic saline (0.9% NaCl) to minimize the risk of hyponatremia, while acknowledging that it provides 7 to 10 g of sodium per day.

Recommendations for IV fluids for nonacutely ill hospitalized patients range from isotonic solutions such as 0.9% NaCl and lactated Ringer’s, to hypotonic fluids such as 5% dextrose in water (D5W) in 0.45% NaCl and D5W in 0.2% NaCl.2–5

The 2013 guidelines of the UK National Institute for Health and Care Excellence (NICE) recommend hypotonic fluids to provide 25 to 30 mL/kg/day of water with 1 mmol/kg/day of sodium. For a 70-kg patient (body surface area 1.7 m2), this would be 1,750 to 2,000 mL of water, with a maximum of 70 mEq/L of sodium (35 mEq/L).5 An option would be D5W in 0.2% NaCl, which has 34 mEq/L of sodium.

When choosing maintenance IV fluids, we need to consider the following questions:

  • What is my patient’s volume status?
  • What is the baseline serum sodium and renal function?
  • Are there comorbid conditions that may affect antidiuretic hormone (ADH) status such as physiologic stimulation from volume depletion, drugs, pathologic medical conditions, or syndrome of inappropriate ADH stimulation?
  • Will my patient be receiving strictly nothing by mouth?
  • Are there unusual fluid losses?

SCENARIO 1: ‘USUAL’ MAINTENANCE

If the patient is euvolemic, with a normal serum osmolality, a GFR more than 60 mL/min/1.73 m2, no stimuli for ADH secretion, and no unusual fluid losses, “usual” maintenance would be expected. The usual volume for this patient can be estimated by the following formulas:

  • Maintenance volume: 2,550 mL (1,500 mL × 1.7 m2 body surface area)
  • Holliday-Segar method6: 2,500 mL (1,500 mL plus 20 mL/kg for every kilogram over 20 kg).

The usual sodium can be also estimated by the following formulas:

  • 2 g Na/day = 2,000 mg/day = 87 mEq/day
  • Holliday-Segar6: 3 mEq Na/100 mL and 2 mEq K/100 mL of maintenance fluid.

Maintenance IV fluids for our nonacutely ill adult patient could be:

  • NICE guideline5: D5W in 0.2% NaCl with 20 mEq KCl, to run at 75 mL/hour
  • Holliday-Segar method6: D5W in 0.2% NaCl with 20 mEq KCl, to run at 100 mL/hour.

Twenty-four hours later, assuming no unusual fluid losses or stimulation of ADH secretion, our patient would weigh the same and would have no significant change in serum osmolality.

OTHER OPTIONS

What if I provide 0.9% NaCl instead?

Each 1 L of normal saline provides 154 mEq of sodium, equivalent to 3.5 g of sodium. Thus, for the 24 hours, with administration of 2 to 2.5 L, the patient would receive a sodium load of 7 to 8.75 g. The consequences of this can be debated, but for 24 hours, more than likely, nothing will happen or be noticeable. The kidneys have a wonderful ability to “dump” excess sodium ingested in the diet, as evidenced by the average Western diet with a sodium load in the range of 4 g per day.7,8

What if I provide 0.45% NaCl instead?

Each liter provides 50% of the sodium load of 0.9% NaCl. With the 24-hour administration of 2 to 2.5 L of D5W in 0.45% NaCl, the sodium load would be 3.5 to 4.8 g, and the kidneys would dump the excess sodium.

What if I provide ‘catch-up’ fluids after 24 hours, not maintenance fluids?

Assuming only usual losses and no unusual ADH stimulation except for the physiologic stimuli from volume depletion for 24 hours, our patient would lose 2 kg (1 L fluid loss = 1 kg weight loss) and 87 mEq of sodium. This is approximately 4.5% dehydration; thus, other than increased thirst, no physical findings of volume depletion would be clinically evident.

Table 1. Scenario 1: 24 hours without fluids.

However, serum osmolality and sodium would increase. After 24 hours of nothing by mouth with usual fluid losses, there would be a rise in serum osmolality of 13.5 mOsm/L (a rise in sodium of 6 to 7 mEq/L), which would stimulate ADH in an attempt to minimize further urinary losses. There would be an intracellular volume loss of 1.3 L (Table 1). Clinically, just as with the administration of 0.9% sodium, these changes would not likely be of any clinical consequence in the first 24 hours.

 

 

SCENARIO 2: IMPAIRED WATER EXCRETION, AND FLUIDS GIVEN

Table 2. Scenario 2: Antidiuretic hormone stimulation and 2L of 0.2% NaCl in 24 hours.

If the patient is euvolemic but has or is at risk for ADH stimulation,1,9 providing maintenance IV fluids according to the NICE or Holliday-Segar recommendations (a total of 2 L of 0.2% NaCl = 34 mEq Na/L = 68 mOsm/L) would result in an excess of free water, as an increase in ADH secretion impairs free water clearance. A potential scenario with impaired water excretion is shown in Table 2.

After 24 hours, the patient’s serum osmolality would drop by about 7 mOsm/L, and the serum sodium would decrease by 3 or 4 mEq. The consequence of the intracellular fluid shift would be seen by the expansion of the intracellular volume from 28 to 28.7 L.

If this patient were to have received 2 L of 0.9% NaCl (308 mOsm/L × 2 L = 616 Osm) as suggested by Moritz and Ayus,1 the result would be a serum osmolality of 284 mOsm/L, thus avoiding hyponatremia and intracellular fluid shifts.

THE BOTTOM LINE

Know your patient, answer the clinical questions noted above, and decide.

For a euvolemic patient with normal serum sodium, GFR greater than 60 mL/1.73 m2, and no ADH stimulation, for 24 hours it probably doesn’t matter that much, but a daily reassessment of the continued need for and type of intravenous fluids is critical.

For patients not meeting the criteria noted above such as a patient with systolic or diastolic heart failure, advanced or end-stage renal disease puts the patient at risk for early potential complications of either hyponatremia or sodium overload. For these patients, maintenance intravenous fluids need to be chosen wisely. Daily weights, examinations, and laboratory testing will let you know if something is not right and will allow for early detection and treatment.

My adult nonacutely ill patient, weighing 70 kg with a glomerular filtration rate (GFR) greater than 60 mL/min/1.73 m2, is admitted to the general medical service. She is to receive nothing by mouth for at least the next 24 hours for testing. Do I need to provide maintenance fluids intravenously?

The question seems like it should have an easy answer. However, there is no consensus either on the type of fluids or the need for them at all.

Mortiz and Ayus1 have described the role of maintenance intravenous (IV) fluids in acutely ill patients and made the case for isotonic saline (0.9% NaCl) to minimize the risk of hyponatremia, while acknowledging that it provides 7 to 10 g of sodium per day.

Recommendations for IV fluids for nonacutely ill hospitalized patients range from isotonic solutions such as 0.9% NaCl and lactated Ringer’s, to hypotonic fluids such as 5% dextrose in water (D5W) in 0.45% NaCl and D5W in 0.2% NaCl.2–5

The 2013 guidelines of the UK National Institute for Health and Care Excellence (NICE) recommend hypotonic fluids to provide 25 to 30 mL/kg/day of water with 1 mmol/kg/day of sodium. For a 70-kg patient (body surface area 1.7 m2), this would be 1,750 to 2,000 mL of water, with a maximum of 70 mEq/L of sodium (35 mEq/L).5 An option would be D5W in 0.2% NaCl, which has 34 mEq/L of sodium.

When choosing maintenance IV fluids, we need to consider the following questions:

  • What is my patient’s volume status?
  • What is the baseline serum sodium and renal function?
  • Are there comorbid conditions that may affect antidiuretic hormone (ADH) status such as physiologic stimulation from volume depletion, drugs, pathologic medical conditions, or syndrome of inappropriate ADH stimulation?
  • Will my patient be receiving strictly nothing by mouth?
  • Are there unusual fluid losses?

SCENARIO 1: ‘USUAL’ MAINTENANCE

If the patient is euvolemic, with a normal serum osmolality, a GFR more than 60 mL/min/1.73 m2, no stimuli for ADH secretion, and no unusual fluid losses, “usual” maintenance would be expected. The usual volume for this patient can be estimated by the following formulas:

  • Maintenance volume: 2,550 mL (1,500 mL × 1.7 m2 body surface area)
  • Holliday-Segar method6: 2,500 mL (1,500 mL plus 20 mL/kg for every kilogram over 20 kg).

The usual sodium can be also estimated by the following formulas:

  • 2 g Na/day = 2,000 mg/day = 87 mEq/day
  • Holliday-Segar6: 3 mEq Na/100 mL and 2 mEq K/100 mL of maintenance fluid.

Maintenance IV fluids for our nonacutely ill adult patient could be:

  • NICE guideline5: D5W in 0.2% NaCl with 20 mEq KCl, to run at 75 mL/hour
  • Holliday-Segar method6: D5W in 0.2% NaCl with 20 mEq KCl, to run at 100 mL/hour.

Twenty-four hours later, assuming no unusual fluid losses or stimulation of ADH secretion, our patient would weigh the same and would have no significant change in serum osmolality.

OTHER OPTIONS

What if I provide 0.9% NaCl instead?

Each 1 L of normal saline provides 154 mEq of sodium, equivalent to 3.5 g of sodium. Thus, for the 24 hours, with administration of 2 to 2.5 L, the patient would receive a sodium load of 7 to 8.75 g. The consequences of this can be debated, but for 24 hours, more than likely, nothing will happen or be noticeable. The kidneys have a wonderful ability to “dump” excess sodium ingested in the diet, as evidenced by the average Western diet with a sodium load in the range of 4 g per day.7,8

What if I provide 0.45% NaCl instead?

Each liter provides 50% of the sodium load of 0.9% NaCl. With the 24-hour administration of 2 to 2.5 L of D5W in 0.45% NaCl, the sodium load would be 3.5 to 4.8 g, and the kidneys would dump the excess sodium.

What if I provide ‘catch-up’ fluids after 24 hours, not maintenance fluids?

Assuming only usual losses and no unusual ADH stimulation except for the physiologic stimuli from volume depletion for 24 hours, our patient would lose 2 kg (1 L fluid loss = 1 kg weight loss) and 87 mEq of sodium. This is approximately 4.5% dehydration; thus, other than increased thirst, no physical findings of volume depletion would be clinically evident.

Table 1. Scenario 1: 24 hours without fluids.

However, serum osmolality and sodium would increase. After 24 hours of nothing by mouth with usual fluid losses, there would be a rise in serum osmolality of 13.5 mOsm/L (a rise in sodium of 6 to 7 mEq/L), which would stimulate ADH in an attempt to minimize further urinary losses. There would be an intracellular volume loss of 1.3 L (Table 1). Clinically, just as with the administration of 0.9% sodium, these changes would not likely be of any clinical consequence in the first 24 hours.

 

 

SCENARIO 2: IMPAIRED WATER EXCRETION, AND FLUIDS GIVEN

Table 2. Scenario 2: Antidiuretic hormone stimulation and 2L of 0.2% NaCl in 24 hours.

If the patient is euvolemic but has or is at risk for ADH stimulation,1,9 providing maintenance IV fluids according to the NICE or Holliday-Segar recommendations (a total of 2 L of 0.2% NaCl = 34 mEq Na/L = 68 mOsm/L) would result in an excess of free water, as an increase in ADH secretion impairs free water clearance. A potential scenario with impaired water excretion is shown in Table 2.

After 24 hours, the patient’s serum osmolality would drop by about 7 mOsm/L, and the serum sodium would decrease by 3 or 4 mEq. The consequence of the intracellular fluid shift would be seen by the expansion of the intracellular volume from 28 to 28.7 L.

If this patient were to have received 2 L of 0.9% NaCl (308 mOsm/L × 2 L = 616 Osm) as suggested by Moritz and Ayus,1 the result would be a serum osmolality of 284 mOsm/L, thus avoiding hyponatremia and intracellular fluid shifts.

THE BOTTOM LINE

Know your patient, answer the clinical questions noted above, and decide.

For a euvolemic patient with normal serum sodium, GFR greater than 60 mL/1.73 m2, and no ADH stimulation, for 24 hours it probably doesn’t matter that much, but a daily reassessment of the continued need for and type of intravenous fluids is critical.

For patients not meeting the criteria noted above such as a patient with systolic or diastolic heart failure, advanced or end-stage renal disease puts the patient at risk for early potential complications of either hyponatremia or sodium overload. For these patients, maintenance intravenous fluids need to be chosen wisely. Daily weights, examinations, and laboratory testing will let you know if something is not right and will allow for early detection and treatment.

References
  1. Mortiz ML, Ayus JC. Maintenance intravenous fluids in acutely ill patients. N Engl J Med 2015; 373(14):1350–1360. doi:10.1056/NEJMra1412877
  2. Feld LG, Neuspiel DR, Foster BA, et al; Subcommittee on Fluid and Electrolyte Therapy. Clinical practice guideline: maintenance intravenous fluids in children. Pediatrics 2018;142(6). doi:10.1542/peds.2018-3083
  3. Sterns RH. Maintenance and replacement fluid therapy in adults. www.uptodate.com/contents/maintenance-and-replacement-fluid-therapy-in-adults. Accessed August 21, 2019.
  4. Shafiee MA, Bohn D, Hoorn EJ, Halperin ML. How to select optimal maintenance intravenous fluid therapy. QJM 2003; 96(8):601–610. doi:10.1093/qjmed/hcg101
  5. National Institute for Health and Care Excellence (NICE). Intravenous fluid therapy in adults in hospital. www.nice.org.uk/guidance/cg174. Accessed August 21, 2019.
  6. Holliday MA, Segar WE. The maintenance need for water in parenteral fluid therapy. Pediatrics 1957; 19(5):823–832. pmid:13431307
  7. Appel LJ, Foti K. Sources of dietary sodium: implications for patients, physicians, and policy. Circulation 2017; 135(19):1784–1787. doi:10.1161/CIRCULATIONAHA.117.027933
  8. Harnack LJ, Cogswell ME, Shikany JM, et al. Sources of sodium in US adults from 3 geographic regions. Circulation 2017; 135(19):1775–1783. doi:10.1161/CIRCULATIONAHA.116.024446
  9. Sterns RH. Pathophysiology and etiology of the syndrome of inappropriate antidiuretic hormone secretion (SIADH). www.uptodate.com/contents/pathophysiology-and-etiology-of-the-syndrome-of-inappropriate-antidiuretic-hormone-secretion-siadh. Accessed August 21, 2019.
References
  1. Mortiz ML, Ayus JC. Maintenance intravenous fluids in acutely ill patients. N Engl J Med 2015; 373(14):1350–1360. doi:10.1056/NEJMra1412877
  2. Feld LG, Neuspiel DR, Foster BA, et al; Subcommittee on Fluid and Electrolyte Therapy. Clinical practice guideline: maintenance intravenous fluids in children. Pediatrics 2018;142(6). doi:10.1542/peds.2018-3083
  3. Sterns RH. Maintenance and replacement fluid therapy in adults. www.uptodate.com/contents/maintenance-and-replacement-fluid-therapy-in-adults. Accessed August 21, 2019.
  4. Shafiee MA, Bohn D, Hoorn EJ, Halperin ML. How to select optimal maintenance intravenous fluid therapy. QJM 2003; 96(8):601–610. doi:10.1093/qjmed/hcg101
  5. National Institute for Health and Care Excellence (NICE). Intravenous fluid therapy in adults in hospital. www.nice.org.uk/guidance/cg174. Accessed August 21, 2019.
  6. Holliday MA, Segar WE. The maintenance need for water in parenteral fluid therapy. Pediatrics 1957; 19(5):823–832. pmid:13431307
  7. Appel LJ, Foti K. Sources of dietary sodium: implications for patients, physicians, and policy. Circulation 2017; 135(19):1784–1787. doi:10.1161/CIRCULATIONAHA.117.027933
  8. Harnack LJ, Cogswell ME, Shikany JM, et al. Sources of sodium in US adults from 3 geographic regions. Circulation 2017; 135(19):1775–1783. doi:10.1161/CIRCULATIONAHA.116.024446
  9. Sterns RH. Pathophysiology and etiology of the syndrome of inappropriate antidiuretic hormone secretion (SIADH). www.uptodate.com/contents/pathophysiology-and-etiology-of-the-syndrome-of-inappropriate-antidiuretic-hormone-secretion-siadh. Accessed August 21, 2019.
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Are daily chest radiographs and arterial blood gas tests required in ICU patients on mechanical ventilation?

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Are daily chest radiographs and arterial blood gas tests required in ICU patients on mechanical ventilation?

No, they are not required or needed, but daily radiography and arterial blood gas testing are common practice: eg, 60% of intensive care unit (ICU) patients get daily radiographs,1 even though results provide low diagnostic yield and are unlikely to alter patient management compared with testing only when indicated.

The Choosing Wisely campaign,2 a collaborative effort of a number of professional societies, advises against ordering these diagnostic tests daily because routine testing increases risks to patients and burdens the healthcare system. Instead, testing is recommended only in response to a specific clinical question, or when the test results will affect the patient’s treatment.

CHEST RADIOGRAPHS: DAILY VS CLINICALLY INDICATED

Chest radiographs enable practitioners to monitor the position of endotracheal tubes and central venous catheters, evaluate fluid status, follow up on abnormal findings, detect complications of procedures (such as a pneumothorax), and identify otherwise undetected conditions.

And daily chest radiographs often detect abnormalities. A 1991 study by Hall et al3 of 538 chest radiographs in 74 patients on mechanical ventilation reported that 30% of daily routine chest radiographs disclosed a new but minor finding (eg, a small change in endotracheal tube position or a small infiltrate). The new findings were major in 13 (17.6%) of the 74 patients (95% confidence interval [CI] 9%–26%). These included findings that required an immediate diagnostic or therapeutic intervention (eg, endotracheal tube below the tracheal carina, malposition of a catheter, pneumothorax, large pleural effusion).

But most studies say daily radiographs are not needed. In a large prospective study published in 2006, Graat et al4 evaluated the clinical value of 2,457 routine chest radiographs in 754 patients in a combined surgical and medical ICU. Daily chest radiographs revealed new or unexpected findings in 5.8% of cases, but only 2.2% warranted a change in therapy. No differences were found between the medical and surgical patients. The authors concluded that daily routine radiographs in ICU patients seldom reveal unexpected, clinically relevant abnormalities, and those findings rarely require urgent intervention.

A 2010 meta-analysis of 8 studies (7,078 patients) by Oba and Zaza5 compared on-demand and daily routine strategies of performing chest radiographs. They estimated that eliminating daily routine chest radiographs would not affect death rates in the hospital (odds ratio [OR] 1.02, 95% CI 0.89–1.17, P = .78) or the ICU (OR 0.92, 95% CI 0.76–1.11, P = .4). They also found no significant differences in length of stay or duration of mechanical ventilation. This meta-analysis suggests that routine radiographs can be eliminated without adversely affecting outcomes in ICU patients.

A larger meta-analysis (9 trials, 39,358 radiographs, 9,611 patients) published in 2012 by Ganapathy et al6 also found no harm associated with restrictive radiography protocols. These investigators compared a daily chest radiography protocol against a protocol based on clinical indications. The primary outcome was the mortality rate in the ICU; secondary outcomes were the mortality rate in the hospital, the length of stay in the ICU, and duration of mechanical ventilation. They found no differences between routine and restrictive strategies in terms of ICU mortality (risk ratio [RR] 1.04, 95% CI 0.84–1.28, P = .72), hospital mortality (RR 0.98, 95% CI 0.68–1.41, P = .91), or other secondary outcomes.

Clinically indicated testing is better

The conclusion from these studies is that routine chest radiographs in patients undergoing mechanical ventilation does not improve patient outcomes, and thus, a clinically indicated protocol is preferred.

Furthermore, routine daily radiographs have adverse effects such as more cumulative radiation exposure to the patient7 and greater risk of accidental removal of devices (eg, catheters, tubes).8 Another concern is a higher risk of hospital-associated infections from bacterial spread from caregivers’ hands.9

Finally, daily radiographs increase the use of healthcare resources and expenditures. In a 2011 study, Gershengorn et al1 estimated that adopting a clinically indicated radiography strategy could save more than $144 million annually in the United States.

The ACR agrees. Appropriateness criteria published by the American College of Radiology (ACR) in 201510 recommend against routine daily chest radiographs in the ICU, in keeping with the findings of the critical care community. The ACR recommends an initial radiograph at admission to the ICU. However, follow-up radiographs should be obtained only for specific clinical indications, including a change in the patient’s clinical condition or to check for proper placement of endotracheal or nasogastric or orogastric tubes, pulmonary arterial catheters, central venous catheters, chest tubes, and other life-support devices.

Ultrasonography as an alternative

Ultrasonography is widely available and provides an alternative to chest radiography for detecting significant abnormalities in patients on mechanical ventilation without exposing them to radiation and using relatively fewer resources.

