A clinician’s perspective: novel oral anticoagulants to reduce the risk of stroke in nonvalvular atrial fibrillation – full speed ahead or proceed with caution?

Abstract

Over the past few years, three novel oral anticoagulants, dabigatran, rivaroxaban, and apixaban, have been approved in the USA and Europe to reduce the risk of stroke or systemic embolism in patients with nonvalvular atrial fibrillation, and the results of a Phase III trial for a fourth novel oral anticoagulant, edoxaban, have recently been published. The aim of this review is to examine this indication from a clinician’s perspective, highlighting efficacy and safety results from the major trials with these novel oral agents. Clinical issues regarding bleeding, monitoring, and reversal are discussed, along with requirements to consider when interrupting treatment with a novel oral anticoagulant for the purpose of transitioning to another anticoagulant and prior to cardioversion, ablation, percutaneous coronary intervention, or emergency surgery. The cost-effectiveness of each of the approved novel oral anticoagulants is reviewed, and the author provides recommendations for selecting appropriate patients for these agents.

Keywords:

• apixaban
• dabigatran
• rivaroxaban
• edoxaban
• anticoagulant reversal
• anticoagulant monitoring

Introduction

Atrial fibrillation (AF) is the most common sustained cardiac arrhythmia, and if left untreated, increases the risk of stroke by five-fold.^1–3 In 2010, there were an estimated 5.2 million people with AF in the USA, and as the prevalence of AF increases with age, this figure is expected to more than double by 2020, largely as a result of the aging population.^2,3

Oral vitamin K antagonists (VKAs), such as warfarin, have been the mainstay of treatment to reduce the risk of stroke in patients with nonvalvular AF and have been shown to reduce this risk by at least two thirds compared with placebo.⁴ Despite this beneficial effect, VKAs have a narrow therapeutic window and a highly variable dose response attributable to both genetic and clinical factors.⁵ Other elements that influence the anticoagulant effects of VKAs include interactions with prescription and nonprescription drugs and dietary intake of vitamin K.⁵ Consequently, close monitoring of the international normalized ratio (INR) is essential to ensure that patients are within the appropriate therapeutic range to prevent stroke and to avoid an elevated risk of bleeding. However, frequent and lifelong monitoring, which is a major burden to patients and their families, in addition to concerns about bleeding, particularly intracranial hemorrhage, may have led to significant underutilization of VKAs for stroke prevention, especially in the elderly population.

More than five decades after the approval of warfarin, novel oral anticoagulants (NOACs), ie, dabigatran (a direct thrombin inhibitor) and rivaroxaban, apixaban, and edoxaban (factor Xa inhibitors), have been developed. These NOACs have more predictable pharmacokinetic profiles than warfarin, fewer dietary and drug interactions, and no requirement for routine anticoagulant monitoring (Table 1).^6–10 Following rigorous Phase III clinical trials (Table 2),^11–14 dabigatran, rivaroxaban, and apixaban were all approved in Europe and the USA to reduce the risk of stroke or systemic embolism in patients with nonvalvular AF^6–8 after all three showed either similar or increased efficacy for reduction of the risk of stroke or systemic embolism compared with warfarin, and a decreased risk of intracranial hemorrhage (Table 3).^11–15 The results of the Phase III trial for edoxaban have recently been published (Table 3);¹⁶ however, edoxaban is still under consideration for approval. While apixaban was swiftly approved in Europe, the US Food and Drug Administration (FDA) delayed approval twice, citing the need for additional information on data management and verification in the ARISTOTLE (Apixaban for Reduction In Stroke and Other ThromboemboLic Events in atrial fibrillation) trial, particularly with regard to potential errors in dispensing study medication, which could have affected study outcomes.¹⁷ Further investigation confirmed the originally reported results, and the FDA recommended approval of apixaban in December 2012.^17,18

