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The Canadian Cardiovascular Society 2018 guideline update for atrial fibrillation – A different perspective

Published online by Cambridge University Press:  25 September 2019

Ian G. Stiell*
Affiliation:
Department of Emergency Medicine, Ottawa Hospital Research Institute, University of Ottawa, Ottawa, ON
M. Sean McMurtry
Affiliation:
Division of Cardiology, University of Alberta, Edmonton, AB
Andrew McRae
Affiliation:
Departments of Emergency Medicine and Community Health Sciences, University of Calgary, Calgary, AB
Ratika Parkash
Affiliation:
Division of Cardiology, Dalhousie University, Halifax, NS
Frank Scheuermeyer
Affiliation:
Department of Emergency Medicine, University of British Columbia, Center for Health Evaluation and Outcome Sciences, Vancouver, BC
Clare L. Atzema
Affiliation:
Division of Emergency Medicine, University of Toronto, Sunnybrook Health Sciences Centre, and ICES, Toronto, ON
Allan Skanes
Affiliation:
Division of Cardiology, Western University, London, ON
*
Correspondence to: Dr. Ian G. Stiell, Clinical Epidemiology Unit, F657, The Ottawa Hospital, 1053 Carling Avenue, Ottawa, ON K1Y 4E9; Email: [email protected]

Abstract

Type
Commentary
Copyright
Copyright © Canadian Association of Emergency Physicians 2019 

INTRODUCTION

In 2018, the Canadian Cardiovascular Society (CCS) published a Focused Update of guidelines for the management of atrial fibrillation (AF).Reference Andrade, Verma and Mitchell1 Some of the updates differ from the Canadian Association of Emergency Physicians (CAEP) 2018 Acute AF Best Practices Checklist.Reference Stiell, Scheuermeyer and Vadeboncoeur2 For emergency department (ED) physicians, the CCS 2018 Update suggested two significant changes: 1) a restriction on which patients can safely undergo cardioversion and 2) an advisory that all acute AF patients undergoing cardioversion be prescribed four weeks of anticoagulation, regardless of age or comorbidity. Both were “weak recommendation status” based upon “low quality evidence” according to the Grading of Recommendations, Assessment, Development, and Evaluation (GRADE) standards.Reference Guyatt, Oxman and Vist3 These changes were controversial, prompting two additional articles in the Canadian Journal of Cardiology, one by the leaders of the CCS changes and the other by the authors of this commentary.Reference Andrade and Mitchell4,Reference Stiell, McMurtry and McRae5 Here we summarize the main issues as they relate to management of acute AF by ED physicians.

GUIDELINE UPDATE

The 2018 Update made 18 recommendations, and this review will focus on recommendations 2 and 6. Recommendation 2 updates the prior “48-hour rule” that has been recommended by the CCS since 1996, a change driven by several large observational studies from Finland.Reference Airaksinen, Gronberg and Nuotio6,Reference Nuotio, Hartikainen, Gronberg, Biancari and Airaksinen7 It now restricts safe cardioversion in non-valvular AF patients with a CHADS2 score > 2 to those who present within 12 hours of onset (provided no stroke or transient ischemic attack (TIA) occurred in the past 6 months). Those who have a CHADS2 score < 2 may be safely cardioverted up to 48 hours from onset.

Recommendation 6 suggests that, regardless of age or comorbidity, all AF patients undergoing cardioversion receive anticoagulation for 4 weeks. Previously, CCS guidelines recommended long-term anticoagulation only for patients at higher risk of stroke (CHADS-65 positive), but CCS panelists placed “greater emphasis on the benefits of stroke prevention compared with the risks of bleeding.” The panel acknowledged that “it might be possible to parse these risks either on the basis patient characteristics or the duration of acute AF/AFL,” but chose not to do so.Reference Andrade, Verma and Mitchell1

EMERGENCY DEPARTMENT CHALLENGES

Acute-onset AF contributes to 50,000 annual Canadian ED visits.Reference O'Reilly, Hopkins and Healey8 Typically, Canadian ED physicians use chemical or electrical cardioversion followed by early discharge home without cardiologist involvement.Reference Stiell, Clement and Rowe9,Reference Scheuermeyer10 In 2018, the CAEP formally adapted the prior CCS AF guidelines for ED use.Reference Stiell, Scheuermeyer and Vadeboncoeur2 The CAEP panel included three cardiologists but also sought widespread input from both the cardiology and emergency medicine communities. The CAEP Checklist recommends cardioversion by drug or shock, early ED discharge, and a prescription of oral anticoagulants (OACs) for all patients who are CHADS-65 positive.