A 2012 meta-analysis (8 studies, 1,048 patients) found that bedside ultrasonography reliably detects pneumothorax.11 It can also provide a rapid diagnosis of the cause of acute respiratory failure such as pneumonia or pulmonary edema.12 Ultrasonography, with the appropriate expertise, can also confirm the position of an endotracheal tube13 or central venous catheter.14

 

 

ARTERIAL BLOOD GAS TESTING: DAILY VS CLINICALLY INDICATED

Arterial blood gas testing has value for managing patients undergoing mechanical ventilation, and it is one of the most commonly performed diagnostic tests in the ICU. It provides reliable information about the patient’s oxygenation and acid-base status. It is commonly requested when changing ventilator settings.

Downsides. Arterial blood gas measurements account for 10% to 20% of the cost incurred during ICU stay.15 In addition, they require an arterial puncture—an invasive procedure associated with potentially serious complications such as occlusion of the artery, digital embolization leading to digital ischemia, local infection, pseudoaneurysm, hematoma, bleeding, and skin necrosis.

Is daily testing needed?

Guidelines say no. The 2013 American Association for Respiratory Care16 guidelines suggest that arterial blood gas testing should be based on the clinical assessment of the patient. They recommend blood gas analysis to evaluate the patient’s ventilatory status (reflected by the partial pressure of arterial carbon dioxide [PaCO2], acid-base status (reflected by pH), arterial oxygenation (partial pressure of arterial oxygen [PaO2] and oxyhemoglobin saturation), oxygen-carrying capacity, and whether the patient likely has an intrapulmonary shunt. They state that testing is useful to quantify the response to therapeutic or diagnostic interventions such as cardiopulmonary exercise testing, to monitor severity and progression of documented disease, and to assess the adequacy of circulatory response.

Studies agree

The ACR recommendation to test “as clinically indicated” is supported by studies showing that patient outcomes are not inferior for arterial blood gas testing when clinically indicated instead of daily, and that this practice is associated with fewer complications, less resource use, and reduced overall patient care costs.

A 2015 study compared the efficacy and safety of obtaining arterial blood gases based on clinical assessment vs daily in 300 critically ill patients.17 Overall, fewer samples were obtained per patient in the clinical assessment group than in the daily group (all patients 3.7 vs 5.5; ventilated patients 2.03 vs 6.12; P < .001 for both). In ventilated patients, there was a 60% decrease in arterial blood gas orders without affecting patient outcomes and safety, including a lower risk of complications and overall cost of care.

In another study, Martinez-Balzano et al18 evaluated the effect of guidelines they developed to optimize the use of arterial blood gas testing in their ICUs. These guidelines encouraged testing of arterial blood gases after an acute respiratory event or for a rational clinical concern, and discouraged testing for routine surveillance, after planned changes of positive end-expiratory pressure or inspired oxygen fraction on mechanical ventilation, for spontaneous breathing trials, or when a disorder was not suspected.

Compared with data collected before implementation, these guidelines reduced the number of arterial blood gas tests by 821.5 per month (41.5%), or approximately 1 test per patient per mechanical-ventilation day for each month (43.1%; P < .001). Appropriately indicated testing rose to 83.4% from a baseline of 67.5% (P = .002). Additionally, this approach was associated with saving 49 liters of blood, reducing ICU costs by $39,432, and freeing up 1,643 staff work hours for other tasks. There were no significant differences in days on mechanical ventilation, severity of illness, or mortality between the 2 periods.18

Extubation effects. Routine arterial blood gas testing has not been shown to affect extubation decisions in patients on mechanical ventilation. In a study of 83 patients who completed a spontaneous breathing trial (total of 100 trials), Salam et al19 found arterial blood gas values obtained during the trial did not change the extubation decision in 93% of the cases.

In a study of 54 extubations in 52 patients,20 65% of the extubations were performed without obtaining an arterial blood gas test after the patient completed a trial of spontaneous breathing. The extubation success rate was 94% for the entire group, and it was the same regardless of whether testing was done (94.7% vs 94.3%, respectively).

Alternatives to arterial blood gases

There are less-invasive means to obtain the information that comes from an arterial blood gas test.

Pulse oximetry is a rapid noninvasive tool that provides continuous assessment of peripheral arterial oxygen saturation as a surrogate marker for tissue arterial oxygenation. However, it cannot measure PaO2 or PaCO2.21

Transcutaneous carbon dioxide (PTCO2) monitoring is another continuous noninvasive alternative. The newer PTCO2 devices are useful in patients with acute respiratory failure and in critically ill patients on vasopressors or vasodilators. Studies have shown good correlation between PTCO2 and PaCO2.22,23

End-tidal carbon dioxide (PetCO2) is another alternative to estimate PaCO2. It can also be used to confirm endotracheal tube placement, during transportation, during procedures in which the patient is under conscious sedation, and to monitor the effectiveness of cardiopulmonary resuscitation and return of circulation after cardiac arrest. PetCO2 measurements are not as accurate as arterial blood gas testing owing to a difference of approximately 2 to 5 mm Hg between PaCO2 and PetCO2 in normal lungs due to alveolar dead space. This difference may be much higher depending on the clinical condition and the degree of alveolar dead space.21,24,25

Venous blood gases, which can be obtained from a peripheral or central venous catheter, are adequate to assess pH and partial pressure of carbon dioxide (PCO2) in hemodynamically stable patients. Walkey et al26 found that the accuracy of venous blood gas measurement to predict arterial blood gases was 90%. They recommended adjusting the venous pH up by 0.05 and the PCO2 down by 5 mm Hg to account for the positive bias of venous blood gases. A limitation of this method is that the values are not reliable in patients who are in shock.

These alternatives can be used as a substitute for daily arterial blood gases. However, in certain clinical scenarios, arterial blood gas measurement remains a necessary and useful clinical tool.

TAKE-HOME MESSAGE

Most scientific evidence suggests that chest radiographs and arterial blood gas measurement in patients undergoing mechanical ventilation—and critically ill, in general—are best done when clinically indicated rather than routinely on a daily basis. This will reduce cost and harm to patients that may result from these unnecessary tests and not adversely affect outcomes.

References
  1. Gershengorn HB, Wunsch H, Scales DC, Rubenfeld GD. Trends in use of daily chest radiographs among US adults receiving mechanical ventilation. JAMA Netw Open 2018; 1(4):e181119. doi:10.1001/jamanetworkopen.2018.1119
  2. American Board of Internal Medicine Foundation. Choosing Wisely. http://www.choosingwisely.org/clinician-lists/critical-care-societies-collaborative-regular-diagnostic-tests. Accessed August 18, 2019.
  3. Hall JB, White SR, Karrison T. Efficacy of daily routine chest radiographs in intubated, mechanically ventilated patients. Crit Care Med 1991; 19(5):689–693. pmid:2026031
  4. Graat ME, Choi G, Wolthuis EK, et al. The clinical value of daily routine chest radiographs in a mixed medical-surgical intensive care unit is low. Crit Care 2006; 10(1):R11. doi:10.1186/cc3955
  5. Oba Y, Zaza T. Abandoning daily routine chest radiography in the intensive care unit: meta-analysis. Radiology 2010; 255(2):386–395. doi:10.1148/radiol.10090946
  6. Ganapathy A, Adhikari NK, Spiegelman J, Scales DC. Routine chest x-rays in intensive care units: a systematic review and meta-analysis. Crit Care 2012; 16(2):R68. doi:10.1186/cc11321
  7. Krishnan S, Moghekar A, Duggal A, et al. Radiation exposure in the medical ICU: predictors and characteristics. Chest 2018; 153(5):1160–1168. doi:10.1016/j.chest.2018.01.019
  8. Hejblum G, Chalumeau-Lemoine L, Ioos V, et al. Comparison of routine and on-demand prescription of chest radiographs in mechanically ventilated adults: a multicentre, cluster-randomised, two-period crossover study. Lancet 2009; 374(9702):1687–1693. doi:10.1016/S0140-6736(09)61459-8
  9. Levin PD, Shatz O, Sviri S, et al. Contamination of portable radiograph equipment with resistant bacteria in the ICU. Chest 2009; 136(2):426–432. doi:10.1378/chest.09-0049
  10. Suh RD, Genshaft SJ, Kirsch J, et al. ACR Appropriateness Criteria® Intensive Care Unit Patients. J Thorac Imaging 2015; 30(6):W63–W65. doi:10.1097/RTI.0000000000000174
  11. Alrajhi K, Woo MY, Vaillancourt C. Test characteristics of ultrasonography for the detection of pneumothorax: a systematic review and meta-analysis. Chest 2012; 141(3):703–708. doi:10.1378/chest.11-0131
  12. Lichetenstein DA, Meziere GA. Relevance of lung ultrasound in the diagnosis of acute respiratory failure: the BLUE protocol. Chest 2008; 134(1):117–125. doi:10.1378/chest.07-2800
  13. Das SK, Choupoo NS, Haldar R, Lahkar A. Transtracheal ultrasound for verification of endotracheal tube placement: a systematic review and meta-analysis. Can J Anaesth 2015; 62(4):413–423. doi:10.1007/s12630-014-0301-z
  14. Ablordeppey EA, Drewry AM, Beyer AB, et al. Diagnostic accuracy of central venous catheter confirmation by bedside ultrasound versus chest radiography in critically ill patients: a systematic review and meta-analysis. Crit Care Med 2017; 45(4):715–724. doi:10.1097/CCM.0000000000002188
  15. DellaVolpe JD, Chakraborti C, Cerreta K, et al. Effects of implementing a protocol for arterial blood gas use on ordering practices and diagnostic yield. Healthc (Amst) 2014; 2(2):130–135. doi:10.1016/j.hjdsi.2013.09.006
  16. Davis MD, Walsh BK, Sittig SE, Restrepo RD. AARC clinical practice guideline: blood gas analysis and hemoximetry. Respir Care 2013; 58(10):1694–1703. doi:10.4187/respcare.02786
  17. Blum FE, Lund ET, Hall HA, Tachauer AD, Chedrawy EG, Zilberstein J. Reevaluation of the utilization of arterial blood gas analysis in the intensive care unit: effects on patient safety and patient outcome. J Crit Care 2015; 30(2):438.e1–e5. doi:10.1016/j.jcrc.2014.10.025
  18. Martínez-Balzano CD, Oliveira P, O’Rourke M, Hills L, Sosa AF; Critical Care Operations Committee of the UMass Memorial Healthcare Center. An educational intervention optimizes the use of arterial blood gas determinations across ICUs from different specialties: a quality-improvement study. Chest 2017; 151(3):579–585. doi:10.1016/j.chest.2016.10.035
  19. Salam A, Smina M, Gada P, et al. The effect of arterial blood gas values on extubation decisions. Respir Care 2003; 48(11):1033–1037. pmid:14585115
  20. Pawson SR, DePriest JL. Are blood gases necessary in mechanically ventilated patients who have successfully completed a spontaneous breathing trial? Respir Care 2004; 49(11):1316–1319. pmid:15507165
  21. Soubani AO. Noninvasive monitoring of oxygen and carbon dioxide. Am J Emerg Med 2001; 19(2):141–146. doi:10.1053/ajem.2001.21353
  22. Nicolini A, Ferrari MB. Evaluation of a transcutaneous carbon dioxide monitor in patients with acute respiratory failure. Ann Thorac Med 2011; 6(4):217–220. doi:10.4103/1817-1737.84776
  23. Bendjelid K, Schütz N, Stotz M, Gerard I, Suter PM, Romand JA. Transcutaneous PCO2 monitoring in critically ill adults: clinical evaluation of a new sensor. Crit Care Med 2005; 33(10):2203–2206. pmid:16215371
  24. Huttmann SE, Windisch W, Storre JH. Techniques for the measurement and monitoring of carbon dioxide in the blood. Ann Am Thorac Soc 2014; 11(4):645–652. doi:10.1513/AnnalsATS.201311-387FR
  25. McSwain SD, Hamel DS, Smith PB, et al. End-tidal and arterial carbon dioxide measurements correlate across all levels of physiologic dead space. Respir Care 2010; 55(3):288–293. pmid:20196877
  26. Walkey AJ, Farber HW, O'Donnell C, Cabral H, Eagan JS, Philippides GJ. The accuracy of the central venous blood gas for acid-base monitoring. J Intensive Care Med 2010; 25(2):104–110. doi:10.1177/0885066609356164
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Shyam Ganti, MD
Division of Pulmonary, Critical Care, and Sleep Medicine, Wayne State University School of Medicine, Detroit, MI

Ravinder D. Bhanot, MD
Division of Pulmonary and Critical Care, Ascension St. Mary’s, Saginaw, MI

Jasleen Kaur, MD
Department of Internal Medicine, Wayne State University School of Medicine, Detroit, MI

Cassondra Cramer-Bour, MD
Department of Medicine, Boston University School of Medicine, Boston, MA

Ayman O. Soubani, MD
Professor of Medicine, Wayne State University School of Medicine; Medical Director, Medical ICU, Harper University Hospital; Service Chief, Pulmonary and Critical Care, and Medical Director, Critical Care Service, Karmanos Cancer Center; Division of Pulmonary, Critical Care and Sleep Medicine, Wayne State University School of Medicine, Detroit, MI

Address: Ayman O. Soubani, MD, Division of Pulmonary, Critical Care and Sleep Medicine. Wayne State University School of Medicine, 3990 John R-3 Hudson, Detroit, MI 48201; [email protected]

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radiographs, chest x-rays, intensive care, ICU, arterial blood gases, ABGs, daily testing, needless testing, smart testing, pulse oximetry, transcutaneous carbon dioxide, end-tidal carbon dioxide, venous blood gases, ultrasonography, ventilation, Shyam Ganti, Ravinder Bhanot, Jaslee Kaur, Cassondra Cramer-Bour, Ayman Soubani
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Shyam Ganti, MD
Division of Pulmonary, Critical Care, and Sleep Medicine, Wayne State University School of Medicine, Detroit, MI

Ravinder D. Bhanot, MD
Division of Pulmonary and Critical Care, Ascension St. Mary’s, Saginaw, MI

Jasleen Kaur, MD
Department of Internal Medicine, Wayne State University School of Medicine, Detroit, MI

Cassondra Cramer-Bour, MD
Department of Medicine, Boston University School of Medicine, Boston, MA

Ayman O. Soubani, MD
Professor of Medicine, Wayne State University School of Medicine; Medical Director, Medical ICU, Harper University Hospital; Service Chief, Pulmonary and Critical Care, and Medical Director, Critical Care Service, Karmanos Cancer Center; Division of Pulmonary, Critical Care and Sleep Medicine, Wayne State University School of Medicine, Detroit, MI

Address: Ayman O. Soubani, MD, Division of Pulmonary, Critical Care and Sleep Medicine. Wayne State University School of Medicine, 3990 John R-3 Hudson, Detroit, MI 48201; [email protected]

Author and Disclosure Information

Shyam Ganti, MD
Division of Pulmonary, Critical Care, and Sleep Medicine, Wayne State University School of Medicine, Detroit, MI

Ravinder D. Bhanot, MD
Division of Pulmonary and Critical Care, Ascension St. Mary’s, Saginaw, MI

Jasleen Kaur, MD
Department of Internal Medicine, Wayne State University School of Medicine, Detroit, MI

Cassondra Cramer-Bour, MD
Department of Medicine, Boston University School of Medicine, Boston, MA

Ayman O. Soubani, MD
Professor of Medicine, Wayne State University School of Medicine; Medical Director, Medical ICU, Harper University Hospital; Service Chief, Pulmonary and Critical Care, and Medical Director, Critical Care Service, Karmanos Cancer Center; Division of Pulmonary, Critical Care and Sleep Medicine, Wayne State University School of Medicine, Detroit, MI

Address: Ayman O. Soubani, MD, Division of Pulmonary, Critical Care and Sleep Medicine. Wayne State University School of Medicine, 3990 John R-3 Hudson, Detroit, MI 48201; [email protected]

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Related Articles

No, they are not required or needed, but daily radiography and arterial blood gas testing are common practice: eg, 60% of intensive care unit (ICU) patients get daily radiographs,1 even though results provide low diagnostic yield and are unlikely to alter patient management compared with testing only when indicated.

The Choosing Wisely campaign,2 a collaborative effort of a number of professional societies, advises against ordering these diagnostic tests daily because routine testing increases risks to patients and burdens the healthcare system. Instead, testing is recommended only in response to a specific clinical question, or when the test results will affect the patient’s treatment.

CHEST RADIOGRAPHS: DAILY VS CLINICALLY INDICATED

Chest radiographs enable practitioners to monitor the position of endotracheal tubes and central venous catheters, evaluate fluid status, follow up on abnormal findings, detect complications of procedures (such as a pneumothorax), and identify otherwise undetected conditions.

And daily chest radiographs often detect abnormalities. A 1991 study by Hall et al3 of 538 chest radiographs in 74 patients on mechanical ventilation reported that 30% of daily routine chest radiographs disclosed a new but minor finding (eg, a small change in endotracheal tube position or a small infiltrate). The new findings were major in 13 (17.6%) of the 74 patients (95% confidence interval [CI] 9%–26%). These included findings that required an immediate diagnostic or therapeutic intervention (eg, endotracheal tube below the tracheal carina, malposition of a catheter, pneumothorax, large pleural effusion).

But most studies say daily radiographs are not needed. In a large prospective study published in 2006, Graat et al4 evaluated the clinical value of 2,457 routine chest radiographs in 754 patients in a combined surgical and medical ICU. Daily chest radiographs revealed new or unexpected findings in 5.8% of cases, but only 2.2% warranted a change in therapy. No differences were found between the medical and surgical patients. The authors concluded that daily routine radiographs in ICU patients seldom reveal unexpected, clinically relevant abnormalities, and those findings rarely require urgent intervention.

A 2010 meta-analysis of 8 studies (7,078 patients) by Oba and Zaza5 compared on-demand and daily routine strategies of performing chest radiographs. They estimated that eliminating daily routine chest radiographs would not affect death rates in the hospital (odds ratio [OR] 1.02, 95% CI 0.89–1.17, P = .78) or the ICU (OR 0.92, 95% CI 0.76–1.11, P = .4). They also found no significant differences in length of stay or duration of mechanical ventilation. This meta-analysis suggests that routine radiographs can be eliminated without adversely affecting outcomes in ICU patients.

A larger meta-analysis (9 trials, 39,358 radiographs, 9,611 patients) published in 2012 by Ganapathy et al6 also found no harm associated with restrictive radiography protocols. These investigators compared a daily chest radiography protocol against a protocol based on clinical indications. The primary outcome was the mortality rate in the ICU; secondary outcomes were the mortality rate in the hospital, the length of stay in the ICU, and duration of mechanical ventilation. They found no differences between routine and restrictive strategies in terms of ICU mortality (risk ratio [RR] 1.04, 95% CI 0.84–1.28, P = .72), hospital mortality (RR 0.98, 95% CI 0.68–1.41, P = .91), or other secondary outcomes.

Clinically indicated testing is better

The conclusion from these studies is that routine chest radiographs in patients undergoing mechanical ventilation does not improve patient outcomes, and thus, a clinically indicated protocol is preferred.

Furthermore, routine daily radiographs have adverse effects such as more cumulative radiation exposure to the patient7 and greater risk of accidental removal of devices (eg, catheters, tubes).8 Another concern is a higher risk of hospital-associated infections from bacterial spread from caregivers’ hands.9

Finally, daily radiographs increase the use of healthcare resources and expenditures. In a 2011 study, Gershengorn et al1 estimated that adopting a clinically indicated radiography strategy could save more than $144 million annually in the United States.

The ACR agrees. Appropriateness criteria published by the American College of Radiology (ACR) in 201510 recommend against routine daily chest radiographs in the ICU, in keeping with the findings of the critical care community. The ACR recommends an initial radiograph at admission to the ICU. However, follow-up radiographs should be obtained only for specific clinical indications, including a change in the patient’s clinical condition or to check for proper placement of endotracheal or nasogastric or orogastric tubes, pulmonary arterial catheters, central venous catheters, chest tubes, and other life-support devices.

Ultrasonography as an alternative

Ultrasonography is widely available and provides an alternative to chest radiography for detecting significant abnormalities in patients on mechanical ventilation without exposing them to radiation and using relatively fewer resources.

A 2012 meta-analysis (8 studies, 1,048 patients) found that bedside ultrasonography reliably detects pneumothorax.11 It can also provide a rapid diagnosis of the cause of acute respiratory failure such as pneumonia or pulmonary edema.12 Ultrasonography, with the appropriate expertise, can also confirm the position of an endotracheal tube13 or central venous catheter.14

 

 

ARTERIAL BLOOD GAS TESTING: DAILY VS CLINICALLY INDICATED

Arterial blood gas testing has value for managing patients undergoing mechanical ventilation, and it is one of the most commonly performed diagnostic tests in the ICU. It provides reliable information about the patient’s oxygenation and acid-base status. It is commonly requested when changing ventilator settings.

Downsides. Arterial blood gas measurements account for 10% to 20% of the cost incurred during ICU stay.15 In addition, they require an arterial puncture—an invasive procedure associated with potentially serious complications such as occlusion of the artery, digital embolization leading to digital ischemia, local infection, pseudoaneurysm, hematoma, bleeding, and skin necrosis.

Is daily testing needed?