Table 1 Comparison of novel oral anticoagulants

	Dabigatran^Citation6	Rivaroxaban^Citation8	Apixaban^Citation7	Edoxaban^Citation9,Citation10
Mechanism of action Cmax, h Half-life, h	Direct thrombin inhibitor 1a 12–17	Factor Xa inhibitor 2–4b 5–9	Factor Xa inhibitor 3–4 8–15	Factor Xa inhibitor 1–2 5.8–10.7, single dose; 8.75–10.4, multiple dose
Renal excretion	Up to 80%	66%	~25%	35–39
Drug interactions
P-gp and CYP3A4	Avoid coadministration with P-gp inducers (eg, rifampin). Decrease dose if coadministered with P-gp inhibitors dronedarone and systemic ketoconazole in patients with CrCl 30–50 mL/min Do not use concurrently with P-gp inhibitors in patients with CrCl <30 mL/min	Avoid concomitant use with combined P-gp and strong CYP3A4 inducers or inhibitors	Avoid coadministration with strong dual inducers of CYP3A4 and P-gp. Decrease dose if used concurrently with strong dual inhibitors of CYP3A4 and P-gp (2.5 mg bid)c	Edoxaban dosage reduction may be needed when coadministered with strong P-gp inhibitors (eg, verapamil, quinidine, amiodarone, and dronedarone). Interactions have been shown with CYP3A4
Concomitant drugs affecting hemostasis	NSAIDs, antiplatelet agents, heparin, fibrinolytic therapy	Aspirin, platelet aggregation inhibitors, other antithrombotic agents, NSAIDs	NSAIDs used chronically, platelet aggregation inhibitors, or other antithrombotic agents, SSRIs, or SNRIs	Data not available
Approved dosage(s)	150 mg bid (US/Europe) 110 mg bid (Europe) 75 mg bid (US)	20 mg daily with evening meal 15 mg daily with evening meal	5 mg bid 2.5 mg bid	Not currently approved (under review)

Notes:

a Postdose in the fasted state

b coadministration with food increases bioavailability of 20 mg dose (increasing mean AUC and C_max by 39% and 76%, respectively)

c avoid concomitant use with strong dual inhibitors of CYP3A4 and P-gp in patients already taking a reduced dose of apixaban.

Abbreviations: AUC, area under concentration-time curve; bid, twice daily; C_max, maximum plasma concentration; CrCl, creatinine clearance; CYP3A4, cytochrome P450 3A4; NSAIDs, nonsteroidal anti-inflammatory drugs; P-gp, P-glycoprotein; SNRI, serotonin-norepinephrine reuptake inhibitor; SSRI, selective serotonin reuptake inhibitor.

Table 2 Comparison of novel oral anticoagulant trials

	Dabigatran^Citation11	Rivaroxaban^Citation14	Apixaban^Citation12,Citation13	Edoxaban^Citation16
Key clinical trial(s)	RE-LY	ROCKET-AF	AVERROES, ARISTOTLE	ENGAGE-AF TIMI-48
Trial design	Randomized, double-blind, prospective, open-label (PROBE)	Randomized, prospective double-blind, double-dummy	Randomized, prospective double-blind, double-dummy	Randomized, prospective, double-blind, double-dummy
Primary efficacy endpoint	Stroke or SE	Stroke or SE	Stroke or SE	Stroke or SE
Primary safety endpoint	Major bleeding (ISTH)	Major (ISTH)/CRNM bleeding	Major bleeding (AVERROES,a ARISTOTLEa)	Major bleeding (ISTH)
Trial dose	150 mg bid or 110 mg bid	20 mg/d	5 mg bid	60 mg/d 30 mg/d
Reduced dose for selected patients	NA	15 mg/d (CrCl 30–49 mL/min)	2.5 mg bidb	Dose halved in selected patientsc
Mean CHADS2 score	2.1	3.5	2.1	Not stated
Mean TTR, %	64	55	62.2	64.9

Notes:

a Defined according to ISTH criteria, adjusted for the decrease in hemoglobin level if a blood transfusion is required

b reduced dose if patients met two of the following: age ≥80 years, body weight ≤60 kg, or serum creatinine level ≥1.5 mg/day

c for patients in either group the dose was halved if any of the following symptoms were present at the time of randomization or at any point during the study: estimated creatinine clearance 30–50 mL/min, body weight ≤60 kg, or the concomitant use of verapamil or quinidine (potent P-glycoprotein inhibitors). A protocol amendment mandated similar dose modification in the case of concomitant dronedarone use.