CAEP members are expressing concern about Recommendations 2 and 6, reporting that they are being advised by cardiology colleagues that these are now “standard of care,” despite the designation of a weak recommendation. Recommendation 2 is challenging for ED physicians in its reliance on CHADS2 to guide decision-making on the timing of cardioversion, in contrast with recent encouragement to use the CHADS-65 algorithm.Reference Neumann, Santesso and Akl27 Although recommendation 3 endorses transesophageal echocardiography to assure safety of urgent cardioversion, this procedure is rarely available on a same-day basis in Canadian hospitals. Recommendation 2, however, is similar to the CAEP Checklist statement, which recommended no cardioversion for patients if onset > 24 hours and two or more CHADS-65 criteria. Consequently, it is not a substantial practice change for Canadian ED physicians to restrict cardioversion for patients with two or more CHADS-65 criteria to those presenting within 12 hours of onset.

Recommendation 6, however, represents a large practice change for Canadian ED physicians when managing CHADS-65 negative patients. Given the lack of evidence that OAC reduces the risk of stroke in such low-risk patients, Canadian emergency physicians are concerned at the prospect of prescribing OAC to younger patients. These patients may participate in activities that may lead to head injuries (e.g., contact sports, cycling) and may be at higher risk of bleeding than they are of a stroke. In addition, a prescription of OAC to CHADS-65 negative patients raises other patient-important issues. OAC initiation after spontaneous cardioversion is not mentioned. Warfarin in naïve patients may take a considerable time to initiate and stabilize, missing the period of highest risk. In some provinces, novel OAC costs are borne by the patient, particularly for those under age 65. It is challenging to initiate OAC in the ED, even for patients who are CHADS-65 positive and who need lifelong anticoagulation.Reference Scheuermeyer, Innes and Pourvali11 Although presented as a weak recommendation, the suggestion to prescribe a minimum of 4 weeks OAC to all patients carries substantial weight and risks an unwarranted change in practice. Importantly, the GRADE system encourages physicians to apply weak recommendations on a patient-specific basis, considering both clinical factors as well as patient values and preferences.

SUMMARY OF STUDIES

The standard 48-hour threshold for safe cardioversion, although empirically developed, has been adopted widely into clinical practice.Reference Verma, Cairns and Mitchell12 Seven observational cohort studies and three recent randomized trials (from 2019) were specifically limited to the patients in question (AF duration ≤ 48 hours)Reference Stiell, Clement and Rowe9,Reference Weigner, Caulfield, Danias, Silverman and Manning13Reference Pluymaekers, Dudink and Luermans19 Among 4,200 patients, thromboembolic events were rare (7 of 4,200 patients, 0.17%) after cardioversion for acute AF. Since the 48-hour safety threshold was endorsed by the CCS AF Guideline panel,Reference Verma, Cairns and Mitchell12,Reference Stiell and Macle20 several large retrospective analyses have challenged this timing.Reference Airaksinen, Gronberg and Nuotio6,Reference Nuotio, Hartikainen, Gronberg, Biancari and Airaksinen7 Retrospective analyses of 10,852 cardioversions in 5,441 patients from Finland found that cardioversion in patients with 12–48 hours of symptoms had a higher thromboembolic risk (30 of 2,777 patients, 1.1%) compared with cardioversion in patients with less than 12 hours of symptoms (8 of 2,440 patients, 0.33%).Reference Nuotio, Hartikainen, Gronberg, Biancari and Airaksinen7 There was no such time-dependent effect for patients who were anticoagulated.Reference Hellman, Kiviniemi and Nuotio21

These observational studies also suggest that OAC offers an important reduction in stroke risk for patients undergoing cardioversion for acute AF/AFLReference Garg, Khunger, Seicean, Chung and Tchou22 in patients with a CHA2DS2-VASc ≥ 2. This was not demonstrated in those with CHA2DS2-VASc 0 or 1. Retrospective analyses from two other large registries of patients undergoing cardioversion, each demonstrated higher rates of 30-day thromboembolic events without OAC.Reference Hansen, Jepsen and Olesen23,Reference Sjalander, Svensson and Friberg24 Importantly, in one of these studies, there were no events among 4,941 patients in the lowest risk subgroup (CHA2DS2-VASc 0 or 1) and who were not on OAC, a detail not clarified in the other study. A significant limitation was that time of symptom onset prior to cardioversion was not known.