Guidelines say no. The 2013 American Association for Respiratory Care16 guidelines suggest that arterial blood gas testing should be based on the clinical assessment of the patient. They recommend blood gas analysis to evaluate the patient’s ventilatory status (reflected by the partial pressure of arterial carbon dioxide [PaCO2], acid-base status (reflected by pH), arterial oxygenation (partial pressure of arterial oxygen [PaO2] and oxyhemoglobin saturation), oxygen-carrying capacity, and whether the patient likely has an intrapulmonary shunt. They state that testing is useful to quantify the response to therapeutic or diagnostic interventions such as cardiopulmonary exercise testing, to monitor severity and progression of documented disease, and to assess the adequacy of circulatory response.

Studies agree

The ACR recommendation to test “as clinically indicated” is supported by studies showing that patient outcomes are not inferior for arterial blood gas testing when clinically indicated instead of daily, and that this practice is associated with fewer complications, less resource use, and reduced overall patient care costs.

A 2015 study compared the efficacy and safety of obtaining arterial blood gases based on clinical assessment vs daily in 300 critically ill patients.17 Overall, fewer samples were obtained per patient in the clinical assessment group than in the daily group (all patients 3.7 vs 5.5; ventilated patients 2.03 vs 6.12; P < .001 for both). In ventilated patients, there was a 60% decrease in arterial blood gas orders without affecting patient outcomes and safety, including a lower risk of complications and overall cost of care.

In another study, Martinez-Balzano et al18 evaluated the effect of guidelines they developed to optimize the use of arterial blood gas testing in their ICUs. These guidelines encouraged testing of arterial blood gases after an acute respiratory event or for a rational clinical concern, and discouraged testing for routine surveillance, after planned changes of positive end-expiratory pressure or inspired oxygen fraction on mechanical ventilation, for spontaneous breathing trials, or when a disorder was not suspected.

Compared with data collected before implementation, these guidelines reduced the number of arterial blood gas tests by 821.5 per month (41.5%), or approximately 1 test per patient per mechanical-ventilation day for each month (43.1%; P < .001). Appropriately indicated testing rose to 83.4% from a baseline of 67.5% (P = .002). Additionally, this approach was associated with saving 49 liters of blood, reducing ICU costs by $39,432, and freeing up 1,643 staff work hours for other tasks. There were no significant differences in days on mechanical ventilation, severity of illness, or mortality between the 2 periods.18

Extubation effects. Routine arterial blood gas testing has not been shown to affect extubation decisions in patients on mechanical ventilation. In a study of 83 patients who completed a spontaneous breathing trial (total of 100 trials), Salam et al19 found arterial blood gas values obtained during the trial did not change the extubation decision in 93% of the cases.

In a study of 54 extubations in 52 patients,20 65% of the extubations were performed without obtaining an arterial blood gas test after the patient completed a trial of spontaneous breathing. The extubation success rate was 94% for the entire group, and it was the same regardless of whether testing was done (94.7% vs 94.3%, respectively).

Alternatives to arterial blood gases

There are less-invasive means to obtain the information that comes from an arterial blood gas test.

Pulse oximetry is a rapid noninvasive tool that provides continuous assessment of peripheral arterial oxygen saturation as a surrogate marker for tissue arterial oxygenation. However, it cannot measure PaO2 or PaCO2.21

Transcutaneous carbon dioxide (PTCO2) monitoring is another continuous noninvasive alternative. The newer PTCO2 devices are useful in patients with acute respiratory failure and in critically ill patients on vasopressors or vasodilators. Studies have shown good correlation between PTCO2 and PaCO2.22,23

End-tidal carbon dioxide (PetCO2) is another alternative to estimate PaCO2. It can also be used to confirm endotracheal tube placement, during transportation, during procedures in which the patient is under conscious sedation, and to monitor the effectiveness of cardiopulmonary resuscitation and return of circulation after cardiac arrest. PetCO2 measurements are not as accurate as arterial blood gas testing owing to a difference of approximately 2 to 5 mm Hg between PaCO2 and PetCO2 in normal lungs due to alveolar dead space. This difference may be much higher depending on the clinical condition and the degree of alveolar dead space.21,24,25

Venous blood gases, which can be obtained from a peripheral or central venous catheter, are adequate to assess pH and partial pressure of carbon dioxide (PCO2) in hemodynamically stable patients. Walkey et al26 found that the accuracy of venous blood gas measurement to predict arterial blood gases was 90%. They recommended adjusting the venous pH up by 0.05 and the PCO2 down by 5 mm Hg to account for the positive bias of venous blood gases. A limitation of this method is that the values are not reliable in patients who are in shock.

These alternatives can be used as a substitute for daily arterial blood gases. However, in certain clinical scenarios, arterial blood gas measurement remains a necessary and useful clinical tool.

TAKE-HOME MESSAGE

Most scientific evidence suggests that chest radiographs and arterial blood gas measurement in patients undergoing mechanical ventilation—and critically ill, in general—are best done when clinically indicated rather than routinely on a daily basis. This will reduce cost and harm to patients that may result from these unnecessary tests and not adversely affect outcomes.

No, they are not required or needed, but daily radiography and arterial blood gas testing are common practice: eg, 60% of intensive care unit (ICU) patients get daily radiographs,1 even though results provide low diagnostic yield and are unlikely to alter patient management compared with testing only when indicated.

The Choosing Wisely campaign,2 a collaborative effort of a number of professional societies, advises against ordering these diagnostic tests daily because routine testing increases risks to patients and burdens the healthcare system. Instead, testing is recommended only in response to a specific clinical question, or when the test results will affect the patient’s treatment.

CHEST RADIOGRAPHS: DAILY VS CLINICALLY INDICATED

Chest radiographs enable practitioners to monitor the position of endotracheal tubes and central venous catheters, evaluate fluid status, follow up on abnormal findings, detect complications of procedures (such as a pneumothorax), and identify otherwise undetected conditions.

And daily chest radiographs often detect abnormalities. A 1991 study by Hall et al3 of 538 chest radiographs in 74 patients on mechanical ventilation reported that 30% of daily routine chest radiographs disclosed a new but minor finding (eg, a small change in endotracheal tube position or a small infiltrate). The new findings were major in 13 (17.6%) of the 74 patients (95% confidence interval [CI] 9%–26%). These included findings that required an immediate diagnostic or therapeutic intervention (eg, endotracheal tube below the tracheal carina, malposition of a catheter, pneumothorax, large pleural effusion).

But most studies say daily radiographs are not needed. In a large prospective study published in 2006, Graat et al4 evaluated the clinical value of 2,457 routine chest radiographs in 754 patients in a combined surgical and medical ICU. Daily chest radiographs revealed new or unexpected findings in 5.8% of cases, but only 2.2% warranted a change in therapy. No differences were found between the medical and surgical patients. The authors concluded that daily routine radiographs in ICU patients seldom reveal unexpected, clinically relevant abnormalities, and those findings rarely require urgent intervention.

A 2010 meta-analysis of 8 studies (7,078 patients) by Oba and Zaza5 compared on-demand and daily routine strategies of performing chest radiographs. They estimated that eliminating daily routine chest radiographs would not affect death rates in the hospital (odds ratio [OR] 1.02, 95% CI 0.89–1.17, P = .78) or the ICU (OR 0.92, 95% CI 0.76–1.11, P = .4). They also found no significant differences in length of stay or duration of mechanical ventilation. This meta-analysis suggests that routine radiographs can be eliminated without adversely affecting outcomes in ICU patients.

A larger meta-analysis (9 trials, 39,358 radiographs, 9,611 patients) published in 2012 by Ganapathy et al6 also found no harm associated with restrictive radiography protocols. These investigators compared a daily chest radiography protocol against a protocol based on clinical indications. The primary outcome was the mortality rate in the ICU; secondary outcomes were the mortality rate in the hospital, the length of stay in the ICU, and duration of mechanical ventilation. They found no differences between routine and restrictive strategies in terms of ICU mortality (risk ratio [RR] 1.04, 95% CI 0.84–1.28, P = .72), hospital mortality (RR 0.98, 95% CI 0.68–1.41, P = .91), or other secondary outcomes.

Clinically indicated testing is better

The conclusion from these studies is that routine chest radiographs in patients undergoing mechanical ventilation does not improve patient outcomes, and thus, a clinically indicated protocol is preferred.

Furthermore, routine daily radiographs have adverse effects such as more cumulative radiation exposure to the patient7 and greater risk of accidental removal of devices (eg, catheters, tubes).8 Another concern is a higher risk of hospital-associated infections from bacterial spread from caregivers’ hands.9

Finally, daily radiographs increase the use of healthcare resources and expenditures. In a 2011 study, Gershengorn et al1 estimated that adopting a clinically indicated radiography strategy could save more than $144 million annually in the United States.

The ACR agrees. Appropriateness criteria published by the American College of Radiology (ACR) in 201510 recommend against routine daily chest radiographs in the ICU, in keeping with the findings of the critical care community. The ACR recommends an initial radiograph at admission to the ICU. However, follow-up radiographs should be obtained only for specific clinical indications, including a change in the patient’s clinical condition or to check for proper placement of endotracheal or nasogastric or orogastric tubes, pulmonary arterial catheters, central venous catheters, chest tubes, and other life-support devices.

Ultrasonography as an alternative

Ultrasonography is widely available and provides an alternative to chest radiography for detecting significant abnormalities in patients on mechanical ventilation without exposing them to radiation and using relatively fewer resources.

A 2012 meta-analysis (8 studies, 1,048 patients) found that bedside ultrasonography reliably detects pneumothorax.11 It can also provide a rapid diagnosis of the cause of acute respiratory failure such as pneumonia or pulmonary edema.12 Ultrasonography, with the appropriate expertise, can also confirm the position of an endotracheal tube13 or central venous catheter.14

 

 

ARTERIAL BLOOD GAS TESTING: DAILY VS CLINICALLY INDICATED

Arterial blood gas testing has value for managing patients undergoing mechanical ventilation, and it is one of the most commonly performed diagnostic tests in the ICU. It provides reliable information about the patient’s oxygenation and acid-base status. It is commonly requested when changing ventilator settings.

Downsides. Arterial blood gas measurements account for 10% to 20% of the cost incurred during ICU stay.15 In addition, they require an arterial puncture—an invasive procedure associated with potentially serious complications such as occlusion of the artery, digital embolization leading to digital ischemia, local infection, pseudoaneurysm, hematoma, bleeding, and skin necrosis.

Is daily testing needed?

Guidelines say no. The 2013 American Association for Respiratory Care16 guidelines suggest that arterial blood gas testing should be based on the clinical assessment of the patient. They recommend blood gas analysis to evaluate the patient’s ventilatory status (reflected by the partial pressure of arterial carbon dioxide [PaCO2], acid-base status (reflected by pH), arterial oxygenation (partial pressure of arterial oxygen [PaO2] and oxyhemoglobin saturation), oxygen-carrying capacity, and whether the patient likely has an intrapulmonary shunt. They state that testing is useful to quantify the response to therapeutic or diagnostic interventions such as cardiopulmonary exercise testing, to monitor severity and progression of documented disease, and to assess the adequacy of circulatory response.

Studies agree

The ACR recommendation to test “as clinically indicated” is supported by studies showing that patient outcomes are not inferior for arterial blood gas testing when clinically indicated instead of daily, and that this practice is associated with fewer complications, less resource use, and reduced overall patient care costs.

A 2015 study compared the efficacy and safety of obtaining arterial blood gases based on clinical assessment vs daily in 300 critically ill patients.17 Overall, fewer samples were obtained per patient in the clinical assessment group than in the daily group (all patients 3.7 vs 5.5; ventilated patients 2.03 vs 6.12; P < .001 for both). In ventilated patients, there was a 60% decrease in arterial blood gas orders without affecting patient outcomes and safety, including a lower risk of complications and overall cost of care.

In another study, Martinez-Balzano et al18 evaluated the effect of guidelines they developed to optimize the use of arterial blood gas testing in their ICUs. These guidelines encouraged testing of arterial blood gases after an acute respiratory event or for a rational clinical concern, and discouraged testing for routine surveillance, after planned changes of positive end-expiratory pressure or inspired oxygen fraction on mechanical ventilation, for spontaneous breathing trials, or when a disorder was not suspected.

Compared with data collected before implementation, these guidelines reduced the number of arterial blood gas tests by 821.5 per month (41.5%), or approximately 1 test per patient per mechanical-ventilation day for each month (43.1%; P < .001). Appropriately indicated testing rose to 83.4% from a baseline of 67.5% (P = .002). Additionally, this approach was associated with saving 49 liters of blood, reducing ICU costs by $39,432, and freeing up 1,643 staff work hours for other tasks. There were no significant differences in days on mechanical ventilation, severity of illness, or mortality between the 2 periods.18

Extubation effects. Routine arterial blood gas testing has not been shown to affect extubation decisions in patients on mechanical ventilation. In a study of 83 patients who completed a spontaneous breathing trial (total of 100 trials), Salam et al19 found arterial blood gas values obtained during the trial did not change the extubation decision in 93% of the cases.

In a study of 54 extubations in 52 patients,20 65% of the extubations were performed without obtaining an arterial blood gas test after the patient completed a trial of spontaneous breathing. The extubation success rate was 94% for the entire group, and it was the same regardless of whether testing was done (94.7% vs 94.3%, respectively).

Alternatives to arterial blood gases

There are less-invasive means to obtain the information that comes from an arterial blood gas test.

Pulse oximetry is a rapid noninvasive tool that provides continuous assessment of peripheral arterial oxygen saturation as a surrogate marker for tissue arterial oxygenation. However, it cannot measure PaO2 or PaCO2.21

Transcutaneous carbon dioxide (PTCO2) monitoring is another continuous noninvasive alternative. The newer PTCO2 devices are useful in patients with acute respiratory failure and in critically ill patients on vasopressors or vasodilators. Studies have shown good correlation between PTCO2 and PaCO2.22,23

End-tidal carbon dioxide (PetCO2) is another alternative to estimate PaCO2. It can also be used to confirm endotracheal tube placement, during transportation, during procedures in which the patient is under conscious sedation, and to monitor the effectiveness of cardiopulmonary resuscitation and return of circulation after cardiac arrest. PetCO2 measurements are not as accurate as arterial blood gas testing owing to a difference of approximately 2 to 5 mm Hg between PaCO2 and PetCO2 in normal lungs due to alveolar dead space. This difference may be much higher depending on the clinical condition and the degree of alveolar dead space.21,24,25

Venous blood gases, which can be obtained from a peripheral or central venous catheter, are adequate to assess pH and partial pressure of carbon dioxide (PCO2) in hemodynamically stable patients. Walkey et al26 found that the accuracy of venous blood gas measurement to predict arterial blood gases was 90%. They recommended adjusting the venous pH up by 0.05 and the PCO2 down by 5 mm Hg to account for the positive bias of venous blood gases. A limitation of this method is that the values are not reliable in patients who are in shock.

These alternatives can be used as a substitute for daily arterial blood gases. However, in certain clinical scenarios, arterial blood gas measurement remains a necessary and useful clinical tool.

TAKE-HOME MESSAGE

Most scientific evidence suggests that chest radiographs and arterial blood gas measurement in patients undergoing mechanical ventilation—and critically ill, in general—are best done when clinically indicated rather than routinely on a daily basis. This will reduce cost and harm to patients that may result from these unnecessary tests and not adversely affect outcomes.