Abbreviations: CHADS₂, Congestive heart failure, Hypertension, Age ≥75 years, Diabetes, Stroke (doubled); CrCl, creatinine clearance; CRNM, clinically relevant nonmajor; ISTH, International Society on Thrombosis and Haemostasis; NA, not applicable; SE, systemic embolism; TTR, time in therapeutic range; ARISTOTLE, Apixaban for Reduction In Stroke and Other ThromboemboLic Events in atrial fibrillation; AVERROES, Apixaban Versus Acetylsalicylic acid (ASA) to Prevent Strokes; RE-LY, Randomized Evaluation of Long-Term Anticoagulation Therapy; ROCKET-AF, Rivaroxaban versus Warfarin in Nonvalvular Atrial Fibrillation; ENGAGE-AF TIMI-48, Edoxaban versus Warfarin in Patients with Atrial Fibrillation; bid, twice daily.

Table 3 Efficacy and safety outcomes in Phase III trials of novel oral anticoagulantsa

	Stroke or SE (%/y)	Major bleeding (%/y)	ICH (%/y)	GI bleeding (%/y)	Mortality (%/y)
RE-LY^Citation11,Citation15
Dabigatran 150 mg bid	1.11	3.32	0.30	1.51	3.64
Dabigatran 110 mg bid	1.54	2.87	0.23	1.12	3.75
Warfarin	1.71	3.57	0.74	1.02	4.13
RR (95% CI): dabigatran 150 mg vs warfarin	0.65 (0.52–0.81); P<0.001	0.93 (0.81–1.07); P=0.31	0.40 (0.27–0.60); P<0.001	1.50 (1.19–1.89); P<0.001	0.88 (0.77–1.00); P=0.051
RR (95% CI): dabigatran 110 mg bid vs warfarin	0.90 (0.74–1.10); P=0.30	0.80 (0.70–0.93); P=0.003	0.31 (0.20–0.47); P<0.001	1.10 (0.86–1.41); P=0.43	0.91 (0.80–1.03); P=0.13
ROCKET-AF^Citation14
Rivaroxaban	2.1	3.6	0.5	3.2	4.5
Warfarin	2.4	3.4	0.7	2.2	4.9
HR (95% CI)	0.88 (0.75–1.03); P<0.001 (noninferiority); P=0.12	1.04 (0.90–1.20); P=0.58	0.67 (0.47–0.93); P=0.02	P<0.001b	0.92 (0.82–1.03); P=0.15
ARISTOTLE^Citation13
Apixaban	1.27	2.13	0.33	0.76	3.52
Warfarin	1.60	3.09	0.80	0.86	3.94
HR (95% CI)	0.79 (0.66–0.95); P<0.01	0.69 (0.60–0.80); P<0.001	0.42 (0.30–0.58); P<0.001	0.89 (0.70–1.15); P=0.37	0.89 (0.80–0.99); P=0.047
AVERROES^Citation12
Apixaban	1.6	1.4	0.4	0.4	3.5
Aspirin	3.7	1.2	0.4	0.4	4.4
HR (95% CI)	0.45 (0.32–0.62); P<0.001	1.13 (0.74–1.75); P=0.57	0.85 (0.38–1.90); P=0.69	0.86 (0.40–1.86); P=0.71	0.79 (0.62–1.02); P=0.07
ENGAGE AF TIMI-48^Citation16
Edoxaban 60 mg	1.57	2.75	0.39	1.51	3.99
Edoxaban 30 mg	2.04	1.61	0.26	0.82	3.80
Warfarin	1.80	3.43	0.85	1.23	4.35
HR (95% CI): high dose vs warfarin	mITT:c 0.79 (0.63–0.99); P<0.001 (noninferiority) ITT:d 0.87 (0.73–1.04); P=0.08	0.80 (0.71–0.91) P<0.001	0.47 (0.34–0.63) P<0.001	1.23 (1.02–1.50) P=0.03	0.92 (0.83–1.01) P=0.08
HR (95% CI): low dose vs warfarin	mITT:c 1.07 (0.87–1.31); P=0.005 (noninferiority) ITT:d 1.13 (0.96–0.34); P=0.10	0.47 (0.41–0.55) P<0.001	0.30 (0.21–0.43) P<0.001	0.67 (0.53–0.83) P<0.001	0.87 (0.79–0.96) P=0.006