Contemporary prospective data in six Canadian EDs documented only one stroke among 1,091 patients undergoing cardioversion under 48 hours without OAC.Reference Stiell, Clement and Rowe9 A recent randomized controlled trial compared outcomes among 437 patients undergoing early or delayed cardioversion. OAC use was not prescribed, and only two strokes were recorded at 30 days, one in each arm.Reference Pluymaekers, Dudink and Luermans19 Two other randomized trials, not yet published, followed 480 patients treated in Canadian EDs with cardioversion for 30 days and found no strokes.Reference Scheuermeyer, Andolfatto, Christenson, Villa-Roel and Rowe25,Reference Stiell, Perry and Birnie26 Cumulatively, these prospective studies have a thromboembolic event rate that is too low to determine the impact of OAC on cardioversion. Nevertheless, the risk of stroke in contemporary practice remains remarkably low. Unfortunately, only retrospective studies are sufficiently large to assess the impact of OAC on stroke rates in the ED. They are limited by not being specifically focused on patients with AF < 48 hours duration, or who had OAC initiated at ED discharge as per CCS guideline recommendations. For patients at very low stroke risk, there is no direct evidence to support or refute the benefit of short-term OAC in the above-mentioned observational studies.

Until large prospective studies can be performed, decision-makers and guideline writers face the dilemma of making a recommendation based on low quality retrospective data or overlooking a signal of potential harm, reassured by a very small number of events in prospective studies.Reference Stiell, McMurtry and McRae5

GRADE WEAK RECOMMENDATION

The CCS guideline panels use the GRADE system, formal approach guideline development, involving rigorous approaches for grading evidence and for translating summarized evidence into recommendations.Reference Guyatt, Oxman and Vist3 An appeal of GRADE is the ability to quantitate both the quality of evidence (high, moderate, low, or very low, depending upon study limitations) and the strength of the recommendations resulting from such evidence (strong or weak).

To optimally implement weak recommendations into practice, physicians must balance an imperfect set of supporting evidence (with concomitant uncertainty in both treatment effects and treatment hazards for a specific patient) with that patient's individual values and preferences.Reference Neumann, Santesso and Akl27 This approach is a form of shared decision-making between the physician and the patient.Reference Stiggelbout, Van der Weijden and De Wit28 We must realize that clinical practice guidelines are not a substitute for patient-focused judgement at the bedside. Further, we cannot expect that evidence-based practice will result in uniformity of care as we incorporate uncertainty about risks and benefits or values and preferences into individual clinical decisions.Reference Djulbegovic and Guyatt29

BOTTOM LINE FOR ED PHYSICIANS

Box 1 summarizes best practices for who can be safely cardioverted and who requires anticoagulation. All CHADS-65 positive patients clearly require indefinite oral anticoagulation unless absolutely contraindicated. For patients who are CHADS-65 negative, a weak recommendation implies that anticoagulation for 4 weeks is neither mandatory nor the standard of care. Rather this is an opportunity to apply patient-focused clinical judgement. Consideration of longer duration of AF, female sex, presence of vascular disease and other comorbidities, as well as patient preference and values, may encourage oral anticoagulation for 4 weeks after cardioversion. In the absence of those factors, it may be reasonable to forego OAC. The risk in broad application of oral anticoagulation post-cardioversion is bleeding, especially for those engaged in activities prone to head injury. This must be weighed against the risk of a thromboembolic event post-cardioversion. Fortunately, in CHADS-65 negative patients, both the risk of thromboembolism after cardioversion and the risk of bleeding associated with a simple 4-week course of OAC appear very low. Until there is better evidence to guide us, ED physicians should exercise prudent clinical judgement paired with shared decision-making with their patients.