References
  1. Gershengorn HB, Wunsch H, Scales DC, Rubenfeld GD. Trends in use of daily chest radiographs among US adults receiving mechanical ventilation. JAMA Netw Open 2018; 1(4):e181119. doi:10.1001/jamanetworkopen.2018.1119
  2. American Board of Internal Medicine Foundation. Choosing Wisely. http://www.choosingwisely.org/clinician-lists/critical-care-societies-collaborative-regular-diagnostic-tests. Accessed August 18, 2019.
  3. Hall JB, White SR, Karrison T. Efficacy of daily routine chest radiographs in intubated, mechanically ventilated patients. Crit Care Med 1991; 19(5):689–693. pmid:2026031
  4. Graat ME, Choi G, Wolthuis EK, et al. The clinical value of daily routine chest radiographs in a mixed medical-surgical intensive care unit is low. Crit Care 2006; 10(1):R11. doi:10.1186/cc3955
  5. Oba Y, Zaza T. Abandoning daily routine chest radiography in the intensive care unit: meta-analysis. Radiology 2010; 255(2):386–395. doi:10.1148/radiol.10090946
  6. Ganapathy A, Adhikari NK, Spiegelman J, Scales DC. Routine chest x-rays in intensive care units: a systematic review and meta-analysis. Crit Care 2012; 16(2):R68. doi:10.1186/cc11321
  7. Krishnan S, Moghekar A, Duggal A, et al. Radiation exposure in the medical ICU: predictors and characteristics. Chest 2018; 153(5):1160–1168. doi:10.1016/j.chest.2018.01.019
  8. Hejblum G, Chalumeau-Lemoine L, Ioos V, et al. Comparison of routine and on-demand prescription of chest radiographs in mechanically ventilated adults: a multicentre, cluster-randomised, two-period crossover study. Lancet 2009; 374(9702):1687–1693. doi:10.1016/S0140-6736(09)61459-8
  9. Levin PD, Shatz O, Sviri S, et al. Contamination of portable radiograph equipment with resistant bacteria in the ICU. Chest 2009; 136(2):426–432. doi:10.1378/chest.09-0049
  10. Suh RD, Genshaft SJ, Kirsch J, et al. ACR Appropriateness Criteria® Intensive Care Unit Patients. J Thorac Imaging 2015; 30(6):W63–W65. doi:10.1097/RTI.0000000000000174
  11. Alrajhi K, Woo MY, Vaillancourt C. Test characteristics of ultrasonography for the detection of pneumothorax: a systematic review and meta-analysis. Chest 2012; 141(3):703–708. doi:10.1378/chest.11-0131
  12. Lichetenstein DA, Meziere GA. Relevance of lung ultrasound in the diagnosis of acute respiratory failure: the BLUE protocol. Chest 2008; 134(1):117–125. doi:10.1378/chest.07-2800
  13. Das SK, Choupoo NS, Haldar R, Lahkar A. Transtracheal ultrasound for verification of endotracheal tube placement: a systematic review and meta-analysis. Can J Anaesth 2015; 62(4):413–423. doi:10.1007/s12630-014-0301-z
  14. Ablordeppey EA, Drewry AM, Beyer AB, et al. Diagnostic accuracy of central venous catheter confirmation by bedside ultrasound versus chest radiography in critically ill patients: a systematic review and meta-analysis. Crit Care Med 2017; 45(4):715–724. doi:10.1097/CCM.0000000000002188
  15. DellaVolpe JD, Chakraborti C, Cerreta K, et al. Effects of implementing a protocol for arterial blood gas use on ordering practices and diagnostic yield. Healthc (Amst) 2014; 2(2):130–135. doi:10.1016/j.hjdsi.2013.09.006
  16. Davis MD, Walsh BK, Sittig SE, Restrepo RD. AARC clinical practice guideline: blood gas analysis and hemoximetry. Respir Care 2013; 58(10):1694–1703. doi:10.4187/respcare.02786
  17. Blum FE, Lund ET, Hall HA, Tachauer AD, Chedrawy EG, Zilberstein J. Reevaluation of the utilization of arterial blood gas analysis in the intensive care unit: effects on patient safety and patient outcome. J Crit Care 2015; 30(2):438.e1–e5. doi:10.1016/j.jcrc.2014.10.025
  18. Martínez-Balzano CD, Oliveira P, O’Rourke M, Hills L, Sosa AF; Critical Care Operations Committee of the UMass Memorial Healthcare Center. An educational intervention optimizes the use of arterial blood gas determinations across ICUs from different specialties: a quality-improvement study. Chest 2017; 151(3):579–585. doi:10.1016/j.chest.2016.10.035
  19. Salam A, Smina M, Gada P, et al. The effect of arterial blood gas values on extubation decisions. Respir Care 2003; 48(11):1033–1037. pmid:14585115
  20. Pawson SR, DePriest JL. Are blood gases necessary in mechanically ventilated patients who have successfully completed a spontaneous breathing trial? Respir Care 2004; 49(11):1316–1319. pmid:15507165
  21. Soubani AO. Noninvasive monitoring of oxygen and carbon dioxide. Am J Emerg Med 2001; 19(2):141–146. doi:10.1053/ajem.2001.21353
  22. Nicolini A, Ferrari MB. Evaluation of a transcutaneous carbon dioxide monitor in patients with acute respiratory failure. Ann Thorac Med 2011; 6(4):217–220. doi:10.4103/1817-1737.84776
  23. Bendjelid K, Schütz N, Stotz M, Gerard I, Suter PM, Romand JA. Transcutaneous PCO2 monitoring in critically ill adults: clinical evaluation of a new sensor. Crit Care Med 2005; 33(10):2203–2206. pmid:16215371
  24. Huttmann SE, Windisch W, Storre JH. Techniques for the measurement and monitoring of carbon dioxide in the blood. Ann Am Thorac Soc 2014; 11(4):645–652. doi:10.1513/AnnalsATS.201311-387FR
  25. McSwain SD, Hamel DS, Smith PB, et al. End-tidal and arterial carbon dioxide measurements correlate across all levels of physiologic dead space. Respir Care 2010; 55(3):288–293. pmid:20196877
  26. Walkey AJ, Farber HW, O'Donnell C, Cabral H, Eagan JS, Philippides GJ. The accuracy of the central venous blood gas for acid-base monitoring. J Intensive Care Med 2010; 25(2):104–110. doi:10.1177/0885066609356164
References
  1. Gershengorn HB, Wunsch H, Scales DC, Rubenfeld GD. Trends in use of daily chest radiographs among US adults receiving mechanical ventilation. JAMA Netw Open 2018; 1(4):e181119. doi:10.1001/jamanetworkopen.2018.1119
  2. American Board of Internal Medicine Foundation. Choosing Wisely. http://www.choosingwisely.org/clinician-lists/critical-care-societies-collaborative-regular-diagnostic-tests. Accessed August 18, 2019.
  3. Hall JB, White SR, Karrison T. Efficacy of daily routine chest radiographs in intubated, mechanically ventilated patients. Crit Care Med 1991; 19(5):689–693. pmid:2026031
  4. Graat ME, Choi G, Wolthuis EK, et al. The clinical value of daily routine chest radiographs in a mixed medical-surgical intensive care unit is low. Crit Care 2006; 10(1):R11. doi:10.1186/cc3955
  5. Oba Y, Zaza T. Abandoning daily routine chest radiography in the intensive care unit: meta-analysis. Radiology 2010; 255(2):386–395. doi:10.1148/radiol.10090946
  6. Ganapathy A, Adhikari NK, Spiegelman J, Scales DC. Routine chest x-rays in intensive care units: a systematic review and meta-analysis. Crit Care 2012; 16(2):R68. doi:10.1186/cc11321
  7. Krishnan S, Moghekar A, Duggal A, et al. Radiation exposure in the medical ICU: predictors and characteristics. Chest 2018; 153(5):1160–1168. doi:10.1016/j.chest.2018.01.019
  8. Hejblum G, Chalumeau-Lemoine L, Ioos V, et al. Comparison of routine and on-demand prescription of chest radiographs in mechanically ventilated adults: a multicentre, cluster-randomised, two-period crossover study. Lancet 2009; 374(9702):1687–1693. doi:10.1016/S0140-6736(09)61459-8
  9. Levin PD, Shatz O, Sviri S, et al. Contamination of portable radiograph equipment with resistant bacteria in the ICU. Chest 2009; 136(2):426–432. doi:10.1378/chest.09-0049
  10. Suh RD, Genshaft SJ, Kirsch J, et al. ACR Appropriateness Criteria® Intensive Care Unit Patients. J Thorac Imaging 2015; 30(6):W63–W65. doi:10.1097/RTI.0000000000000174
  11. Alrajhi K, Woo MY, Vaillancourt C. Test characteristics of ultrasonography for the detection of pneumothorax: a systematic review and meta-analysis. Chest 2012; 141(3):703–708. doi:10.1378/chest.11-0131
  12. Lichetenstein DA, Meziere GA. Relevance of lung ultrasound in the diagnosis of acute respiratory failure: the BLUE protocol. Chest 2008; 134(1):117–125. doi:10.1378/chest.07-2800
  13. Das SK, Choupoo NS, Haldar R, Lahkar A. Transtracheal ultrasound for verification of endotracheal tube placement: a systematic review and meta-analysis. Can J Anaesth 2015; 62(4):413–423. doi:10.1007/s12630-014-0301-z
  14. Ablordeppey EA, Drewry AM, Beyer AB, et al. Diagnostic accuracy of central venous catheter confirmation by bedside ultrasound versus chest radiography in critically ill patients: a systematic review and meta-analysis. Crit Care Med 2017; 45(4):715–724. doi:10.1097/CCM.0000000000002188
  15. DellaVolpe JD, Chakraborti C, Cerreta K, et al. Effects of implementing a protocol for arterial blood gas use on ordering practices and diagnostic yield. Healthc (Amst) 2014; 2(2):130–135. doi:10.1016/j.hjdsi.2013.09.006
  16. Davis MD, Walsh BK, Sittig SE, Restrepo RD. AARC clinical practice guideline: blood gas analysis and hemoximetry. Respir Care 2013; 58(10):1694–1703. doi:10.4187/respcare.02786
  17. Blum FE, Lund ET, Hall HA, Tachauer AD, Chedrawy EG, Zilberstein J. Reevaluation of the utilization of arterial blood gas analysis in the intensive care unit: effects on patient safety and patient outcome. J Crit Care 2015; 30(2):438.e1–e5. doi:10.1016/j.jcrc.2014.10.025
  18. Martínez-Balzano CD, Oliveira P, O’Rourke M, Hills L, Sosa AF; Critical Care Operations Committee of the UMass Memorial Healthcare Center. An educational intervention optimizes the use of arterial blood gas determinations across ICUs from different specialties: a quality-improvement study. Chest 2017; 151(3):579–585. doi:10.1016/j.chest.2016.10.035
  19. Salam A, Smina M, Gada P, et al. The effect of arterial blood gas values on extubation decisions. Respir Care 2003; 48(11):1033–1037. pmid:14585115
  20. Pawson SR, DePriest JL. Are blood gases necessary in mechanically ventilated patients who have successfully completed a spontaneous breathing trial? Respir Care 2004; 49(11):1316–1319. pmid:15507165
  21. Soubani AO. Noninvasive monitoring of oxygen and carbon dioxide. Am J Emerg Med 2001; 19(2):141–146. doi:10.1053/ajem.2001.21353
  22. Nicolini A, Ferrari MB. Evaluation of a transcutaneous carbon dioxide monitor in patients with acute respiratory failure. Ann Thorac Med 2011; 6(4):217–220. doi:10.4103/1817-1737.84776
  23. Bendjelid K, Schütz N, Stotz M, Gerard I, Suter PM, Romand JA. Transcutaneous PCO2 monitoring in critically ill adults: clinical evaluation of a new sensor. Crit Care Med 2005; 33(10):2203–2206. pmid:16215371
  24. Huttmann SE, Windisch W, Storre JH. Techniques for the measurement and monitoring of carbon dioxide in the blood. Ann Am Thorac Soc 2014; 11(4):645–652. doi:10.1513/AnnalsATS.201311-387FR
  25. McSwain SD, Hamel DS, Smith PB, et al. End-tidal and arterial carbon dioxide measurements correlate across all levels of physiologic dead space. Respir Care 2010; 55(3):288–293. pmid:20196877
  26. Walkey AJ, Farber HW, O'Donnell C, Cabral H, Eagan JS, Philippides GJ. The accuracy of the central venous blood gas for acid-base monitoring. J Intensive Care Med 2010; 25(2):104–110. doi:10.1177/0885066609356164
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Are daily chest radiographs and arterial blood gas tests required in ICU patients on mechanical ventilation?
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Should we stop aspirin before noncardiac surgery?

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Should we stop aspirin before noncardiac surgery?

In patients with cardiac stents, do not stop aspirin. If the risk of bleeding outweighs the benefit (eg, with intracranial procedures), an informed discussion involving the surgeon, cardiologist, and patient is critical to ascertain risks vs benefits.

See related editorial

In patients using aspirin for secondary prevention, the decision depends on the patient’s cardiac status and an assessment of risk vs benefit. Aspirin has no role in patients undergoing noncardiac surgery who are at low risk of a major adverse cardiac event.1,2

Aspirin used for secondary prevention reduces rates of death from vascular causes,3 but data on the magnitude of benefit in the perioperative setting are still evolving. In patients with coronary stents, continuing aspirin is beneficial,4,5 whereas stopping it is associated with an increased risk of acute stent thrombosis, which causes significant morbidity and mortality.6

SURGERY AND THROMBOTIC RISK: WHY CONSIDER ASPIRIN?

The Vascular Events in Noncardiac Surgery Patients Cohort Evaluation (VISION) study7 prospectively screened 15,133 patients for myocardial injury with troponin T levels daily for the first 3 consecutive postoperative days; 1,263 (8%) of the patients had a troponin elevation of 0.03 ng/mL or higher. The 30-day mortality rate in this group was 9.8%, compared with 1.1% in patients with a troponin T level of less than 0.03 ng/mL (odds ratio 10.07; 95% confidence interval [CI] 7.84–12.94; P < .001).8 The higher the peak troponin T concentration, the higher the risk of death within 30 days:

  • 0.01 ng/mL or less, risk 1.0%
  • 0.02 ng/mL, risk 4.0%
  • 0.03 to 0.29 ng/mL, risk 9.3%
  • 0.30 ng/mL or greater, risk 16.9%.7

Myocardial injury is a common postoperative vascular complication.7 Myocardial infarction (MI) or injury perioperatively increases the risk of death: 1 in 10 patients dies within 30 days after surgery.8

Surgery creates substantial physiologic stress through factors such as fasting, anesthesia, intubation, surgical trauma, extubation, and pain. It promotes coagulation9 and inflammation with activation of platelets,10 potentially leading to thrombosis.11 Coronary thrombosis secondary to plaque rupture11,12 can result in perioperative MI. Perioperative hemodynamic variability, anemia, and hypoxia can lead to demand-supply mismatch and also cause cardiac ischemia.

Aspirin is an antiplatelet agent that irreversibly inhibits platelet aggregation by blocking the formation of cyclooxygenase. It has been used for several decades as an antithrombotic agent in primary and secondary prevention. However, its benefit in primary prevention is uncertain, and the magnitude of antithrombotic benefit must be balanced against the risk of bleeding.

The Antithrombotic Trialists’ Collaboration13 performed a systematic review of 6 primary prevention trials involving 95,000 patients and found that aspirin therapy was associated with a 12% reduction in serious vascular events, which occurred in 0.51% of patients taking aspirin per year vs 0.57% of controls (P = .0001). However, aspirin also increased the risk of major bleeding, at a rate of 0.10% vs 0.07% per year (P < .0001), with 2 bleeding events for every avoided vascular event.13

WILL ASPIRIN PROTECT PATIENTS AT CARDIAC RISK?

The second Perioperative Ischemic Evaluation trial (POISE 2),1 in patients with atherosclerotic disease or at risk for it, found that giving aspirin in the perioperative period did not reduce the rate of death or nonfatal MI, but increased the risk of a major bleeding event.

The trial included 10,010 patients undergoing noncardiac surgery who were randomly assigned to receive aspirin or placebo. The aspirin arm included 2 groups: patients who were not on aspirin (initiation arm), and patients on aspirin at the time of randomization (continuation arm).

Death or nonfatal MI (the primary outcome) occurred in 7.0% of patients on aspirin vs 7.1% of patients receiving placebo (hazard ratio [HR] 0.99, 95% CI 0.86–1.15, P = .92). The risk of major bleeding was 4.6% in the aspirin group vs 3.8% in the placebo group (HR 1.23, 95% CI 1.01–1.49, P = .04).1

George et al,14 in a prospective observational study in a single tertiary care center, found that fewer patients with myocardial injury in noncardiac surgery died if they took aspirin or clopidogrel postoperatively. Conversely, lack of antithrombotic therapy was an independent predictor of death (P < .001). The mortality rate in patients with myocardial injury who were on antithrombotic therapy postoperatively was 6.7%, compared with 12.1% in those without postoperative antithrombotic therapy (estimated number needed to treat, 19).14

 

 

PATIENTS WITH CORONARY STENTS UNDERGOING NONCARDIAC SURGERY

Percutaneous coronary intervention (PCI) accounts for 3.6% of all operating-room procedures in the United States,15 and 20% to 35% of patients who undergo PCI undergo noncardiac surgery within 2 years of stent implantation.16,17

Antiplatelet therapy is discontinued in about 20% of patients with previous PCI who undergo noncardiac surgery.18

Observational data have shown that stopping antiplatelet therapy in patients with previous PCI with stent placement who undergo noncardiac surgery is the single most important predictor of stent thrombosis and death.19–21 The risk increases if the interval between stent implantation and surgery is shorter, especially within 180 days.16,17 Patients who have stent thrombosis are at significantly higher risk of death.

Graham et al4 conducted a subgroup analysis of the POISE 2 trial comparing aspirin and placebo in 470 patients who had undergone PCI (427 had stent placement, and the rest had angioplasty or an unspecified type of PCI); 234 patients received aspirin and 236 placebo. The median time from stent implantation to surgery was 5.3 years.

Of the patients in the aspirin arm, 14 (6%) had the primary outcome of death or nonfatal MI compared with 27 patients (11.5%) in the placebo arm (absolute risk reduction 5.5%, 95% CI 0.4%–10.5%). The result, which differed from that in the primary trial,1 was due to reduction in MI in the PCI subgroup on aspirin. PCI patients who were on aspirin did not have increased bleeding risk. This subgroup analysis, albeit small and limited, suggests that continuing low-dose aspirin in patients with previous PCI, irrespective of the type of stent or the time from stent implantations, minimizes the risk of perioperative MI.

GUIDELINES AND RECOMMENDATIONS

Routine perioperative use of aspirin increases the risk of bleeding without a reduction in ischemic events.1 Patients with prior PCI are at increased risk of acute stent thrombosis when antiplatelet medications are discontinued.20,21 Available data, although limited, support continuing low-dose aspirin without interruption in the perioperative period in PCI patients,4 as do the guidelines from the American College of Cardiology.5

Figure 1. Proposed perioperative management of aspirin and antiplatelet therapy in patients undergoing noncardiac surgery.
Figure 1. Proposed perioperative management of aspirin and antiplatelet therapy in patients undergoing noncardiac surgery.

We propose a management algorithm for patients undergoing noncardiac surgery on antiplatelet therapy that takes into consideration whether the surgery is urgent, elective, or time-sensitive (Figure 1). It is imperative to involve the cardiologist, surgeon, anesthesiologist, and the patient in the decision-making process.

In the perioperative setting for patients undergoing noncardiac surgery:

  • Discontinue aspirin in patients without coronary heart disease, as bleeding risk outweighs benefit.
  • Consider aspirin in patients at high risk for a major adverse cardiac event if benefits outweigh risk.
  • Continue low-dose aspirin without interruption in patients with a coronary stent, irrespective of the type of stent.
  • If a patient has had PCI with stent placement but is not currently on aspirin, talk with the patient and the treating cardiologist to find out why, and initiate aspirin if no contraindications exist.
References
  1. Devereaux PJ, Mrkobrada M, Sessler DI, et al; POISE-2 Investigators. Aspirin in patients undergoing noncardiac surgery. N Engl J Med 2014; 370(16):1494–1503. doi:10.1056/NEJMoa1401105
  2. Fleisher LA, Fleischmann KE, Auerbach AD, et al; American College of Cardiology; American Heart Association. 2014 ACC/AHA guideline on perioperative cardiovascular evaluation and management of patients undergoing noncardiac surgery: a report of the American College of Cardiology/American Heart Association Task Force on practice guidelines. J Am Coll Cardiol 2014; 64(22):e77–e137. doi:10.1016/j.jacc.2014.07.944
  3. Collaborative overview of randomised trials of antiplatelet therapy—I: prevention of death, myocardial infarction, and stroke by prolonged antiplatelet therapy in various categories of patients. Antiplatelet Trialists’ Collaboration. BMJ 1994; 308(6921):81–106. pmid:8298418
  4. Graham MM, Sessler DI, Parlow JL, et al. Aspirin in patients with previous percutaneous coronary intervention undergoing noncardiac surgery. Ann Intern Med 2018; 168(4):237–244. doi:10.7326/M17-2341
  5. Levine GN, Bates ER, Bittl JA, et al. 2016 ACC/AHA guideline focused update on duration of dual antiplatelet therapy in patients with coronary artery disease: a report of the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines. J Am Coll Cardiol 2016; 68(10):1082–1115. doi:10.1016/j.jacc.2016.03.513
  6. Albaladejo P, Marret E, Samama CM, et al. Non-cardiac surgery in patients with coronary stents: the RECO study. Heart 2011; 97(19):1566–1572. doi:10.1136/hrt.2011.224519
  7. Vascular Events in Noncardiac Surgery Patients Cohort Evaluation (VISION) Study Investigators; Devereaux PJ, Chan MT, Alonso-Coello P, et al. Association between postoperative troponin levels and 30-day mortality among patients undergoing noncardiac surgery. JAMA 2012; 307(21):2295–2304. doi:10.1001/jama.2012.5502
  8. Botto F, Alonso-Coello P, Chan MT, et al. Myocardial injury after noncardiac surgery: a large, international, prospective cohort study establishing diagnostic criteria, characteristics, predictors, and 30-day outcomes. Anesthesiology 2014; 120(3):564–578. doi:10.1097/ALN.0000000000000113
  9. Gorka J, Polok K, Iwaniec T, et al. Altered preoperative coagulation and fibrinolysis are associated with myocardial injury after non-cardiac surgery. Br J Anaesth 2017; 118(5):713–719. doi:10.1093/bja/aex081
  10. Rajagopalan S, Ford I, Bachoo P, et al. Platelet activation, myocardial ischemic events and postoperative non-response to aspirin in patients undergoing major vascular surgery. J Thromb Haemost 2007; 5(10):2028–2035. doi:10.1111/j.1538-7836.2007.02694.x
  11. Priebe HJ. Triggers of perioperative myocardial ischaemia and infarction. Br J Anaesth 2004; 93(1):9–20. doi:10.1093/bja/aeh147
  12. Devereaux PJ, Goldman L, Cook DJ, Gilbert K, Leslie K, Guyatt GH. Perioperative cardiac events in patients undergoing noncardiac surgery: a review of the magnitude of the problem, the pathophysiology of the events and methods to estimate and communicate risk. CMAJ 2005; 173(6):627–634. doi:10.1503/cmaj.050011
  13. Antithrombotic Trialists’ (ATT) Collaboration; Baigent C, Blackwell L, Collins R, et al. Aspirin in the primary and secondary prevention of vascular disease: collaborative meta-analysis of individual participant data from randomised trials. Lancet 2009; 373(9678):1849–1860. doi:10.1016/S0140-6736(09)60503-1
  14. George R, Menon VP, Edathadathil F, et al. Myocardial injury after noncardiac surgery—incidence and predictors from a prospective observational cohort study at an Indian tertiary care centre. Medicine (Baltimore) 2018; 97(19):e0402. doi:10.1097/MD.0000000000010402
  15. Weiss AJ, Elixhauser A, Andrews RM; Healthcare Cost and Utilization Project (HCUP). Characteristics of operating room procedures in US hospitals, 2011: statistical brief #170. https://hcup-us.ahrq.gov/reports/statbriefs/sb170-Operating-Room-Procedures-United-States-2011.jsp. Accessed May 3, 2019.
  16. Hawn MT, Graham LA, Richman JS, Itani KM, Henderson WG, Maddox TM. Risk of major adverse cardiac events following noncardiac surgery in patients with coronary stents. JAMA 2013; 310(14):1462–1472. doi:10.1001/jama.2013.278787
  17. Wijeysundera DN, Wijeysundera HC, Yun L, et al. Risk of elective major noncardiac surgery after coronary stent insertion: a population-based study. Circulation 2012; 126(11):1355–1362. doi:10.1161/CIRCULATIONAHA.112.102715
  18. Rossini R, Capodanno D, Lettieri C, et al. Prevalence, predictors, and long-term prognosis of premature discontinuation of oral antiplatelet therapy after drug eluting stent implantation. Am J Cardiol 2011; 107(2):186–194. doi:10.1016/j.amjcard.2010.08.067
  19. Eisenberg MJ, Richard PR, Libersan D, Filion KB. Safety of short-term discontinuation of antiplatelet therapy in patients with drug-eluting stents. Circulation 2009; 119(12):1634–1642. doi:10.1161/CIRCULATIONAHA.108.813667
  20. Iakovou I, Schmidt T, Bonizzoni E, et al. Incidence, predictors, and outcome of thrombosis after successful implantation of drug-eluting stents. JAMA 2005; 293(17):2126–2130. doi:10.1001/jama.293.17.2126
  21. Park DW, Park SW, Park KH, et al. Frequency of and risk factors for stent thrombosis after drug-eluting stent implantation during long-term follow-up. Am J Cardiol 2006; 98(3):352–356. doi:10.1016/j.amjcard.2006.02.039
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Anbazhagan Prabhakaran, MD, MRCP (Edin), FACP
Department of Hospital Medicine, Cleveland Clinic; Clinical Assistant Professor, Cleveland Clinic Lerner College of Medicine of Case Western Reserve University; Cleveland, OH

Christopher Whinney, MD, SFHM, FACP
Chairman, Department of Hospital Medicine, Cleveland Clinic; Clinical Assistant Professor, Cleveland Clinic Lerner College of Medicine of Case Western Reserve University; Cleveland, OH

Address: Anbazhagan Prabhakaran, MD, MRCP (Edin), FACP, Department of Hospital Medicine, M2 Annex, Cleveland Clinic, 9500 Euclid Avenue, Cleveland OH 44195; [email protected]

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Cleveland Clinic Journal of Medicine - 86(8)
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518-521
Legacy Keywords
aspirin, surgery, perioperative medication, prevention, stent thrombosis, VISION study, POISE study, myocardial injury after noncardiac surgery, MINS, bleeding, percutaneous coronary intervention, antiplatelet therapy, Anbazhagan Prabhakaran, Christopher Whinney
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Anbazhagan Prabhakaran, MD, MRCP (Edin), FACP
Department of Hospital Medicine, Cleveland Clinic; Clinical Assistant Professor, Cleveland Clinic Lerner College of Medicine of Case Western Reserve University; Cleveland, OH

Christopher Whinney, MD, SFHM, FACP
Chairman, Department of Hospital Medicine, Cleveland Clinic; Clinical Assistant Professor, Cleveland Clinic Lerner College of Medicine of Case Western Reserve University; Cleveland, OH

Address: Anbazhagan Prabhakaran, MD, MRCP (Edin), FACP, Department of Hospital Medicine, M2 Annex, Cleveland Clinic, 9500 Euclid Avenue, Cleveland OH 44195; [email protected]

Author and Disclosure Information

Anbazhagan Prabhakaran, MD, MRCP (Edin), FACP
Department of Hospital Medicine, Cleveland Clinic; Clinical Assistant Professor, Cleveland Clinic Lerner College of Medicine of Case Western Reserve University; Cleveland, OH

Christopher Whinney, MD, SFHM, FACP
Chairman, Department of Hospital Medicine, Cleveland Clinic; Clinical Assistant Professor, Cleveland Clinic Lerner College of Medicine of Case Western Reserve University; Cleveland, OH

Address: Anbazhagan Prabhakaran, MD, MRCP (Edin), FACP, Department of Hospital Medicine, M2 Annex, Cleveland Clinic, 9500 Euclid Avenue, Cleveland OH 44195; [email protected]

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Related Articles

In patients with cardiac stents, do not stop aspirin. If the risk of bleeding outweighs the benefit (eg, with intracranial procedures), an informed discussion involving the surgeon, cardiologist, and patient is critical to ascertain risks vs benefits.