Notes:

a All P values are for superiority, unless otherwise stated

b HR was not provided for the outcome of GI bleeding

c included data from patients who underwent randomization and received at least one dose of study drug during the treatment period (from administration of first dose to either 3 days after receipt of last dose or end of double-blind therapy, whichever came first, with interval censoring of events during study drug interruptions that lasted more than 3 days)

d included all primary endpoints during the overall study period from randomization until the end of double-blind treatment.

Abbreviations: CI, confidence interval; GI, gastrointestinal; HR, hazard ratio; ICH, intracranial hemorrhage; ITT, intent-to-treat; mITT, modified intent-to-treat; RR, relative risk; SE, systemic embolism; vs, versus; ARISTOTLE, Apixaban for Reduction In Stroke and Other ThromboemboLic Events in atrial fibrillation; AVERROES, Apixaban Versus Acetylsalicylic acid (ASA) to Prevent Strokes; RE-LY, Randomized Evaluation of Long-Term Anticoagulation Therapy; ROCKET-AF, Rivaroxaban versus Warfarin in Nonvalvular Atrial Fibrillation; ENGAGE-AF TIMI-48, Edoxaban versus Warfarin in Patients with Atrial Fibrillation; bid, twice daily.

The benefits of the NOACs over warfarin have been partially offset by a lack of reversal agents and an inability to precisely monitor their anticoagulant effects. The purpose of this review is to examine the role of NOACs in reducing the risk of stroke in patients with nonvalvular AF from a clinician’s perspective, highlighting results from the major trials and discussing important issues related to their use in clinical practice.

Efficacy and safety of NOACs in Phase III trials

Dabigatran

The efficacy and safety of the direct thrombin inhibitor, dabigatran (150 mg twice daily and 110 mg twice daily) were investigated in the RE-LY (Randomized Evaluation of Long-Term Anticoagulation Therapy) trial (Table 3), the design of which is shown in Table 2.¹¹ The approved dosages of dabigatran vary between markets; the FDA-approved dose is 150 mg (75 mg in patients with severe renal impairment),⁷ while both the 150 mg and 110 mg doses are approved in Europe.¹⁹ Dabigatran 150 mg twice daily was superior to warfarin (P<0.001) for reduction of the risk of stroke or systemic embolism, with a similar risk of major bleeding between groups (P=0.31). The dabigatran 110 mg twice daily dosage was noninferior to warfarin in reducing the risk of stroke or systemic embolism (P<0.001), with a significantly lower risk of major bleeding (P=0.003). The risk of ischemic stroke was significantly lower with dabigatran 150 mg than with warfarin (relative risk 0.76, 95% confidence interval [CI] 0.60–0.98; P=0.03), but was similar in both groups when dabigatran 110 mg was compared with warfarin (relative risk 1.11, 95% CI 0.89–1.40; P=0.35). Compared with warfarin, the risk of intracranial hemorrhage was lower (P<0.001) for both dabigatran doses. The risk of gastrointestinal bleeding was higher with dabigatran 150 mg twice daily than with warfarin (P<0.001), but was similar in the dabigatran 110 mg twice daily and warfarin groups (P=0.43). There was a nonsignificant trend toward reduced risk of mortality with dabigatran 150 mg versus warfarin (P=0.051); however, this trend did not occur with the dabigatran 110 mg twice daily dosage (P=0.13). The only adverse event significantly more common with dabigatran than with warfarin was dyspepsia (11.8%, 11.3%, and 5.8% for the dabigatran 110 mg, 150 mg, and warfarin groups, respectively).¹¹ The risk of myocardial infarction (MI) was higher with dabigatran than with warfarin, but was not statistically significant for either comparison (P=0.09 and P=0.12, respectively, for the 110 mg and 150 mg twice daily dosages).¹⁵ A meta-analysis of seven dabigatran trials across indications also found a nonsignificant increase in the risk of MI or acute coronary syndrome (27% higher in dabigatran-treated patients; P=0.05).²⁰ Another analysis of the RE-LY data found no statistically significant differences in event rates with either dabigatran dosage versus warfarin when using aggregated cardiac events (eg, MI as well as unstable angina, percutaneous coronary intervention, and cardiac arrest).²¹