Box 1. Summary of current recommendations for cardioversion and anticoagulation in acute atrial fibrillation.

  1. 1 Cardioversion for non-valvular acute AF patients who are not anticoagulated and have not had a stroke or TIA (in the past 6 months) should be restricted to those who:

    1. a) Present within 12 hours of onset if they have two or more CHADS-65 criteria, unless they can be cleared by transesophageal echocardiography

    2. b) Present within 48 hours of onset if they have 0 or 1 CHADS-65 criteria, unless they can be cleared by transesophageal echocardiography

  2. 2 Anticoagulation post-cardioversion:

    1. a) Should be prescribed indefinitely for patients who are CHADS-65 positive

    2. b) Might be considered for a 4-week period for patients who are CHADS-65 negative after careful consideration of risks and benefits and a shared decision-making process with the patient

Competing interests

None declared.

References

REFERENCES

1.Andrade, JG, Verma, A, Mitchell, LB, et al. 2018 Focused update of the Canadian Cardiovascular Society guidelines for the management of atrial fibrillation. Can J Cardiol 2018;34(11):1371–92.Google Scholar
2.Stiell, IG, Scheuermeyer, FX, Vadeboncoeur, A, et al. CAEP acute atrial fibrillation/flutter best practices checklist. CJEM 2018;20(3):334–42.Google Scholar
3.Guyatt, GH, Oxman, AD, Vist, GE, et al. GRADE: an emerging consensus on rating quality of evidence and strength of recommendations. BMJ 2008;336(7650):924–6.Google Scholar
4.Andrade, JG, Mitchell, LB. Evidence base for emergency department anticoagulation practices in atrial fibrillation: a conundrum and possible approaches. Can J Cardiol 2019; in press.Google Scholar
5.Stiell, IG, McMurtry, MS, McRae, A, et al. Safe cardioversion for patients with acute-onset atrial fibrillation and flutter: practical concerns and considerations. Can J Cardiol 2019; in press.Google Scholar
6.Airaksinen, KE, Gronberg, T, Nuotio, I, et al. Thromboembolic complications after cardioversion of acute atrial fibrillation: the FinCV (Finnish CardioVersion) study. J Am Coll Cardiol 2013;62(13):1187–92.10.1016/j.jacc.2013.04.089Google Scholar
7.Nuotio, I, Hartikainen, JE, Gronberg, T, Biancari, F, Airaksinen, KE. Time to cardioversion for acute atrial fibrillation and thromboembolic complications. JAMA 2014;312(6):647–9.Google Scholar
8.O'Reilly, DJ, Hopkins, RB, Healey, JS, et al. The burden of atrial fibrillation on the hospital sector in Canada. Can J Cardiol 2013;29(2):229–35.10.1016/j.cjca.2012.03.023Google Scholar
9.Stiell, IG, Clement, CM, Rowe, BH, et al. Outcomes for ED patients with recent-onset atrial fibrillation and flutter (RAFF) treated in Canadian hospitals. Ann Emerg Med 2017;69(5):562–71.10.1016/j.annemergmed.2016.10.013Google Scholar
10.Scheuermeyer, FX. New frontiers in Canadian atrial fibrillation management. CJEM 2018;20(3):323–4.Google Scholar
11.Scheuermeyer, FX, Innes, G, Pourvali, R, et al. Missed opportunities for appropriate anticoagulation among emergency department patients with uncomplicated atrial fibrillation or flutter. Ann Emerg Med 2013;62(6):557–65.Google Scholar
12.Verma, A, Cairns, JA, Mitchell, LB, et al. 2014 focused update of the Canadian Cardiovascular Society guidelines for the management of atrial fibrillation. Can J Cardiol 2014;30(10):1114–30.10.1016/j.cjca.2014.08.001Google Scholar
13.Weigner, MJ, Caulfield, TA, Danias, PG, Silverman, DI, Manning, WJ. Risk for clinical thromboembolism associated with conversion to sinus rhythm in patients with atrial fibrillation lasting less than 48 hours. Ann Intern Med 1997;126(8):615–20.10.7326/0003-4819-126-8-199704150-00005Google Scholar