See related editorial

In patients using aspirin for secondary prevention, the decision depends on the patient’s cardiac status and an assessment of risk vs benefit. Aspirin has no role in patients undergoing noncardiac surgery who are at low risk of a major adverse cardiac event.1,2

Aspirin used for secondary prevention reduces rates of death from vascular causes,3 but data on the magnitude of benefit in the perioperative setting are still evolving. In patients with coronary stents, continuing aspirin is beneficial,4,5 whereas stopping it is associated with an increased risk of acute stent thrombosis, which causes significant morbidity and mortality.6

SURGERY AND THROMBOTIC RISK: WHY CONSIDER ASPIRIN?

The Vascular Events in Noncardiac Surgery Patients Cohort Evaluation (VISION) study7 prospectively screened 15,133 patients for myocardial injury with troponin T levels daily for the first 3 consecutive postoperative days; 1,263 (8%) of the patients had a troponin elevation of 0.03 ng/mL or higher. The 30-day mortality rate in this group was 9.8%, compared with 1.1% in patients with a troponin T level of less than 0.03 ng/mL (odds ratio 10.07; 95% confidence interval [CI] 7.84–12.94; P < .001).8 The higher the peak troponin T concentration, the higher the risk of death within 30 days:

  • 0.01 ng/mL or less, risk 1.0%
  • 0.02 ng/mL, risk 4.0%
  • 0.03 to 0.29 ng/mL, risk 9.3%
  • 0.30 ng/mL or greater, risk 16.9%.7

Myocardial injury is a common postoperative vascular complication.7 Myocardial infarction (MI) or injury perioperatively increases the risk of death: 1 in 10 patients dies within 30 days after surgery.8

Surgery creates substantial physiologic stress through factors such as fasting, anesthesia, intubation, surgical trauma, extubation, and pain. It promotes coagulation9 and inflammation with activation of platelets,10 potentially leading to thrombosis.11 Coronary thrombosis secondary to plaque rupture11,12 can result in perioperative MI. Perioperative hemodynamic variability, anemia, and hypoxia can lead to demand-supply mismatch and also cause cardiac ischemia.

Aspirin is an antiplatelet agent that irreversibly inhibits platelet aggregation by blocking the formation of cyclooxygenase. It has been used for several decades as an antithrombotic agent in primary and secondary prevention. However, its benefit in primary prevention is uncertain, and the magnitude of antithrombotic benefit must be balanced against the risk of bleeding.

The Antithrombotic Trialists’ Collaboration13 performed a systematic review of 6 primary prevention trials involving 95,000 patients and found that aspirin therapy was associated with a 12% reduction in serious vascular events, which occurred in 0.51% of patients taking aspirin per year vs 0.57% of controls (P = .0001). However, aspirin also increased the risk of major bleeding, at a rate of 0.10% vs 0.07% per year (P < .0001), with 2 bleeding events for every avoided vascular event.13

WILL ASPIRIN PROTECT PATIENTS AT CARDIAC RISK?

The second Perioperative Ischemic Evaluation trial (POISE 2),1 in patients with atherosclerotic disease or at risk for it, found that giving aspirin in the perioperative period did not reduce the rate of death or nonfatal MI, but increased the risk of a major bleeding event.

The trial included 10,010 patients undergoing noncardiac surgery who were randomly assigned to receive aspirin or placebo. The aspirin arm included 2 groups: patients who were not on aspirin (initiation arm), and patients on aspirin at the time of randomization (continuation arm).

Death or nonfatal MI (the primary outcome) occurred in 7.0% of patients on aspirin vs 7.1% of patients receiving placebo (hazard ratio [HR] 0.99, 95% CI 0.86–1.15, P = .92). The risk of major bleeding was 4.6% in the aspirin group vs 3.8% in the placebo group (HR 1.23, 95% CI 1.01–1.49, P = .04).1

George et al,14 in a prospective observational study in a single tertiary care center, found that fewer patients with myocardial injury in noncardiac surgery died if they took aspirin or clopidogrel postoperatively. Conversely, lack of antithrombotic therapy was an independent predictor of death (P < .001). The mortality rate in patients with myocardial injury who were on antithrombotic therapy postoperatively was 6.7%, compared with 12.1% in those without postoperative antithrombotic therapy (estimated number needed to treat, 19).14

 

 

PATIENTS WITH CORONARY STENTS UNDERGOING NONCARDIAC SURGERY

Percutaneous coronary intervention (PCI) accounts for 3.6% of all operating-room procedures in the United States,15 and 20% to 35% of patients who undergo PCI undergo noncardiac surgery within 2 years of stent implantation.16,17

Antiplatelet therapy is discontinued in about 20% of patients with previous PCI who undergo noncardiac surgery.18

Observational data have shown that stopping antiplatelet therapy in patients with previous PCI with stent placement who undergo noncardiac surgery is the single most important predictor of stent thrombosis and death.19–21 The risk increases if the interval between stent implantation and surgery is shorter, especially within 180 days.16,17 Patients who have stent thrombosis are at significantly higher risk of death.

Graham et al4 conducted a subgroup analysis of the POISE 2 trial comparing aspirin and placebo in 470 patients who had undergone PCI (427 had stent placement, and the rest had angioplasty or an unspecified type of PCI); 234 patients received aspirin and 236 placebo. The median time from stent implantation to surgery was 5.3 years.

Of the patients in the aspirin arm, 14 (6%) had the primary outcome of death or nonfatal MI compared with 27 patients (11.5%) in the placebo arm (absolute risk reduction 5.5%, 95% CI 0.4%–10.5%). The result, which differed from that in the primary trial,1 was due to reduction in MI in the PCI subgroup on aspirin. PCI patients who were on aspirin did not have increased bleeding risk. This subgroup analysis, albeit small and limited, suggests that continuing low-dose aspirin in patients with previous PCI, irrespective of the type of stent or the time from stent implantations, minimizes the risk of perioperative MI.

GUIDELINES AND RECOMMENDATIONS

Routine perioperative use of aspirin increases the risk of bleeding without a reduction in ischemic events.1 Patients with prior PCI are at increased risk of acute stent thrombosis when antiplatelet medications are discontinued.20,21 Available data, although limited, support continuing low-dose aspirin without interruption in the perioperative period in PCI patients,4 as do the guidelines from the American College of Cardiology.5

Figure 1. Proposed perioperative management of aspirin and antiplatelet therapy in patients undergoing noncardiac surgery.
Figure 1. Proposed perioperative management of aspirin and antiplatelet therapy in patients undergoing noncardiac surgery.

We propose a management algorithm for patients undergoing noncardiac surgery on antiplatelet therapy that takes into consideration whether the surgery is urgent, elective, or time-sensitive (Figure 1). It is imperative to involve the cardiologist, surgeon, anesthesiologist, and the patient in the decision-making process.

In the perioperative setting for patients undergoing noncardiac surgery:

  • Discontinue aspirin in patients without coronary heart disease, as bleeding risk outweighs benefit.
  • Consider aspirin in patients at high risk for a major adverse cardiac event if benefits outweigh risk.
  • Continue low-dose aspirin without interruption in patients with a coronary stent, irrespective of the type of stent.
  • If a patient has had PCI with stent placement but is not currently on aspirin, talk with the patient and the treating cardiologist to find out why, and initiate aspirin if no contraindications exist.

In patients with cardiac stents, do not stop aspirin. If the risk of bleeding outweighs the benefit (eg, with intracranial procedures), an informed discussion involving the surgeon, cardiologist, and patient is critical to ascertain risks vs benefits.

See related editorial

In patients using aspirin for secondary prevention, the decision depends on the patient’s cardiac status and an assessment of risk vs benefit. Aspirin has no role in patients undergoing noncardiac surgery who are at low risk of a major adverse cardiac event.1,2

Aspirin used for secondary prevention reduces rates of death from vascular causes,3 but data on the magnitude of benefit in the perioperative setting are still evolving. In patients with coronary stents, continuing aspirin is beneficial,4,5 whereas stopping it is associated with an increased risk of acute stent thrombosis, which causes significant morbidity and mortality.6

SURGERY AND THROMBOTIC RISK: WHY CONSIDER ASPIRIN?

The Vascular Events in Noncardiac Surgery Patients Cohort Evaluation (VISION) study7 prospectively screened 15,133 patients for myocardial injury with troponin T levels daily for the first 3 consecutive postoperative days; 1,263 (8%) of the patients had a troponin elevation of 0.03 ng/mL or higher. The 30-day mortality rate in this group was 9.8%, compared with 1.1% in patients with a troponin T level of less than 0.03 ng/mL (odds ratio 10.07; 95% confidence interval [CI] 7.84–12.94; P < .001).8 The higher the peak troponin T concentration, the higher the risk of death within 30 days:

  • 0.01 ng/mL or less, risk 1.0%
  • 0.02 ng/mL, risk 4.0%
  • 0.03 to 0.29 ng/mL, risk 9.3%
  • 0.30 ng/mL or greater, risk 16.9%.7

Myocardial injury is a common postoperative vascular complication.7 Myocardial infarction (MI) or injury perioperatively increases the risk of death: 1 in 10 patients dies within 30 days after surgery.8

Surgery creates substantial physiologic stress through factors such as fasting, anesthesia, intubation, surgical trauma, extubation, and pain. It promotes coagulation9 and inflammation with activation of platelets,10 potentially leading to thrombosis.11 Coronary thrombosis secondary to plaque rupture11,12 can result in perioperative MI. Perioperative hemodynamic variability, anemia, and hypoxia can lead to demand-supply mismatch and also cause cardiac ischemia.

Aspirin is an antiplatelet agent that irreversibly inhibits platelet aggregation by blocking the formation of cyclooxygenase. It has been used for several decades as an antithrombotic agent in primary and secondary prevention. However, its benefit in primary prevention is uncertain, and the magnitude of antithrombotic benefit must be balanced against the risk of bleeding.

The Antithrombotic Trialists’ Collaboration13 performed a systematic review of 6 primary prevention trials involving 95,000 patients and found that aspirin therapy was associated with a 12% reduction in serious vascular events, which occurred in 0.51% of patients taking aspirin per year vs 0.57% of controls (P = .0001). However, aspirin also increased the risk of major bleeding, at a rate of 0.10% vs 0.07% per year (P < .0001), with 2 bleeding events for every avoided vascular event.13

WILL ASPIRIN PROTECT PATIENTS AT CARDIAC RISK?

The second Perioperative Ischemic Evaluation trial (POISE 2),1 in patients with atherosclerotic disease or at risk for it, found that giving aspirin in the perioperative period did not reduce the rate of death or nonfatal MI, but increased the risk of a major bleeding event.

The trial included 10,010 patients undergoing noncardiac surgery who were randomly assigned to receive aspirin or placebo. The aspirin arm included 2 groups: patients who were not on aspirin (initiation arm), and patients on aspirin at the time of randomization (continuation arm).

Death or nonfatal MI (the primary outcome) occurred in 7.0% of patients on aspirin vs 7.1% of patients receiving placebo (hazard ratio [HR] 0.99, 95% CI 0.86–1.15, P = .92). The risk of major bleeding was 4.6% in the aspirin group vs 3.8% in the placebo group (HR 1.23, 95% CI 1.01–1.49, P = .04).1

George et al,14 in a prospective observational study in a single tertiary care center, found that fewer patients with myocardial injury in noncardiac surgery died if they took aspirin or clopidogrel postoperatively. Conversely, lack of antithrombotic therapy was an independent predictor of death (P < .001). The mortality rate in patients with myocardial injury who were on antithrombotic therapy postoperatively was 6.7%, compared with 12.1% in those without postoperative antithrombotic therapy (estimated number needed to treat, 19).14

 

 

PATIENTS WITH CORONARY STENTS UNDERGOING NONCARDIAC SURGERY

Percutaneous coronary intervention (PCI) accounts for 3.6% of all operating-room procedures in the United States,15 and 20% to 35% of patients who undergo PCI undergo noncardiac surgery within 2 years of stent implantation.16,17

Antiplatelet therapy is discontinued in about 20% of patients with previous PCI who undergo noncardiac surgery.18

Observational data have shown that stopping antiplatelet therapy in patients with previous PCI with stent placement who undergo noncardiac surgery is the single most important predictor of stent thrombosis and death.19–21 The risk increases if the interval between stent implantation and surgery is shorter, especially within 180 days.16,17 Patients who have stent thrombosis are at significantly higher risk of death.

Graham et al4 conducted a subgroup analysis of the POISE 2 trial comparing aspirin and placebo in 470 patients who had undergone PCI (427 had stent placement, and the rest had angioplasty or an unspecified type of PCI); 234 patients received aspirin and 236 placebo. The median time from stent implantation to surgery was 5.3 years.

Of the patients in the aspirin arm, 14 (6%) had the primary outcome of death or nonfatal MI compared with 27 patients (11.5%) in the placebo arm (absolute risk reduction 5.5%, 95% CI 0.4%–10.5%). The result, which differed from that in the primary trial,1 was due to reduction in MI in the PCI subgroup on aspirin. PCI patients who were on aspirin did not have increased bleeding risk. This subgroup analysis, albeit small and limited, suggests that continuing low-dose aspirin in patients with previous PCI, irrespective of the type of stent or the time from stent implantations, minimizes the risk of perioperative MI.

GUIDELINES AND RECOMMENDATIONS

Routine perioperative use of aspirin increases the risk of bleeding without a reduction in ischemic events.1 Patients with prior PCI are at increased risk of acute stent thrombosis when antiplatelet medications are discontinued.20,21 Available data, although limited, support continuing low-dose aspirin without interruption in the perioperative period in PCI patients,4 as do the guidelines from the American College of Cardiology.5

Figure 1. Proposed perioperative management of aspirin and antiplatelet therapy in patients undergoing noncardiac surgery.
Figure 1. Proposed perioperative management of aspirin and antiplatelet therapy in patients undergoing noncardiac surgery.

We propose a management algorithm for patients undergoing noncardiac surgery on antiplatelet therapy that takes into consideration whether the surgery is urgent, elective, or time-sensitive (Figure 1). It is imperative to involve the cardiologist, surgeon, anesthesiologist, and the patient in the decision-making process.

In the perioperative setting for patients undergoing noncardiac surgery:

  • Discontinue aspirin in patients without coronary heart disease, as bleeding risk outweighs benefit.
  • Consider aspirin in patients at high risk for a major adverse cardiac event if benefits outweigh risk.
  • Continue low-dose aspirin without interruption in patients with a coronary stent, irrespective of the type of stent.
  • If a patient has had PCI with stent placement but is not currently on aspirin, talk with the patient and the treating cardiologist to find out why, and initiate aspirin if no contraindications exist.
References
  1. Devereaux PJ, Mrkobrada M, Sessler DI, et al; POISE-2 Investigators. Aspirin in patients undergoing noncardiac surgery. N Engl J Med 2014; 370(16):1494–1503. doi:10.1056/NEJMoa1401105
  2. Fleisher LA, Fleischmann KE, Auerbach AD, et al; American College of Cardiology; American Heart Association. 2014 ACC/AHA guideline on perioperative cardiovascular evaluation and management of patients undergoing noncardiac surgery: a report of the American College of Cardiology/American Heart Association Task Force on practice guidelines. J Am Coll Cardiol 2014; 64(22):e77–e137. doi:10.1016/j.jacc.2014.07.944
  3. Collaborative overview of randomised trials of antiplatelet therapy—I: prevention of death, myocardial infarction, and stroke by prolonged antiplatelet therapy in various categories of patients. Antiplatelet Trialists’ Collaboration. BMJ 1994; 308(6921):81–106. pmid:8298418
  4. Graham MM, Sessler DI, Parlow JL, et al. Aspirin in patients with previous percutaneous coronary intervention undergoing noncardiac surgery. Ann Intern Med 2018; 168(4):237–244. doi:10.7326/M17-2341
  5. Levine GN, Bates ER, Bittl JA, et al. 2016 ACC/AHA guideline focused update on duration of dual antiplatelet therapy in patients with coronary artery disease: a report of the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines. J Am Coll Cardiol 2016; 68(10):1082–1115. doi:10.1016/j.jacc.2016.03.513
  6. Albaladejo P, Marret E, Samama CM, et al. Non-cardiac surgery in patients with coronary stents: the RECO study. Heart 2011; 97(19):1566–1572. doi:10.1136/hrt.2011.224519
  7. Vascular Events in Noncardiac Surgery Patients Cohort Evaluation (VISION) Study Investigators; Devereaux PJ, Chan MT, Alonso-Coello P, et al. Association between postoperative troponin levels and 30-day mortality among patients undergoing noncardiac surgery. JAMA 2012; 307(21):2295–2304. doi:10.1001/jama.2012.5502
  8. Botto F, Alonso-Coello P, Chan MT, et al. Myocardial injury after noncardiac surgery: a large, international, prospective cohort study establishing diagnostic criteria, characteristics, predictors, and 30-day outcomes. Anesthesiology 2014; 120(3):564–578. doi:10.1097/ALN.0000000000000113
  9. Gorka J, Polok K, Iwaniec T, et al. Altered preoperative coagulation and fibrinolysis are associated with myocardial injury after non-cardiac surgery. Br J Anaesth 2017; 118(5):713–719. doi:10.1093/bja/aex081
  10. Rajagopalan S, Ford I, Bachoo P, et al. Platelet activation, myocardial ischemic events and postoperative non-response to aspirin in patients undergoing major vascular surgery. J Thromb Haemost 2007; 5(10):2028–2035. doi:10.1111/j.1538-7836.2007.02694.x
  11. Priebe HJ. Triggers of perioperative myocardial ischaemia and infarction. Br J Anaesth 2004; 93(1):9–20. doi:10.1093/bja/aeh147
  12. Devereaux PJ, Goldman L, Cook DJ, Gilbert K, Leslie K, Guyatt GH. Perioperative cardiac events in patients undergoing noncardiac surgery: a review of the magnitude of the problem, the pathophysiology of the events and methods to estimate and communicate risk. CMAJ 2005; 173(6):627–634. doi:10.1503/cmaj.050011
  13. Antithrombotic Trialists’ (ATT) Collaboration; Baigent C, Blackwell L, Collins R, et al. Aspirin in the primary and secondary prevention of vascular disease: collaborative meta-analysis of individual participant data from randomised trials. Lancet 2009; 373(9678):1849–1860. doi:10.1016/S0140-6736(09)60503-1
  14. George R, Menon VP, Edathadathil F, et al. Myocardial injury after noncardiac surgery—incidence and predictors from a prospective observational cohort study at an Indian tertiary care centre. Medicine (Baltimore) 2018; 97(19):e0402. doi:10.1097/MD.0000000000010402
  15. Weiss AJ, Elixhauser A, Andrews RM; Healthcare Cost and Utilization Project (HCUP). Characteristics of operating room procedures in US hospitals, 2011: statistical brief #170. https://hcup-us.ahrq.gov/reports/statbriefs/sb170-Operating-Room-Procedures-United-States-2011.jsp. Accessed May 3, 2019.
  16. Hawn MT, Graham LA, Richman JS, Itani KM, Henderson WG, Maddox TM. Risk of major adverse cardiac events following noncardiac surgery in patients with coronary stents. JAMA 2013; 310(14):1462–1472. doi:10.1001/jama.2013.278787
  17. Wijeysundera DN, Wijeysundera HC, Yun L, et al. Risk of elective major noncardiac surgery after coronary stent insertion: a population-based study. Circulation 2012; 126(11):1355–1362. doi:10.1161/CIRCULATIONAHA.112.102715
  18. Rossini R, Capodanno D, Lettieri C, et al. Prevalence, predictors, and long-term prognosis of premature discontinuation of oral antiplatelet therapy after drug eluting stent implantation. Am J Cardiol 2011; 107(2):186–194. doi:10.1016/j.amjcard.2010.08.067
  19. Eisenberg MJ, Richard PR, Libersan D, Filion KB. Safety of short-term discontinuation of antiplatelet therapy in patients with drug-eluting stents. Circulation 2009; 119(12):1634–1642. doi:10.1161/CIRCULATIONAHA.108.813667
  20. Iakovou I, Schmidt T, Bonizzoni E, et al. Incidence, predictors, and outcome of thrombosis after successful implantation of drug-eluting stents. JAMA 2005; 293(17):2126–2130. doi:10.1001/jama.293.17.2126
  21. Park DW, Park SW, Park KH, et al. Frequency of and risk factors for stent thrombosis after drug-eluting stent implantation during long-term follow-up. Am J Cardiol 2006; 98(3):352–356. doi:10.1016/j.amjcard.2006.02.039
References
  1. Devereaux PJ, Mrkobrada M, Sessler DI, et al; POISE-2 Investigators. Aspirin in patients undergoing noncardiac surgery. N Engl J Med 2014; 370(16):1494–1503. doi:10.1056/NEJMoa1401105
  2. Fleisher LA, Fleischmann KE, Auerbach AD, et al; American College of Cardiology; American Heart Association. 2014 ACC/AHA guideline on perioperative cardiovascular evaluation and management of patients undergoing noncardiac surgery: a report of the American College of Cardiology/American Heart Association Task Force on practice guidelines. J Am Coll Cardiol 2014; 64(22):e77–e137. doi:10.1016/j.jacc.2014.07.944
  3. Collaborative overview of randomised trials of antiplatelet therapy—I: prevention of death, myocardial infarction, and stroke by prolonged antiplatelet therapy in various categories of patients. Antiplatelet Trialists’ Collaboration. BMJ 1994; 308(6921):81–106. pmid:8298418
  4. Graham MM, Sessler DI, Parlow JL, et al. Aspirin in patients with previous percutaneous coronary intervention undergoing noncardiac surgery. Ann Intern Med 2018; 168(4):237–244. doi:10.7326/M17-2341
  5. Levine GN, Bates ER, Bittl JA, et al. 2016 ACC/AHA guideline focused update on duration of dual antiplatelet therapy in patients with coronary artery disease: a report of the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines. J Am Coll Cardiol 2016; 68(10):1082–1115. doi:10.1016/j.jacc.2016.03.513
  6. Albaladejo P, Marret E, Samama CM, et al. Non-cardiac surgery in patients with coronary stents: the RECO study. Heart 2011; 97(19):1566–1572. doi:10.1136/hrt.2011.224519
  7. Vascular Events in Noncardiac Surgery Patients Cohort Evaluation (VISION) Study Investigators; Devereaux PJ, Chan MT, Alonso-Coello P, et al. Association between postoperative troponin levels and 30-day mortality among patients undergoing noncardiac surgery. JAMA 2012; 307(21):2295–2304. doi:10.1001/jama.2012.5502
  8. Botto F, Alonso-Coello P, Chan MT, et al. Myocardial injury after noncardiac surgery: a large, international, prospective cohort study establishing diagnostic criteria, characteristics, predictors, and 30-day outcomes. Anesthesiology 2014; 120(3):564–578. doi:10.1097/ALN.0000000000000113
  9. Gorka J, Polok K, Iwaniec T, et al. Altered preoperative coagulation and fibrinolysis are associated with myocardial injury after non-cardiac surgery. Br J Anaesth 2017; 118(5):713–719. doi:10.1093/bja/aex081
  10. Rajagopalan S, Ford I, Bachoo P, et al. Platelet activation, myocardial ischemic events and postoperative non-response to aspirin in patients undergoing major vascular surgery. J Thromb Haemost 2007; 5(10):2028–2035. doi:10.1111/j.1538-7836.2007.02694.x
  11. Priebe HJ. Triggers of perioperative myocardial ischaemia and infarction. Br J Anaesth 2004; 93(1):9–20. doi:10.1093/bja/aeh147
  12. Devereaux PJ, Goldman L, Cook DJ, Gilbert K, Leslie K, Guyatt GH. Perioperative cardiac events in patients undergoing noncardiac surgery: a review of the magnitude of the problem, the pathophysiology of the events and methods to estimate and communicate risk. CMAJ 2005; 173(6):627–634. doi:10.1503/cmaj.050011
  13. Antithrombotic Trialists’ (ATT) Collaboration; Baigent C, Blackwell L, Collins R, et al. Aspirin in the primary and secondary prevention of vascular disease: collaborative meta-analysis of individual participant data from randomised trials. Lancet 2009; 373(9678):1849–1860. doi:10.1016/S0140-6736(09)60503-1
  14. George R, Menon VP, Edathadathil F, et al. Myocardial injury after noncardiac surgery—incidence and predictors from a prospective observational cohort study at an Indian tertiary care centre. Medicine (Baltimore) 2018; 97(19):e0402. doi:10.1097/MD.0000000000010402
  15. Weiss AJ, Elixhauser A, Andrews RM; Healthcare Cost and Utilization Project (HCUP). Characteristics of operating room procedures in US hospitals, 2011: statistical brief #170. https://hcup-us.ahrq.gov/reports/statbriefs/sb170-Operating-Room-Procedures-United-States-2011.jsp. Accessed May 3, 2019.
  16. Hawn MT, Graham LA, Richman JS, Itani KM, Henderson WG, Maddox TM. Risk of major adverse cardiac events following noncardiac surgery in patients with coronary stents. JAMA 2013; 310(14):1462–1472. doi:10.1001/jama.2013.278787
  17. Wijeysundera DN, Wijeysundera HC, Yun L, et al. Risk of elective major noncardiac surgery after coronary stent insertion: a population-based study. Circulation 2012; 126(11):1355–1362. doi:10.1161/CIRCULATIONAHA.112.102715
  18. Rossini R, Capodanno D, Lettieri C, et al. Prevalence, predictors, and long-term prognosis of premature discontinuation of oral antiplatelet therapy after drug eluting stent implantation. Am J Cardiol 2011; 107(2):186–194. doi:10.1016/j.amjcard.2010.08.067
  19. Eisenberg MJ, Richard PR, Libersan D, Filion KB. Safety of short-term discontinuation of antiplatelet therapy in patients with drug-eluting stents. Circulation 2009; 119(12):1634–1642. doi:10.1161/CIRCULATIONAHA.108.813667
  20. Iakovou I, Schmidt T, Bonizzoni E, et al. Incidence, predictors, and outcome of thrombosis after successful implantation of drug-eluting stents. JAMA 2005; 293(17):2126–2130. doi:10.1001/jama.293.17.2126
  21. Park DW, Park SW, Park KH, et al. Frequency of and risk factors for stent thrombosis after drug-eluting stent implantation during long-term follow-up. Am J Cardiol 2006; 98(3):352–356. doi:10.1016/j.amjcard.2006.02.039
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Do patients on biologic drugs for rheumatic disease need PCP prophylaxis?

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Do patients on biologic drugs for rheumatic disease need PCP prophylaxis?

Pneumocystis jirovecii (previously carinii) pneumonia (PCP) is rare in patients taking biologic response modifiers for rheumatic disease.1–10 However, prophylaxis should be considered in patients who have granulomatosis with polyangiitis or underlying pulmonary disease, or who are concomitantly receiving glucocorticoids in high doses. There is some risk of adverse reactions to the prophylactic medicine.1,11–21 Until clear guidelines are available, the decision to initiate PCP prophylaxis and the choice of agent should be individualized.

THE BURDEN OF PCP

Table 1. Biologic agents used for rheumatic disease
PCP is a life-threatening opportunistic infection. Common causes of immunosuppression are advanced human immunodeficiency virus (HIV) infection, hematologic malignancy, anti-rejection drugs, chemotherapy, glucocorticoid therapy, and other immunosuppressive drugs. Here, we focus on the risk of PCP with immunomodulatory biologic drugs used for rheumatic disease that deplete B cells or inhibit T-cell activation, cytokine production, or cytokine function (Table 1).22

In a meta-analysis23 of 867 patients who developed PCP and did not have HIV infection, 20.1% had autoimmune or chronic inflammatory disease and the rest were transplant recipients or had malignancies. The mortality rate was 30.6%.

PHARMACOLOGIC RISK FACTORS FOR PCP

Treatment with glucocorticoids

Treatment with glucocorticoids is an important risk factor for PCP, independent of biologic therapy.

Calero-Bernal et al11 reported on 128 patients with non-HIV PCP, of whom 114 (89%) had received a glucocorticoid for more than 4 weeks, and 98 (76%) were currently receiving one. The mean daily dose was equivalent to 27.73 mg of prednisone per day in those on glucocorticoids only, and 21.34 mg in those receiving glucocorticoids in combination with other immunosuppressants.

Park et al,12 in a retrospective study of Korean patients treated for rheumatic disease with high-dose glucocorticoids (≥ 30 mg/day of prednisone or equivalent for more than 4 weeks), reported an incidence rate of PCP of 2.37 per 100 patient-years in those not on prophylaxis.

Other studies13,14 have also found a prednisone dose greater than 15 to 20 mg per day for more than 4 weeks or concomitant use of 2 or more disease-modifying antirheumatic drugs to be a significant risk factor.13,14

Tumor necrosis factor alpha antagonists

A US Food and Drug Administration review1 of voluntary reports of adverse drug events estimated the incidence of PCP to be 2.3 per 100,000 patient-years with infliximab and 1.6 per 100,000 patient-years with etanercept. In most cases, other immunosuppressants were used concomitantly.1

Postmarketing surveillance2 of 5,000 patients with rheumatoid arthritis showed an incidence of suspected PCP of 0.4% within the first 6 months of starting infliximab therapy.

Komano et al,15 in a case-control study of patients with rheumatoid arthritis treated with infliximab, reported that all 21 patients with PCP were also on methotrexate (median dosage 8 mg per week) and prednisolone (median dosage 7.5 mg per day).

PCP has also been reported after adalimumab use in combination with prednisone, azathioprine, and methotrexate, as well as with certolizumab, golimumab, tocilizumab, abatacept, and rituximab.3–6,24–26

Rituximab

Calero-Bernal et al11 reported that 23% of patients with non-HIV PCP who were receiving immunosuppressant drugs were on rituximab.

Alexandre et al16 performed a retrospective review of 11 cases of PCP complicating rituximab therapy for autoimmune disease, in which 10 (91%) of the patients were also on corticosteroids, with a median dosage of 30 mg of prednisone daily. A literature review of an additional 18 cases revealed similar findings.

 

 

PATIENT RISK FACTORS FOR PCP

Table 2. Risk factors for Pneumocystis jirovecii pneumonia in patients on biologic therapy for rheumatic disease
Certain clinical, laboratory, and pharmacologic factors are associated with increased risk of PCP (Table 2).3–6,9,17–19,21,22,27

Pulmonary disease, age, other factors

Komano et al,15 in their study of patients with rheumatoid arthritis treated with infliximab, found that 10 (48%) of 21 patients with PCP had preexisting pulmonary disease, compared with 11 (10.8%) of 102 patients without PCP (P < .001). Patients with PCP were older (mean age 64 vs 54, P < .001), were on higher median doses of prednisolone per day (7.5 vs 5 mg, P = .001), and had lower median serum immunoglobulin G (IgG) levels (944 vs 1,394 mg/dL, P < .001).15 

Tadros et al13 performed a case-control study that also showed that patients with autoimmune disease who developed PCP had lower lymphocyte counts than controls on admission. Other risk factors included low CD4 counts and age older than 50.

Li et al17 found that patients with autoimmune or inflammatory disease with PCP were more likely to have low CD3, CD4, and CD8 cell counts, as well as albumin levels less than 28 g/L. They therefore suggested that lymphocyte subtyping may be a useful tool to guide PCP prophylaxis.

Granulomatosis with polyangiitis

Patients with granulomatosis with polyangiitis have a significantly higher incidence of PCP than patients with other connective tissue diseases.

Ward and Donald18 reviewed 223 cases of PCP in patients with connective tissue disease. The highest frequency (89 cases per 10,000 hospitalizations per year) was in patients with granulomatosis with polyangiitis, followed by 65 per 10,000 hospitalizations per year for patients with polyarteritis nodosa. The lowest frequency was in rheumatoid arthritis patients, at 2 per 10,000 hospitalizations per year. In decreasing order, diseases with significant associations with PCP were:

  • Polyarteritis nodosa (odds ratio [OR] 10.20, 95% confidence interval [CI] 5.69–18.29)
  • Granulomatosis with polyangiitis (OR 7.81, 95% CI 4.71–13.05)
  • Inflammatory myopathy (OR 4.44, 95% CI 2.67–7.38)
  • Systemic lupus erythematosus (OR 2.52, 95% CI 1.66–3.82).

Vallabhaneni and Chiller,26 in a meta-analysis including rheumatoid arthritis patients on biologics, did not find an increased risk of PCP (OR 1.77, 95% CI 0.42–7.47).

Park et al12 found that the highest incidences of PCP were in patients with granulomatosis with polyangiitis, microscopic polyangiitis, and systemic sclerosis. For systemic sclerosis, the main reason for giving high-dose glucocorticoids was interstitial lung disease.

Other studies19,20,28 also found an association with coexisting pulmonary disease in patients with rheumatoid arthritis.

CURRENT GUIDELINES

There are guidelines for primary and secondary prophylaxis of PCP in HIV-positive patients with CD4 counts less than 200/mm3 or a history of acquired immunodeficiency syndrome (AIDS)-defining illness.27 Additionally, patients with a CD4 cell percentage less than 14% should be considered for prophylaxis.27

Unfortunately, there are no guidelines for prophylaxis in patients taking immunosuppressants for rheumatic disease.

The recommended regimen for PCP prophylaxis in HIV-infected patients is trimethoprim-sulfamethoxazole, 1 double-strength or 1 single-strength tablet daily. Alternative regimens include 1 double-strength tablet 3 times per week, dapsone, aerosolized pentamidine, and atovaquone.27

There are also guidelines for prophylaxis in kidney transplant recipients, as well as for patients with hematologic malignancies and solid-organ malignancies, particularly those on chemotherapeutic agents and the T-cell-depleting agent alemtuzumab.29–31

Italian clinical practice guidelines for the use of tumor necrosis factor antagonists in inflammatory bowel disease recommend consideration of PCP prophylaxis in patients who are also on other immunosuppressants, particularly high-dose glucocorticoids.32

Prophylaxis has been shown to increase life expectancy and quality-adjusted life-years and to reduce cost for patients on immunosuppressive therapy for granulomatosis with polyangiitis.21 The European Society of Clinical Microbiology and Infectious Diseases recently produced consensus statements recommending PCP prophylaxis for patients on rituximab with other concomitant immunosuppressants such as the equivalent of prednisone 20 mg daily for more than 4 weeks.33 Prophylaxis was not recommended for other biologic therapies.34,35

THE RISKS OF PROPHYLAXIS

The risk of PCP should be weighed against the risk of prophylaxis in patients with rheumatic disease. Adverse reactions to sulfonamide antibiotics including disease flares have been reported in patients with systemic lupus erythematosus.36,37 Other studies have found no increased risk of flares in patients taking trimethoprim-sulfamethoxazole for PCP prophylaxis.12,38 A retrospective analysis of patients with vasculitis found no increased risk of combining methotrexate and trimethoprim-sulfamethoxazole.39