Rivaroxaban

The efficacy and safety of the factor Xa inhibitor rivaroxaban were investigated in ROCKET-AF (Rivaroxaban Once Daily Oral Direct Factor Xa Inhibition Compared with Vitamin K Antagonism for Prevention of Stroke and Embolism Trial in Atrial Fibrillation; Table 3).¹⁴ The trial design is shown in Table 2. Patients who were enrolled in ROCKET-AF were at a higher risk of stroke than those in RE-LY or ARISTOTLE (CHADS₂ [Congestive heart failure, Hypertension, Age ≥75 years, Diabetes mellitus, prior Stroke, transient ischemic attack, or central nervous system thromboembolism {doubled}]; score 3.5 versus 2.1 in RE-LY and ARISTOTLE). A once-daily dose of rivaroxaban (20 mg) was used, with a dose reduction (15 mg) in patients with a creatinine clearance of 30–49 mL per minute. Rivaroxaban was noninferior to warfarin (P<0.001) for reduction in the risk of stroke or systemic embolism in the intent-to-treat population; however, superiority was not shown (P=0.12). The risk of major bleeding was similar in rivaroxaban-treated and warfarin-treated patients (P=0.58). The risk of intracranial hemorrhage was significantly lower with rivaroxaban, but the risk of gastrointestinal bleeding was significantly higher (P=0.02 and P<0.001, respectively). The risks of mortality and MI were not significantly different between groups (P=0.15 and P=0.12, respectively).

Apixaban

The efficacy and safety of the factor Xa inhibitor apixaban were investigated in the AVERROES (Apixaban Versus Acetylsalicylic acid [ASA] to Prevent Strokes) and ARISTOTLE trials (Table 3).^12,13 The trial designs are shown in Table 2. In both Phase III trials for apixaban (5 mg twice daily), a reduced dose of 2.5 mg (twice daily) was used if patients met two of the following criteria: age ≥80 years, body weight ≤60 kg, or serum creatinine level ≥1.5 mg/dL. It should be noted that only a limited number of patients received the lower apixaban dose (AVERROES, 6.0%; ARISTOTLE, 4.7%).^12,13 In AVERROES, the risk of stroke or systemic embolism was significantly lower in the apixaban group than in the aspirin group (P<0.001 for superiority); however, the risk of major bleeding was comparable in the two groups (P=0.57).¹² A trend toward lower risk of mortality was observed with apixaban (P=0.07), and the risks of intracranial hemorrhage and gastrointestinal bleeding were similar between groups (P=0.69 and P=0.71, respectively). In ARISTOTLE, the risk of stroke or systemic embolism was significantly lower with apixaban than with warfarin (P<0.01 for superiority), and this reduction was primarily driven by a reduction in the risk of hemorrhagic stroke (hazard ratio [HR] 0.51, 95% CI 0.35–0.75; P<0.001). The risks of major bleeding (P<0.001), intracranial hemorrhage (P<0.001), and mortality (P=0.047) were significantly decreased with apixaban compared with warfarin.¹³ In AVERROES and ARISTOTLE, the risks of gastrointestinal bleeding (P=0.71 and P=0.37, respectively) and MI (P=0.37 and P=0.59, respectively) were similar with apixaban versus the two comparators.^12,13