14.Michael, JA, Stiell, IG, Agarwal, S, Mandavia, DP. Cardioversion of paroxysmal atrial fibrillation in the emergency department. Ann Emerg Med 1999;33:379–87.10.1016/S0196-0644(99)70300-8Google Scholar
15.Gallagher, MM, Hennessy, BJ, Edvardsson, N, et al. Embolic complications of direct current cardioversion of atrial arrhythmias: association with low intensity of anticoagulation at the time of cardioversion. J Am Coll Cardiol 2002;40(5):926–33.Google Scholar
16.Burton, JH, Vinson, DR, Drummond, K, et al. Electrical cardioversion of emergency department patients with atrial fibrillation. Ann Emerg Med 2004;44(1):2030.Google Scholar
17.Stiell, IG, Clement, CM, Perry, JJ, et al. An aggressive protocol for rapid management and discharge of emergency department patients with recent-onset episodes of atrial fibrillation and flutter. CJEM 2010;12(3):181–91.10.1017/S1481803500012227Google Scholar
18.Scheuermeyer, FX, Grafstein, E, Stenstrom, R, et al. Thirty-day outcomes of emergency department patients undergoing electrical cardioversion for atrial fibrillation or flutter. Acad Emerg Med 2010;17(4):408–15.Google Scholar
19.Pluymaekers, NAHA, Dudink, EAMP, Luermans, JGLM, et al. Early or delayed cardioversion in recent-onset atrial fibrillation. N Engl J Med 2019;380(16):1499–508.10.1056/NEJMoa1900353Google Scholar
20.Stiell, IG, Macle, L. Canadian Cardiovascular Society atrial fibrillation guidelines 2010: management of recent-onset atrial fibrillation and flutter in the emergency department. Can J Cardiol 2011;27(1):3846.Google Scholar
21.Hellman, T, Kiviniemi, T, Nuotio, I, et al. Optimal timing for cardioversion in patients with atrial fibrillation. Clin Cardiol 2018;41(7):966–71.10.1002/clc.22986Google Scholar
22.Garg, A, Khunger, M, Seicean, S, Chung, MK, Tchou, PJ. Incidence of thromboembolic complications within 30 days of electrical cardioversion performed within 48 hours of atrial fibrillation onset. JACC Clin Electrophysiol 2016;2(4):487–94.Google Scholar
23.Hansen, ML, Jepsen, RM, Olesen, JB, et al. Thromboembolic risk in 16,274 atrial fibrillation patients undergoing direct current cardioversion with and without oral anticoagulant therapy. Europace 2015;17(1):1823.10.1093/europace/euu189Google Scholar
24.Sjalander, S, Svensson, PJ, Friberg, L. Atrial fibrillation patients with CHA2DS2-VASc >1 benefit from oral anticoagulation prior to cardioversion. Int J Cardiol 2016;215:360–3.1+benefit+from+oral+anticoagulation+prior+to+cardioversion.+Int+J+Cardiol+2016;215:360–3.>Google Scholar
25.Scheuermeyer, FX, Andolfatto, G, Christenson, J, Villa-Roel, C, Rowe, BH. Electrical vs chemical cardioversion in patients with acute atrial fibrillation: a multicenter parallel group randomized controlled clinical trial. Acad Emerg Med 2019; in press.Google Scholar
26.Stiell, IG, Perry, JJ, Birnie, D, et al. A randomized controlled trial of drug vs electrical cardioversion for recent-onset atrial fibrillation. Acad Emerg Med 2019;26[S1], S22.Google Scholar
27.Neumann, I, Santesso, N, Akl, EA, et al. A guide for health professionals to interpret and use recommendations in guidelines developed with the GRADE approach. J Clin Epidemiol 2016;72:4555.Google Scholar
28.Stiggelbout, AM, Van der Weijden, T, De Wit, MP, et al. Shared decision making: really putting patients at the centre of healthcare. BMJ 2012;344:e256.Google Scholar
29.Djulbegovic, B, Guyatt, GH. Evidence-based practice is not synonymous with delivery of uniform health care. JAMA 2014;312(13):1293–4.Google Scholar