KEY POINTS

  • PCP is an opportunistic infection with a high risk of death.
  • PCP has been reported with biologics used as immunomodulators in rheumatic disease.
  • PCP prophylaxis should be considered in patients at high risk of PCP, such as those who have granulomatosis with polyangiitis, underlying pulmonary disease or who are concomitantly taking glucocorticoids.
References
  1. US Food and Drug Administration. Safety update on TNF-alpha antagonists: infliximab and etanercept.https://wayback.archive-it.org/7993/20180127041103/https://www.fda.gov/ohrms/dockets/ac/01/briefing/3779b2_01_cber_safety_revision2.htm. Accessed May 3, 2019.
  2. Takeuchi T, Tatsuki Y, Nogami Y, et al. Postmarketing surveillance of the safety profile of infliximab in 5000 Japanese patients with rheumatoid arthritis. Ann Rheum Dis 2008; 67(2):189–194. doi:10.1136/ard.2007.072967
  3. Koike T, Harigai M, Ishiguro N, et al. Safety and effectiveness of adalimumab in Japanese rheumatoid arthritis patients: postmarketing surveillance report of the first 3,000 patients. Mod Rheumatol 2012; 22(4):498–508. doi:10.1007/s10165-011-0541-5
  4. Bykerk V, Cush J, Winthrop K, et al. Update on the safety profile of certolizumab pegol in rheumatoid arthritis: an integrated analysis from clinical trials. Ann Rheum Dis 2015; 74(1):96–103. doi:10.1136/annrheumdis-2013-203660
  5. Koike T, Harigai M, Inokuma S, et al. Postmarketing surveillance of tocilizumab for rheumatoid arthritis in Japan: interim analysis of 3881 patients. Ann Rheum Dis 2011; 70(12):2148–2151. doi:10.1136/ard.2011.151092
  6. Harigai M, Ishiguro N, Inokuma S, et al. Postmarketing surveillance of the safety and effectiveness of abatacept in Japanese patients with rheumatoid arthritis. Mod Rheumatol 2016; 26(4):491–498. doi:10.3109/14397595.2015.1123211
  7. Koike T, Harigai M, Inokuma S, et al. Postmarketing surveillance of the safety and effectiveness of etanercept in Japan. J Rheumatol 2009; 36(5):898–906. doi:10.3899/jrheum.080791
  8. Grubbs JA, Baddley JW. Pneumocystis jirovecii pneumonia in patients receiving tumor-necrosis-factor-inhibitor therapy: implications for chemoprophylaxis. Curr Rheumatol Rep 2014; 16(10):445. doi:10.1007/s11926-014-0445-4
  9. US Food and Drug Administration. FDA adverse event reporting system (FAERS) public dashboard. www.fda.gov/Drugs/GuidanceComplianceRegulatoryInformation/Surveillance/AdverseDrugEffects/ucm070093.htm. Accessed May 3, 2019.
  10. Rutherford AI, Patarata E, Subesinghe S, Hyrich KL, Galloway JB. Opportunistic infections in rheumatoid arthritis patients exposed to biologic therapy: results from the British Society for Rheumatology Biologics Register for Rheumatoid Arthritis. Rheumatology (Oxford) 2018; 57(6):997–1001. doi:10.1093/rheumatology/key023
  11. Calero-Bernal ML, Martin-Garrido I, Donazar-Ezcurra M, Limper AH, Carmona EM. Intermittent courses of corticosteroids also present a risk for Pneumocystis pneumonia in non-HIV patients. Can Respir J 2016; 2016:2464791. doi:10.1155/2016/2464791
  12. Park JW, Curtis JR, Moon J, Song YW, Kim S, Lee EB. Prophylactic effect of trimethoprim-sulfamethoxazole for pneumocystis pneumonia in patients with rheumatic diseases exposed to prolonged high-dose glucocorticoids. Ann Rheum Dis 2018; 77(5):644–649. doi:10.1136/annrheumdis-2017-211796
  13. Tadros S, Teichtahl AJ, Ciciriello S, Wicks IP. Pneumocystis jirovecii pneumonia in systemic autoimmune rheumatic disease: a case-control study. Semin Arthritis Rheum 2017; 46(6):804–809. doi:10.1016/j.semarthrit.2016.09.009
  14. Demoruelle MK, Kahr A, Verilhac K, Deane K, Fischer A, West S. Recent-onset systemic lupus erythematosus complicated by acute respiratory failure. Arthritis Care Res (Hoboken) 2013; 65(2):314–323. doi:10.1002/acr.21857
  15. Komano Y, Harigai M, Koike R, et al. Pneumocystis jiroveci pneumonia in patients with rheumatoid arthritis treated with infliximab: a retrospective review and case-control study of 21 patients. Arthritis Rheum 2009; 61(3):305–312. doi:10.1002/art.24283
  16. Alexandre K, Ingen-Housz-Oro S, Versini M, Sailler L, Benhamou Y. Pneumocystis jirovecii pneumonia in patients treated with rituximab for systemic diseases: report of 11 cases and review of the literature. Eur J Intern Med 2018; 50:e23–e24. doi:10.1016/j.ejim.2017.11.014
  17. Li Y, Ghannoum M, Deng C, et al. Pneumocystis pneumonia in patients with inflammatory or autoimmune diseases: usefulness of lymphocyte subtyping. Int J Infect Dis 2017; 57:108–115. doi:10.1016/j.ijid.2017.02.010
  18. Ward MM, Donald F. Pneumocystis carinii pneumonia in patients with connective tissue diseases: the role of hospital experience in diagnosis and mortality. Arthritis Rheum 1999; 42(4):780–789. doi:10.1002/1529-0131(199904)42:4<780::AID-ANR23>3.0.CO;2-M
  19. Katsuyama T, Saito K, Kubo S, Nawata M, Tanaka Y. Prophylaxis for Pneumocystis pneumonia in patients with rheumatoid arthritis treated with biologics, based on risk factors found in a retrospective study. Arthritis Res Ther 2014; 16(1):R43. doi:10.1186/ar4472
  20. Tanaka M, Sakai R, Koike R, et al. Pneumocystis jirovecii pneumonia associated with etanercept treatment in patients with rheumatoid arthritis: a retrospective review of 15 cases and analysis of risk factors. Mod Rheumatol 2012; 22(6):849–858. doi:10.1007/s10165-012-0615-z
  21. Chung JB, Armstrong K, Schwartz JS, Albert D. Cost-effectiveness of prophylaxis against Pneumocystis carinii pneumonia in patients with Wegener’s granulomatosis undergoing immunosuppressive therapy. Arthritis Rheum 2000; 43(8):1841–1848. doi:10.1002/1529-0131(200008)43:8<1841::AID-ANR21>3.0.CO;2-Q
  22. Selmi C, Generali E, Massarotti M, Bianchi G, Scire CA. New treatments for inflammatory rheumatic disease. Immunol Res 2014; 60(2–3):277–288. doi:10.1007/s12026-014-8565-5
  23. Liu Y, Su L, Jiang SJ, Qu H. Risk factors for mortality from Pneumocystis carinii pneumonia (PCP) in non-HIV patients: a meta-analysis. Oncotarget 2017; 8(35):59729–59739. doi:10.18632/oncotarget.19927
  24. Desales AL, Mendez-Navarro J, Méndez-Tovar LJ, et al. Pneumocystosis in a patient with Crohn's disease treated with combination therapy with adalimumab. J Crohns Colitis 2012; 6(4):483–487. doi:10.1016/j.crohns.2011.10.012
  25. Kalyoncu U, Karadag O, Akdogan A, et al. Pneumocystis carinii pneumonia in a rheumatoid arthritis patient treated with adalimumab. Scand J Infect Dis 2007; 39(5):475–478. doi:10.1080/00365540601071867
  26. Vallabhaneni S, Chiller TM. Fungal infections and new biologic therapies. Curr Rheumatol Rep 2016; 18(5):29. doi:10.1007/s11926-016-0572-1
  27. Panel on Opportunistic Infections in HIV-Infected Adults and Adolescents. Guidelines for the prevention and treatment of opportunistic infections in HIV-infected adults and adolescents: recommendations from the Centers for Disease Control and Prevention, the National Institutes of Health, and the HIV Medicine Association of the Infectious Diseases Society of America. www.aidsinfo.nih.gov/contentfiles/lvguidelines/adult_oi.pdf. Accessed May 3, 2019.
  28. Kourbeti IS, Ziakas PD, Mylonakis E. Biologic therapies in rheumatoid arthritis and the risk of opportunistic infections: a meta-analysis. Clin Infect Dis 2014; 58(12):1649–1657. doi:10.1093/cid/ciu185
  29. Bia M, Adey DB, Bloom RD, Chan L, Kulkarni S, Tomlanovich S. KDOQI US commentary on the 2009 KDIGO clinical practice guideline for the care of kidney transplant recipients. Am J Kidney Dis 2010; 56(2):189–218. doi:10.1053/j.ajkd.2010.04.010
  30. Baden LR, Swaminathan S, Angarone M, et al. Prevention and treatment of cancer-related infections, version 2.2016, NCCN clinical practice guidelines in oncology. J Natl Compr Canc Netw 2016; 14(7):882–913. pmid:27407129
  31. Cooley L, Dendle C, Wolf J, et al. Consensus guidelines for diagnosis, prophylaxis and management of Pneumocystis jirovecii pneumonia in patients with haematological and solid malignancies, 2014. Intern Med J 2014; 44(12b):1350–1363. doi:10.1111/imj.12599
  32. Orlando A, Armuzzi A, Papi C, et al; Italian Society of Gastroenterology; Italian Group for the study of Inflammatory Bowel Disease. The Italian Society of Gastroenterology (SIGE) and the Italian Group for the study of Inflammatory Bowel Disease (IG-IBD) clinical practice guidelines: the use of tumor necrosis factor-alpha antagonist therapy in inflammatory bowel disease. Dig Liver Dis 2011; 43(1):1–20. doi:10.1016/j.dld.2010.07.010
  33. Mikulska M, Lanini S, Gudiol C, et al. ESCMID Study Group for Infections in Compromised Hosts (ESGICH) consensus document on the safety of targeted and biological therapies: an infectious diseases perspective (agents targeting lymphoid cells surface antigens [I]: CD19, CD20 and CD52). Clin Microbiol Infect 2018; 24(suppl 2):S71–S82. doi:10.1016/j.cmi.2018.02.003
  34. Baddley J, Cantini F, Goletti D, et al. ESCMID Study Group for Infections in Compromised Hosts (ESGICH) consensus document on the safety of targeted and biological therapies: an infectious diseases perspective (soluble immune effector molecules [I]: anti-tumor necrosis factor-alpha agents). Clin Microbiol Infect 2018; 24(suppl 2):S10–S20. doi:10.1016/j.cmi.2017.12.025
  35. Winthrop K, Mariette X, Silva J, et al. ESCMID Study Group for Infections in Compromised Hosts (ESGICH) consensus document on the safety of targeted and biological therapies: an infectious diseases perspective (soluble immune effector molecules [II]: agents targeting interleukins, immunoglobulins and complement factors). Clin Microbiol Infect 2018; 24(suppl 2):S21–S40. doi:10.1016/j.cmi.2018.02.002
  36. Petri M, Allbritton J. Antibiotic allergy in systemic lupus erythematosus: a case-control study. J Rheumatol 1992; 19(2):265–269. pmid:1629825
  37. Pope J, Jerome D, Fenlon D, Krizova A, Ouimet J. Frequency of adverse drug reactions in patients with systemic lupus erythematosus. J Rheumatol 2003; 30(3):480–484. pmid:12610805
  38. Vananuvat P, Suwannalai P, Sungkanuparph S, Limsuwan T, Ngamjanyaporn P, Janwityanujit S. Primary prophylaxis for Pneumocystis jirovecii pneumonia in patients with connective tissue diseases. Semin Arthritis Rheum 2011; 41(3):497–502. doi:10.1016/j.semarthrit.2011.05.004
  39. Tamaki H, Butler R, Langford C. Abstract Number: 1755: Safety of methotrexate and low-dose trimethoprim-sulfamethoxazole in patients with ANCA-associated vasculitis. www.acrabstracts.org/abstract/safety-of-methotrexate-and-low-dose-trimethoprim-sulfamethoxazole-in-patients-with-anca-associated-vasculitis. Accessed May 3, 2019.
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Address: Joy-Ann Tabanor, MBBS, Division of Rheumatology, University of Connecticut School of Medicine, 263 Farmington Avenue, Farmington, CT 06030-5353; [email protected]

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Related Articles

Pneumocystis jirovecii (previously carinii) pneumonia (PCP) is rare in patients taking biologic response modifiers for rheumatic disease.1–10 However, prophylaxis should be considered in patients who have granulomatosis with polyangiitis or underlying pulmonary disease, or who are concomitantly receiving glucocorticoids in high doses. There is some risk of adverse reactions to the prophylactic medicine.1,11–21 Until clear guidelines are available, the decision to initiate PCP prophylaxis and the choice of agent should be individualized.

THE BURDEN OF PCP

Table 1. Biologic agents used for rheumatic disease
PCP is a life-threatening opportunistic infection. Common causes of immunosuppression are advanced human immunodeficiency virus (HIV) infection, hematologic malignancy, anti-rejection drugs, chemotherapy, glucocorticoid therapy, and other immunosuppressive drugs. Here, we focus on the risk of PCP with immunomodulatory biologic drugs used for rheumatic disease that deplete B cells or inhibit T-cell activation, cytokine production, or cytokine function (Table 1).22

In a meta-analysis23 of 867 patients who developed PCP and did not have HIV infection, 20.1% had autoimmune or chronic inflammatory disease and the rest were transplant recipients or had malignancies. The mortality rate was 30.6%.

PHARMACOLOGIC RISK FACTORS FOR PCP

Treatment with glucocorticoids

Treatment with glucocorticoids is an important risk factor for PCP, independent of biologic therapy.

Calero-Bernal et al11 reported on 128 patients with non-HIV PCP, of whom 114 (89%) had received a glucocorticoid for more than 4 weeks, and 98 (76%) were currently receiving one. The mean daily dose was equivalent to 27.73 mg of prednisone per day in those on glucocorticoids only, and 21.34 mg in those receiving glucocorticoids in combination with other immunosuppressants.

Park et al,12 in a retrospective study of Korean patients treated for rheumatic disease with high-dose glucocorticoids (≥ 30 mg/day of prednisone or equivalent for more than 4 weeks), reported an incidence rate of PCP of 2.37 per 100 patient-years in those not on prophylaxis.

Other studies13,14 have also found a prednisone dose greater than 15 to 20 mg per day for more than 4 weeks or concomitant use of 2 or more disease-modifying antirheumatic drugs to be a significant risk factor.13,14

Tumor necrosis factor alpha antagonists

A US Food and Drug Administration review1 of voluntary reports of adverse drug events estimated the incidence of PCP to be 2.3 per 100,000 patient-years with infliximab and 1.6 per 100,000 patient-years with etanercept. In most cases, other immunosuppressants were used concomitantly.1

Postmarketing surveillance2 of 5,000 patients with rheumatoid arthritis showed an incidence of suspected PCP of 0.4% within the first 6 months of starting infliximab therapy.

Komano et al,15 in a case-control study of patients with rheumatoid arthritis treated with infliximab, reported that all 21 patients with PCP were also on methotrexate (median dosage 8 mg per week) and prednisolone (median dosage 7.5 mg per day).

PCP has also been reported after adalimumab use in combination with prednisone, azathioprine, and methotrexate, as well as with certolizumab, golimumab, tocilizumab, abatacept, and rituximab.3–6,24–26

Rituximab

Calero-Bernal et al11 reported that 23% of patients with non-HIV PCP who were receiving immunosuppressant drugs were on rituximab.

Alexandre et al16 performed a retrospective review of 11 cases of PCP complicating rituximab therapy for autoimmune disease, in which 10 (91%) of the patients were also on corticosteroids, with a median dosage of 30 mg of prednisone daily. A literature review of an additional 18 cases revealed similar findings.

 

 

PATIENT RISK FACTORS FOR PCP

Table 2. Risk factors for Pneumocystis jirovecii pneumonia in patients on biologic therapy for rheumatic disease
Certain clinical, laboratory, and pharmacologic factors are associated with increased risk of PCP (Table 2).3–6,9,17–19,21,22,27

Pulmonary disease, age, other factors

Komano et al,15 in their study of patients with rheumatoid arthritis treated with infliximab, found that 10 (48%) of 21 patients with PCP had preexisting pulmonary disease, compared with 11 (10.8%) of 102 patients without PCP (P < .001). Patients with PCP were older (mean age 64 vs 54, P < .001), were on higher median doses of prednisolone per day (7.5 vs 5 mg, P = .001), and had lower median serum immunoglobulin G (IgG) levels (944 vs 1,394 mg/dL, P < .001).15 

Tadros et al13 performed a case-control study that also showed that patients with autoimmune disease who developed PCP had lower lymphocyte counts than controls on admission. Other risk factors included low CD4 counts and age older than 50.

Li et al17 found that patients with autoimmune or inflammatory disease with PCP were more likely to have low CD3, CD4, and CD8 cell counts, as well as albumin levels less than 28 g/L. They therefore suggested that lymphocyte subtyping may be a useful tool to guide PCP prophylaxis.

Granulomatosis with polyangiitis

Patients with granulomatosis with polyangiitis have a significantly higher incidence of PCP than patients with other connective tissue diseases.

Ward and Donald18 reviewed 223 cases of PCP in patients with connective tissue disease. The highest frequency (89 cases per 10,000 hospitalizations per year) was in patients with granulomatosis with polyangiitis, followed by 65 per 10,000 hospitalizations per year for patients with polyarteritis nodosa. The lowest frequency was in rheumatoid arthritis patients, at 2 per 10,000 hospitalizations per year. In decreasing order, diseases with significant associations with PCP were:

  • Polyarteritis nodosa (odds ratio [OR] 10.20, 95% confidence interval [CI] 5.69–18.29)
  • Granulomatosis with polyangiitis (OR 7.81, 95% CI 4.71–13.05)
  • Inflammatory myopathy (OR 4.44, 95% CI 2.67–7.38)
  • Systemic lupus erythematosus (OR 2.52, 95% CI 1.66–3.82).

Vallabhaneni and Chiller,26 in a meta-analysis including rheumatoid arthritis patients on biologics, did not find an increased risk of PCP (OR 1.77, 95% CI 0.42–7.47).

Park et al12 found that the highest incidences of PCP were in patients with granulomatosis with polyangiitis, microscopic polyangiitis, and systemic sclerosis. For systemic sclerosis, the main reason for giving high-dose glucocorticoids was interstitial lung disease.

Other studies19,20,28 also found an association with coexisting pulmonary disease in patients with rheumatoid arthritis.

CURRENT GUIDELINES

There are guidelines for primary and secondary prophylaxis of PCP in HIV-positive patients with CD4 counts less than 200/mm3 or a history of acquired immunodeficiency syndrome (AIDS)-defining illness.27 Additionally, patients with a CD4 cell percentage less than 14% should be considered for prophylaxis.27

Unfortunately, there are no guidelines for prophylaxis in patients taking immunosuppressants for rheumatic disease.

The recommended regimen for PCP prophylaxis in HIV-infected patients is trimethoprim-sulfamethoxazole, 1 double-strength or 1 single-strength tablet daily. Alternative regimens include 1 double-strength tablet 3 times per week, dapsone, aerosolized pentamidine, and atovaquone.27

There are also guidelines for prophylaxis in kidney transplant recipients, as well as for patients with hematologic malignancies and solid-organ malignancies, particularly those on chemotherapeutic agents and the T-cell-depleting agent alemtuzumab.29–31

Italian clinical practice guidelines for the use of tumor necrosis factor antagonists in inflammatory bowel disease recommend consideration of PCP prophylaxis in patients who are also on other immunosuppressants, particularly high-dose glucocorticoids.32

Prophylaxis has been shown to increase life expectancy and quality-adjusted life-years and to reduce cost for patients on immunosuppressive therapy for granulomatosis with polyangiitis.21 The European Society of Clinical Microbiology and Infectious Diseases recently produced consensus statements recommending PCP prophylaxis for patients on rituximab with other concomitant immunosuppressants such as the equivalent of prednisone 20 mg daily for more than 4 weeks.33 Prophylaxis was not recommended for other biologic therapies.34,35

THE RISKS OF PROPHYLAXIS

The risk of PCP should be weighed against the risk of prophylaxis in patients with rheumatic disease. Adverse reactions to sulfonamide antibiotics including disease flares have been reported in patients with systemic lupus erythematosus.36,37 Other studies have found no increased risk of flares in patients taking trimethoprim-sulfamethoxazole for PCP prophylaxis.12,38 A retrospective analysis of patients with vasculitis found no increased risk of combining methotrexate and trimethoprim-sulfamethoxazole.39

KEY POINTS

  • PCP is an opportunistic infection with a high risk of death.
  • PCP has been reported with biologics used as immunomodulators in rheumatic disease.
  • PCP prophylaxis should be considered in patients at high risk of PCP, such as those who have granulomatosis with polyangiitis, underlying pulmonary disease or who are concomitantly taking glucocorticoids.

Pneumocystis jirovecii (previously carinii) pneumonia (PCP) is rare in patients taking biologic response modifiers for rheumatic disease.1–10 However, prophylaxis should be considered in patients who have granulomatosis with polyangiitis or underlying pulmonary disease, or who are concomitantly receiving glucocorticoids in high doses. There is some risk of adverse reactions to the prophylactic medicine.1,11–21 Until clear guidelines are available, the decision to initiate PCP prophylaxis and the choice of agent should be individualized.

THE BURDEN OF PCP

Table 1. Biologic agents used for rheumatic disease
PCP is a life-threatening opportunistic infection. Common causes of immunosuppression are advanced human immunodeficiency virus (HIV) infection, hematologic malignancy, anti-rejection drugs, chemotherapy, glucocorticoid therapy, and other immunosuppressive drugs. Here, we focus on the risk of PCP with immunomodulatory biologic drugs used for rheumatic disease that deplete B cells or inhibit T-cell activation, cytokine production, or cytokine function (Table 1).22

In a meta-analysis23 of 867 patients who developed PCP and did not have HIV infection, 20.1% had autoimmune or chronic inflammatory disease and the rest were transplant recipients or had malignancies. The mortality rate was 30.6%.

PHARMACOLOGIC RISK FACTORS FOR PCP

Treatment with glucocorticoids

Treatment with glucocorticoids is an important risk factor for PCP, independent of biologic therapy.

Calero-Bernal et al11 reported on 128 patients with non-HIV PCP, of whom 114 (89%) had received a glucocorticoid for more than 4 weeks, and 98 (76%) were currently receiving one. The mean daily dose was equivalent to 27.73 mg of prednisone per day in those on glucocorticoids only, and 21.34 mg in those receiving glucocorticoids in combination with other immunosuppressants.

Park et al,12 in a retrospective study of Korean patients treated for rheumatic disease with high-dose glucocorticoids (≥ 30 mg/day of prednisone or equivalent for more than 4 weeks), reported an incidence rate of PCP of 2.37 per 100 patient-years in those not on prophylaxis.

Other studies13,14 have also found a prednisone dose greater than 15 to 20 mg per day for more than 4 weeks or concomitant use of 2 or more disease-modifying antirheumatic drugs to be a significant risk factor.13,14

Tumor necrosis factor alpha antagonists

A US Food and Drug Administration review1 of voluntary reports of adverse drug events estimated the incidence of PCP to be 2.3 per 100,000 patient-years with infliximab and 1.6 per 100,000 patient-years with etanercept. In most cases, other immunosuppressants were used concomitantly.1

Postmarketing surveillance2 of 5,000 patients with rheumatoid arthritis showed an incidence of suspected PCP of 0.4% within the first 6 months of starting infliximab therapy.

Komano et al,15 in a case-control study of patients with rheumatoid arthritis treated with infliximab, reported that all 21 patients with PCP were also on methotrexate (median dosage 8 mg per week) and prednisolone (median dosage 7.5 mg per day).

PCP has also been reported after adalimumab use in combination with prednisone, azathioprine, and methotrexate, as well as with certolizumab, golimumab, tocilizumab, abatacept, and rituximab.3–6,24–26

Rituximab

Calero-Bernal et al11 reported that 23% of patients with non-HIV PCP who were receiving immunosuppressant drugs were on rituximab.

Alexandre et al16 performed a retrospective review of 11 cases of PCP complicating rituximab therapy for autoimmune disease, in which 10 (91%) of the patients were also on corticosteroids, with a median dosage of 30 mg of prednisone daily. A literature review of an additional 18 cases revealed similar findings.

 

 

PATIENT RISK FACTORS FOR PCP

Table 2. Risk factors for Pneumocystis jirovecii pneumonia in patients on biologic therapy for rheumatic disease
Certain clinical, laboratory, and pharmacologic factors are associated with increased risk of PCP (Table 2).3–6,9,17–19,21,22,27

Pulmonary disease, age, other factors

Komano et al,15 in their study of patients with rheumatoid arthritis treated with infliximab, found that 10 (48%) of 21 patients with PCP had preexisting pulmonary disease, compared with 11 (10.8%) of 102 patients without PCP (P < .001). Patients with PCP were older (mean age 64 vs 54, P < .001), were on higher median doses of prednisolone per day (7.5 vs 5 mg, P = .001), and had lower median serum immunoglobulin G (IgG) levels (944 vs 1,394 mg/dL, P < .001).15 

Tadros et al13 performed a case-control study that also showed that patients with autoimmune disease who developed PCP had lower lymphocyte counts than controls on admission. Other risk factors included low CD4 counts and age older than 50.

Li et al17 found that patients with autoimmune or inflammatory disease with PCP were more likely to have low CD3, CD4, and CD8 cell counts, as well as albumin levels less than 28 g/L. They therefore suggested that lymphocyte subtyping may be a useful tool to guide PCP prophylaxis.

Granulomatosis with polyangiitis

Patients with granulomatosis with polyangiitis have a significantly higher incidence of PCP than patients with other connective tissue diseases.