Edoxaban

The efficacy and safety of the factor Xa inhibitor edoxaban (60 mg and 30 mg once daily) were investigated in the ENGAGE AF-TIMI 48 trial (Edoxaban versus Warfarin in Patients with Atrial Fibrillation); Table 3).¹⁶ The trial design is shown in Table 2. The edoxaban dose was halved (30 mg and 15 mg once daily) if any of the following conditions were present at the time of randomization or at any point during the study: estimated creatinine clearance 30–50 mL per minute, body weight ≤60 kg, or concomitant use of verapamil or quinidine (potent P-glycoprotein inhibitors). A protocol amendment mandated similar dose modification in the event of concomitant dronedarone use. Both doses (60 mg and 30 mg) were found to be noninferior to warfarin for reduction in the risk of stroke or systemic embolism (modified intent-to-treat population, P<0.001 and P=0.005 for noninferiority, respectively; intent-to-treat population, P=0.08 and P=0.10 for superiority, respectively) and were associated with significantly lower risks of major bleeding (P<0.001 and P<0.001).¹⁶ The risk of all-cause mortality was significantly reduced with edoxaban 30 mg versus warfarin (P=0.006) but was similar in the edoxaban 60 mg and warfarin groups (P=0.08).¹⁶ The risk of major gastrointestinal bleeding was significantly higher with edoxaban 60 mg than with warfarin (P=0.03), but was lower with edoxaban 30 mg (P<0.001 versus warfarin). Edoxaban is not discussed further in this review, because neither dose has yet been approved by the FDA or European agencies.

Clinical issues

Although the RE-LY, ROCKET-AF, and ARISTOTLE studies investigated similar outcomes, only head-to-head comparisons can determine the relative safety of each of these NOACs versus the others. Whereas all treatment arms within a trial are equally affected, one should consider differences in trial design (Table 2), such as baseline CHADS₂ scores and study drug blinding, before making indirect comparisons between NOACs. Nevertheless, understanding clinical issues, such as bleeding, monitoring, and reversal, may help clinicians select the appropriate treatment to reduce the risk of stroke or systemic embolism in patients with nonvalvular AF. A practical guide for how to manage NOACs in specific clinical situations has been developed by the European Heart Rhythm Association (EHRA).²²

Bleeding

Real-world experience and postmarketing data are providing additional insights into the use of NOACs in patients with nonvalvular AF. Since its approval in late 2010, reports have associated dabigatran with serious adverse events, particularly bleeding, most commonly in patients with low body weight, advanced age, or impaired renal function.^23–25 The information from these reports is consistent with data from a RE-LY subanalysis that identified older age (≥75 years) and poor renal function as key predictors of bleeding events with dabigatran treatment.²⁶ Subsequent investigations by the FDA and the European Medicines Agency’s Committee for Medicinal Products for Human Use concluded that the bleeding risks were consistent with the bleeding rates reported in RE-LY,^27,28 and the dabigatran prescribing information recommends assessing patient renal function before beginning treatment and as clinically indicated thereafter.⁶ Furthermore, the FDA concluded in a Mini-Sentinel pilot analysis that observed bleeding rates associated with new use of dabigatran were lower than bleeding rates associated with new use of warfarin.²⁸ A larger study was conducted by the FDA to assess the efficacy and safety of dabigatran versus warfarin in 134,000 Medicare patients, aged 65 years or older, who had received a diagnosis of nonvalvular AF within the 6 months prior to the first dispensing of medication.²⁹ The results showed that dabigatran (combined data for 150 mg and 75 mg dosages) was associated with a lower risk of ischemic stroke (adjusted HR 0.80, 95% CI 0.67–0.96), intracranial hemorrhage (HR 0.34, 95% CI 0.26–0.46), and death (HR 0.86, 95% CI 0.77–0.96) compared with warfarin. An increased risk of major gastrointestinal bleeding (HR 1.28, 95% CI 1.14–1.44) was observed; however, the risk of MI was similar between the treatment groups.²⁹ A real-world, nationwide cohort study was conducted in Denmark that assessed the use of dabigatran (post-approval) in anticoagulant-naive patients with AF.³⁰ In the 14,267 patients identified through registry data, the mean age was 70.8 years, 56.5% were male, the mean CHADS₂ score was 1.16, and the median follow-up was 10.5 months.³⁰ The investigators found that there were similar risks of stroke or systemic embolism and major bleeding with both doses (150 mg and 110 mg) of dabigatran and with warfarin, and that the risks of mortality, intracranial hemorrhage, pulmonary embolism, and MI were all lower in dabigatran-treated patients.³⁰ An additional real-world study from a single hospital in Hong Kong was conducted to compare dabigatran with warfarin (matched by age, sex, and treatment duration) in patients with AF.³¹ The mean age of the 244 patients recruited was 70.1 years, 54.1% were male, their mean CHADS₂ score was 2.4, and the median treatment duration was 310 days.³¹ The investigators found that the risks of stroke and bleeding (any degree) were similar in dabigatran-treated and warfarin-treated patients.³¹ The investigators also found that there was no significant difference in treatment compliance rates between the two groups.³¹

Real-world data on bleeding with rivaroxaban and apixaban are limited, as these therapies have been available for less time than dabigatran, but trial subanalyses are available. In ROCKET-AF, predictors of major bleeding with rivaroxaban included older age, male sex, increased body mass index, diabetes, chronic obstructive lung disease, and worsening renal function.³² Risks of major adverse outcomes, including death following a major bleeding event, were similar in patients treated with rivaroxaban and warfarin in ROCKET-AF.³³ Additionally, rivaroxaban was associated with a lower risk of intracranial hemorrhage.³³ A subgroup analysis of ARISTOTLE found a lower risk of bleeding in all age categories for apixaban-treated versus warfarin-treated patients, including those aged ≥75 years.¹³ In addition to observing a reduced risk of stroke or systemic embolism regardless of renal function, another analysis from ARISTOTLE found a greater reduction in the relative risk of major bleeding in the apixaban arm versus warfarin arm with worsening renal impairment (creatinine clearance <50 mL per minute).³⁴ When considering these data, it is important to note that patients with a creatinine clearance <30 mL per minute (RE-LY and ROCKET-AF) or <25 mL per minute (ARISTOTLE) were excluded from the trials; NOACs should not be used in patients with creatinine clearance <15 mL per minute, as there are limited clinical outcomes data to inform on the use of NOACs in such patients.^6–8 A separate analysis of the ARISTOTLE trial found that, compared with warfarin, apixaban was associated with a 31% reduction in risk of a first major bleeding event, and was associated with fewer intracranial hemorrhages.³⁵ Additionally, apixaban was associated with fewer adverse consequences following extracranial hemorrhages, fewer trauma-associated hemorrhages, and a 50% reduction in fatal events at 30 days in the case of a major hemorrhage.³⁵ The EHRA guide states that current recommendations on bleeding management are not so much based on clinical experience as expert opinion on laboratory endpoints.²² For bleeding that is not life-threatening, the guide suggests that time is the most important reversal strategy for the anticoagulant effects of NOACs because of their short half-lives (Table 1); however, standard supportive measures should also be used, including mechanical compression, surgical hemostasis, fluid replacement, and other hemodynamic support. Data to support how to treat life-threatening bleeding are limited,²² and are discussed in more detail in the next two sections.

Monitoring anticoagulant effects

Due to its narrow therapeutic window, patients taking warfarin require regular monitoring to maintain therapeutic levels (INR 2.0–3.0).⁵ Equivalent monitoring is not required with NOAC treatment and INR is not an effective option for monitoring anticoagulation in NOAC-treated patients. Patients most likely to require anticoagulation for nonvalvular AF are older and have more comorbidities, and therefore may interact with a variety of health care providers. Many of these providers may be unfamiliar with NOACs and assume that INR testing can be done for these agents.

A number of treatment-specific methods for monitoring NOAC treatment are under investigation (Table 4), but they are generally not ready for clinical use and data are limited to a few small studies.^36–42 These tests differ from those used for warfarin because of their target-specific mechanisms of action (Figure 1). Additionally, for NOACs, the direct anticoagulant activity, rapid onset/offset of anticoagulant effects, and relatively short half-lives make it critically important to know the timing of the last drug dose when evaluating test results.