Ward and Donald18 reviewed 223 cases of PCP in patients with connective tissue disease. The highest frequency (89 cases per 10,000 hospitalizations per year) was in patients with granulomatosis with polyangiitis, followed by 65 per 10,000 hospitalizations per year for patients with polyarteritis nodosa. The lowest frequency was in rheumatoid arthritis patients, at 2 per 10,000 hospitalizations per year. In decreasing order, diseases with significant associations with PCP were:

  • Polyarteritis nodosa (odds ratio [OR] 10.20, 95% confidence interval [CI] 5.69–18.29)
  • Granulomatosis with polyangiitis (OR 7.81, 95% CI 4.71–13.05)
  • Inflammatory myopathy (OR 4.44, 95% CI 2.67–7.38)
  • Systemic lupus erythematosus (OR 2.52, 95% CI 1.66–3.82).

Vallabhaneni and Chiller,26 in a meta-analysis including rheumatoid arthritis patients on biologics, did not find an increased risk of PCP (OR 1.77, 95% CI 0.42–7.47).

Park et al12 found that the highest incidences of PCP were in patients with granulomatosis with polyangiitis, microscopic polyangiitis, and systemic sclerosis. For systemic sclerosis, the main reason for giving high-dose glucocorticoids was interstitial lung disease.

Other studies19,20,28 also found an association with coexisting pulmonary disease in patients with rheumatoid arthritis.

CURRENT GUIDELINES

There are guidelines for primary and secondary prophylaxis of PCP in HIV-positive patients with CD4 counts less than 200/mm3 or a history of acquired immunodeficiency syndrome (AIDS)-defining illness.27 Additionally, patients with a CD4 cell percentage less than 14% should be considered for prophylaxis.27

Unfortunately, there are no guidelines for prophylaxis in patients taking immunosuppressants for rheumatic disease.

The recommended regimen for PCP prophylaxis in HIV-infected patients is trimethoprim-sulfamethoxazole, 1 double-strength or 1 single-strength tablet daily. Alternative regimens include 1 double-strength tablet 3 times per week, dapsone, aerosolized pentamidine, and atovaquone.27

There are also guidelines for prophylaxis in kidney transplant recipients, as well as for patients with hematologic malignancies and solid-organ malignancies, particularly those on chemotherapeutic agents and the T-cell-depleting agent alemtuzumab.29–31

Italian clinical practice guidelines for the use of tumor necrosis factor antagonists in inflammatory bowel disease recommend consideration of PCP prophylaxis in patients who are also on other immunosuppressants, particularly high-dose glucocorticoids.32

Prophylaxis has been shown to increase life expectancy and quality-adjusted life-years and to reduce cost for patients on immunosuppressive therapy for granulomatosis with polyangiitis.21 The European Society of Clinical Microbiology and Infectious Diseases recently produced consensus statements recommending PCP prophylaxis for patients on rituximab with other concomitant immunosuppressants such as the equivalent of prednisone 20 mg daily for more than 4 weeks.33 Prophylaxis was not recommended for other biologic therapies.34,35

THE RISKS OF PROPHYLAXIS

The risk of PCP should be weighed against the risk of prophylaxis in patients with rheumatic disease. Adverse reactions to sulfonamide antibiotics including disease flares have been reported in patients with systemic lupus erythematosus.36,37 Other studies have found no increased risk of flares in patients taking trimethoprim-sulfamethoxazole for PCP prophylaxis.12,38 A retrospective analysis of patients with vasculitis found no increased risk of combining methotrexate and trimethoprim-sulfamethoxazole.39

KEY POINTS

  • PCP is an opportunistic infection with a high risk of death.
  • PCP has been reported with biologics used as immunomodulators in rheumatic disease.
  • PCP prophylaxis should be considered in patients at high risk of PCP, such as those who have granulomatosis with polyangiitis, underlying pulmonary disease or who are concomitantly taking glucocorticoids.
References
  1. US Food and Drug Administration. Safety update on TNF-alpha antagonists: infliximab and etanercept.https://wayback.archive-it.org/7993/20180127041103/https://www.fda.gov/ohrms/dockets/ac/01/briefing/3779b2_01_cber_safety_revision2.htm. Accessed May 3, 2019.
  2. Takeuchi T, Tatsuki Y, Nogami Y, et al. Postmarketing surveillance of the safety profile of infliximab in 5000 Japanese patients with rheumatoid arthritis. Ann Rheum Dis 2008; 67(2):189–194. doi:10.1136/ard.2007.072967
  3. Koike T, Harigai M, Ishiguro N, et al. Safety and effectiveness of adalimumab in Japanese rheumatoid arthritis patients: postmarketing surveillance report of the first 3,000 patients. Mod Rheumatol 2012; 22(4):498–508. doi:10.1007/s10165-011-0541-5
  4. Bykerk V, Cush J, Winthrop K, et al. Update on the safety profile of certolizumab pegol in rheumatoid arthritis: an integrated analysis from clinical trials. Ann Rheum Dis 2015; 74(1):96–103. doi:10.1136/annrheumdis-2013-203660
  5. Koike T, Harigai M, Inokuma S, et al. Postmarketing surveillance of tocilizumab for rheumatoid arthritis in Japan: interim analysis of 3881 patients. Ann Rheum Dis 2011; 70(12):2148–2151. doi:10.1136/ard.2011.151092
  6. Harigai M, Ishiguro N, Inokuma S, et al. Postmarketing surveillance of the safety and effectiveness of abatacept in Japanese patients with rheumatoid arthritis. Mod Rheumatol 2016; 26(4):491–498. doi:10.3109/14397595.2015.1123211
  7. Koike T, Harigai M, Inokuma S, et al. Postmarketing surveillance of the safety and effectiveness of etanercept in Japan. J Rheumatol 2009; 36(5):898–906. doi:10.3899/jrheum.080791
  8. Grubbs JA, Baddley JW. Pneumocystis jirovecii pneumonia in patients receiving tumor-necrosis-factor-inhibitor therapy: implications for chemoprophylaxis. Curr Rheumatol Rep 2014; 16(10):445. doi:10.1007/s11926-014-0445-4
  9. US Food and Drug Administration. FDA adverse event reporting system (FAERS) public dashboard. www.fda.gov/Drugs/GuidanceComplianceRegulatoryInformation/Surveillance/AdverseDrugEffects/ucm070093.htm. Accessed May 3, 2019.
  10. Rutherford AI, Patarata E, Subesinghe S, Hyrich KL, Galloway JB. Opportunistic infections in rheumatoid arthritis patients exposed to biologic therapy: results from the British Society for Rheumatology Biologics Register for Rheumatoid Arthritis. Rheumatology (Oxford) 2018; 57(6):997–1001. doi:10.1093/rheumatology/key023
  11. Calero-Bernal ML, Martin-Garrido I, Donazar-Ezcurra M, Limper AH, Carmona EM. Intermittent courses of corticosteroids also present a risk for Pneumocystis pneumonia in non-HIV patients. Can Respir J 2016; 2016:2464791. doi:10.1155/2016/2464791
  12. Park JW, Curtis JR, Moon J, Song YW, Kim S, Lee EB. Prophylactic effect of trimethoprim-sulfamethoxazole for pneumocystis pneumonia in patients with rheumatic diseases exposed to prolonged high-dose glucocorticoids. Ann Rheum Dis 2018; 77(5):644–649. doi:10.1136/annrheumdis-2017-211796
  13. Tadros S, Teichtahl AJ, Ciciriello S, Wicks IP. Pneumocystis jirovecii pneumonia in systemic autoimmune rheumatic disease: a case-control study. Semin Arthritis Rheum 2017; 46(6):804–809. doi:10.1016/j.semarthrit.2016.09.009
  14. Demoruelle MK, Kahr A, Verilhac K, Deane K, Fischer A, West S. Recent-onset systemic lupus erythematosus complicated by acute respiratory failure. Arthritis Care Res (Hoboken) 2013; 65(2):314–323. doi:10.1002/acr.21857
  15. Komano Y, Harigai M, Koike R, et al. Pneumocystis jiroveci pneumonia in patients with rheumatoid arthritis treated with infliximab: a retrospective review and case-control study of 21 patients. Arthritis Rheum 2009; 61(3):305–312. doi:10.1002/art.24283
  16. Alexandre K, Ingen-Housz-Oro S, Versini M, Sailler L, Benhamou Y. Pneumocystis jirovecii pneumonia in patients treated with rituximab for systemic diseases: report of 11 cases and review of the literature. Eur J Intern Med 2018; 50:e23–e24. doi:10.1016/j.ejim.2017.11.014
  17. Li Y, Ghannoum M, Deng C, et al. Pneumocystis pneumonia in patients with inflammatory or autoimmune diseases: usefulness of lymphocyte subtyping. Int J Infect Dis 2017; 57:108–115. doi:10.1016/j.ijid.2017.02.010
  18. Ward MM, Donald F. Pneumocystis carinii pneumonia in patients with connective tissue diseases: the role of hospital experience in diagnosis and mortality. Arthritis Rheum 1999; 42(4):780–789. doi:10.1002/1529-0131(199904)42:4<780::AID-ANR23>3.0.CO;2-M
  19. Katsuyama T, Saito K, Kubo S, Nawata M, Tanaka Y. Prophylaxis for Pneumocystis pneumonia in patients with rheumatoid arthritis treated with biologics, based on risk factors found in a retrospective study. Arthritis Res Ther 2014; 16(1):R43. doi:10.1186/ar4472
  20. Tanaka M, Sakai R, Koike R, et al. Pneumocystis jirovecii pneumonia associated with etanercept treatment in patients with rheumatoid arthritis: a retrospective review of 15 cases and analysis of risk factors. Mod Rheumatol 2012; 22(6):849–858. doi:10.1007/s10165-012-0615-z
  21. Chung JB, Armstrong K, Schwartz JS, Albert D. Cost-effectiveness of prophylaxis against Pneumocystis carinii pneumonia in patients with Wegener’s granulomatosis undergoing immunosuppressive therapy. Arthritis Rheum 2000; 43(8):1841–1848. doi:10.1002/1529-0131(200008)43:8<1841::AID-ANR21>3.0.CO;2-Q
  22. Selmi C, Generali E, Massarotti M, Bianchi G, Scire CA. New treatments for inflammatory rheumatic disease. Immunol Res 2014; 60(2–3):277–288. doi:10.1007/s12026-014-8565-5
  23. Liu Y, Su L, Jiang SJ, Qu H. Risk factors for mortality from Pneumocystis carinii pneumonia (PCP) in non-HIV patients: a meta-analysis. Oncotarget 2017; 8(35):59729–59739. doi:10.18632/oncotarget.19927
  24. Desales AL, Mendez-Navarro J, Méndez-Tovar LJ, et al. Pneumocystosis in a patient with Crohn's disease treated with combination therapy with adalimumab. J Crohns Colitis 2012; 6(4):483–487. doi:10.1016/j.crohns.2011.10.012
  25. Kalyoncu U, Karadag O, Akdogan A, et al. Pneumocystis carinii pneumonia in a rheumatoid arthritis patient treated with adalimumab. Scand J Infect Dis 2007; 39(5):475–478. doi:10.1080/00365540601071867
  26. Vallabhaneni S, Chiller TM. Fungal infections and new biologic therapies. Curr Rheumatol Rep 2016; 18(5):29. doi:10.1007/s11926-016-0572-1
  27. Panel on Opportunistic Infections in HIV-Infected Adults and Adolescents. Guidelines for the prevention and treatment of opportunistic infections in HIV-infected adults and adolescents: recommendations from the Centers for Disease Control and Prevention, the National Institutes of Health, and the HIV Medicine Association of the Infectious Diseases Society of America. www.aidsinfo.nih.gov/contentfiles/lvguidelines/adult_oi.pdf. Accessed May 3, 2019.
  28. Kourbeti IS, Ziakas PD, Mylonakis E. Biologic therapies in rheumatoid arthritis and the risk of opportunistic infections: a meta-analysis. Clin Infect Dis 2014; 58(12):1649–1657. doi:10.1093/cid/ciu185
  29. Bia M, Adey DB, Bloom RD, Chan L, Kulkarni S, Tomlanovich S. KDOQI US commentary on the 2009 KDIGO clinical practice guideline for the care of kidney transplant recipients. Am J Kidney Dis 2010; 56(2):189–218. doi:10.1053/j.ajkd.2010.04.010
  30. Baden LR, Swaminathan S, Angarone M, et al. Prevention and treatment of cancer-related infections, version 2.2016, NCCN clinical practice guidelines in oncology. J Natl Compr Canc Netw 2016; 14(7):882–913. pmid:27407129
  31. Cooley L, Dendle C, Wolf J, et al. Consensus guidelines for diagnosis, prophylaxis and management of Pneumocystis jirovecii pneumonia in patients with haematological and solid malignancies, 2014. Intern Med J 2014; 44(12b):1350–1363. doi:10.1111/imj.12599
  32. Orlando A, Armuzzi A, Papi C, et al; Italian Society of Gastroenterology; Italian Group for the study of Inflammatory Bowel Disease. The Italian Society of Gastroenterology (SIGE) and the Italian Group for the study of Inflammatory Bowel Disease (IG-IBD) clinical practice guidelines: the use of tumor necrosis factor-alpha antagonist therapy in inflammatory bowel disease. Dig Liver Dis 2011; 43(1):1–20. doi:10.1016/j.dld.2010.07.010
  33. Mikulska M, Lanini S, Gudiol C, et al. ESCMID Study Group for Infections in Compromised Hosts (ESGICH) consensus document on the safety of targeted and biological therapies: an infectious diseases perspective (agents targeting lymphoid cells surface antigens [I]: CD19, CD20 and CD52). Clin Microbiol Infect 2018; 24(suppl 2):S71–S82. doi:10.1016/j.cmi.2018.02.003
  34. Baddley J, Cantini F, Goletti D, et al. ESCMID Study Group for Infections in Compromised Hosts (ESGICH) consensus document on the safety of targeted and biological therapies: an infectious diseases perspective (soluble immune effector molecules [I]: anti-tumor necrosis factor-alpha agents). Clin Microbiol Infect 2018; 24(suppl 2):S10–S20. doi:10.1016/j.cmi.2017.12.025
  35. Winthrop K, Mariette X, Silva J, et al. ESCMID Study Group for Infections in Compromised Hosts (ESGICH) consensus document on the safety of targeted and biological therapies: an infectious diseases perspective (soluble immune effector molecules [II]: agents targeting interleukins, immunoglobulins and complement factors). Clin Microbiol Infect 2018; 24(suppl 2):S21–S40. doi:10.1016/j.cmi.2018.02.002
  36. Petri M, Allbritton J. Antibiotic allergy in systemic lupus erythematosus: a case-control study. J Rheumatol 1992; 19(2):265–269. pmid:1629825
  37. Pope J, Jerome D, Fenlon D, Krizova A, Ouimet J. Frequency of adverse drug reactions in patients with systemic lupus erythematosus. J Rheumatol 2003; 30(3):480–484. pmid:12610805
  38. Vananuvat P, Suwannalai P, Sungkanuparph S, Limsuwan T, Ngamjanyaporn P, Janwityanujit S. Primary prophylaxis for Pneumocystis jirovecii pneumonia in patients with connective tissue diseases. Semin Arthritis Rheum 2011; 41(3):497–502. doi:10.1016/j.semarthrit.2011.05.004
  39. Tamaki H, Butler R, Langford C. Abstract Number: 1755: Safety of methotrexate and low-dose trimethoprim-sulfamethoxazole in patients with ANCA-associated vasculitis. www.acrabstracts.org/abstract/safety-of-methotrexate-and-low-dose-trimethoprim-sulfamethoxazole-in-patients-with-anca-associated-vasculitis. Accessed May 3, 2019.
References
  1. US Food and Drug Administration. Safety update on TNF-alpha antagonists: infliximab and etanercept.https://wayback.archive-it.org/7993/20180127041103/https://www.fda.gov/ohrms/dockets/ac/01/briefing/3779b2_01_cber_safety_revision2.htm. Accessed May 3, 2019.
  2. Takeuchi T, Tatsuki Y, Nogami Y, et al. Postmarketing surveillance of the safety profile of infliximab in 5000 Japanese patients with rheumatoid arthritis. Ann Rheum Dis 2008; 67(2):189–194. doi:10.1136/ard.2007.072967
  3. Koike T, Harigai M, Ishiguro N, et al. Safety and effectiveness of adalimumab in Japanese rheumatoid arthritis patients: postmarketing surveillance report of the first 3,000 patients. Mod Rheumatol 2012; 22(4):498–508. doi:10.1007/s10165-011-0541-5
  4. Bykerk V, Cush J, Winthrop K, et al. Update on the safety profile of certolizumab pegol in rheumatoid arthritis: an integrated analysis from clinical trials. Ann Rheum Dis 2015; 74(1):96–103. doi:10.1136/annrheumdis-2013-203660
  5. Koike T, Harigai M, Inokuma S, et al. Postmarketing surveillance of tocilizumab for rheumatoid arthritis in Japan: interim analysis of 3881 patients. Ann Rheum Dis 2011; 70(12):2148–2151. doi:10.1136/ard.2011.151092
  6. Harigai M, Ishiguro N, Inokuma S, et al. Postmarketing surveillance of the safety and effectiveness of abatacept in Japanese patients with rheumatoid arthritis. Mod Rheumatol 2016; 26(4):491–498. doi:10.3109/14397595.2015.1123211
  7. Koike T, Harigai M, Inokuma S, et al. Postmarketing surveillance of the safety and effectiveness of etanercept in Japan. J Rheumatol 2009; 36(5):898–906. doi:10.3899/jrheum.080791
  8. Grubbs JA, Baddley JW. Pneumocystis jirovecii pneumonia in patients receiving tumor-necrosis-factor-inhibitor therapy: implications for chemoprophylaxis. Curr Rheumatol Rep 2014; 16(10):445. doi:10.1007/s11926-014-0445-4
  9. US Food and Drug Administration. FDA adverse event reporting system (FAERS) public dashboard. www.fda.gov/Drugs/GuidanceComplianceRegulatoryInformation/Surveillance/AdverseDrugEffects/ucm070093.htm. Accessed May 3, 2019.
  10. Rutherford AI, Patarata E, Subesinghe S, Hyrich KL, Galloway JB. Opportunistic infections in rheumatoid arthritis patients exposed to biologic therapy: results from the British Society for Rheumatology Biologics Register for Rheumatoid Arthritis. Rheumatology (Oxford) 2018; 57(6):997–1001. doi:10.1093/rheumatology/key023
  11. Calero-Bernal ML, Martin-Garrido I, Donazar-Ezcurra M, Limper AH, Carmona EM. Intermittent courses of corticosteroids also present a risk for Pneumocystis pneumonia in non-HIV patients. Can Respir J 2016; 2016:2464791. doi:10.1155/2016/2464791
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Cleveland Clinic Journal of Medicine - 86(7)
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Cleveland Clinic Journal of Medicine - 86(7)
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449-453
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Do patients on biologic drugs for rheumatic disease need PCP prophylaxis?
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Do patients on biologic drugs for rheumatic disease need PCP prophylaxis?
Legacy Keywords
Pneumocystis jirovecii, Pneumocystis carinii, pneumonia, PCP, prophylaxis, biologics, biologic response modifiers, glucocorticoids, tumor necrosis factor alpha antagonists, TNF antagonists, anti-tumor necrosis factor alpha agents, adalimumab, certolizumab, etanercept, golimumab, infliximab, interleukin 1 receptor antagonists, anakinra, canakinumab, rilonacept, interleukin 1 receptor antagonists, IL-1 antagonists, mepolizumab, interleukin 6 receptor antagonists, IL-6 antagonists, sarilumab, tocilizumab, interleukin 12/23 antagonist, ustekinumab, interleukin 17 antagonists, ixekizumab, secukinumab, T-cell costimulation blocker, abatacept, anti-CD20 antibody, rituximab, anti-B-cell activating factor, B-lymphocyte stimulator antibody, belimumab, opportunistic infections, immunocompromised, sulfamethoxazole, trimethoprim, Bactrim, Joy-Ann Tabanor, Santhanam Lakshminarayanan
Legacy Keywords
Pneumocystis jirovecii, Pneumocystis carinii, pneumonia, PCP, prophylaxis, biologics, biologic response modifiers, glucocorticoids, tumor necrosis factor alpha antagonists, TNF antagonists, anti-tumor necrosis factor alpha agents, adalimumab, certolizumab, etanercept, golimumab, infliximab, interleukin 1 receptor antagonists, anakinra, canakinumab, rilonacept, interleukin 1 receptor antagonists, IL-1 antagonists, mepolizumab, interleukin 6 receptor antagonists, IL-6 antagonists, sarilumab, tocilizumab, interleukin 12/23 antagonist, ustekinumab, interleukin 17 antagonists, ixekizumab, secukinumab, T-cell costimulation blocker, abatacept, anti-CD20 antibody, rituximab, anti-B-cell activating factor, B-lymphocyte stimulator antibody, belimumab, opportunistic infections, immunocompromised, sulfamethoxazole, trimethoprim, Bactrim, Joy-Ann Tabanor, Santhanam Lakshminarayanan
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