Figure 1 Sites of action for monitoring assays in the coagulation pathway.

Abbreviations: aPTT, activated partial thromboplastin time; dTT, diluted thrombin time; ECT, ecarin clotting time; mPT, modified prothrombin time; PT, prothrombin time; TT, thrombin time.

Table 4 Anticoagulant monitoring assays

	Description	Dabigatran^Citation38,Citation40,Citation41	Rivaroxaban^Citation36,Citation37,Citation39	Apixaban^Citation7,Citation36,Citation42,Citation44
Anti-factor Xa	Measures factor X activation directly using a chromogenic substrate	NA	Quantitative	Quantitative
Activated partial thromboplastin time (aPTT)	Test for the intrinsic system; measures kininogen, prekallikrein, XII, XI, IX, VIII, X, V, and thrombin	Qualitative	Not useful	Not useful
Prothrombin time (PT)	Test of the extrinsic pathway, provides an overview of VII, X, V, thrombin, and fibrinogen	Not useful	Qualitative	Not useful
Thrombin time (TT)	Functional test of fibrinogen concentration and fibrin formation	Qualitative assessment, but values may be abnormally high even at clinically insignificant levels	Not useful	Not useful
Diluted TTa	Uses the Hemoclot Thrombin Inhibitor assay (Hyphen BioMed, Neuville-sur-Oise, France)^Citation40	Quantitative analysis	Not useful	Not useful
Modified PTa	Modification of PT assay by adding calcium chloride to the thromboplastin reagent to increase assay dynamic range and improve sensitivity^Citation42	NA	NA	More sensitive than PT and aPTT^Citation41
Ecarin clotting timea	Specific assay for thrombin generation	Quantitative	NA	NA
Heptest^®a (American Diagnostica, Stamford, CT, USA)	Quantitative heparin clotting test	NA	Prolonged	More sensitive than PT and aPTT^Citation42

Note:

a Not widely available.

Abbreviations: NA, data not available; aPTT, activated partial thromboplastin time; PT, prothrombin time; TT, thrombin time.

Dabigatran

A close linear relationship has been shown between prolongation of ecarin clotting time and plasma concentrations of dabigatran.^38,43 Ecarin clotting time is the most sensitive assay for determining the anticoagulant effect of dabigatran; however, it is not widely available. Prothrombin time is widely available, but unsuitable as a primary measure of anticoagulant activity.⁴¹ Measurement of activated partial thromboplastin time (aPTT) at trough levels of dabigatran may be useful for identifying an excess anticoagulant effect but not for precise quantification.^6,41 The thrombin time assay is useful in detecting very low dabigatran plasma levels, and the diluted thrombin time assay can identify therapeutic and supratherapeutic levels.^40,43 The dabigatran prescribing information suggests use of aPTT or ecarin clotting time, but not INR, to assess the anticoagulant activity of dabigatran.⁶

Rivaroxaban

The prothrombin time, aPTT, Heptest^® (American Diagnostica, Stamford, CT, USA), and anti-factor Xa assays are all prolonged by rivaroxaban.⁸ Rivaroxaban and other factor Xa inhibitors affect INR measurements, and if treatment with rivaroxaban and warfarin overlap, prothrombin time is not useful for assessing the extent of anticoagulation. The Heptest, which measures inhibition of exogenous factor Xa, may then be a good alternative. The prothrombinase-induced clotting time can also be used, but is not commercially available and offers limited results. The anti-factor Xa assay is the most sensitive and reliable method for assessing the anticoagulant effect of rivaroxaban, and kits with rivaroxaban calibrators and controls are now commercially available.^44,45

Apixaban

In human plasma, the anticoagulant effect of apixaban on prothrombin time varies significantly depending on the thromboplastin reagent used, and therefore prothrombin time is not useful for monitoring.⁷ It may, however, have clinical utility in an emergency situation to provide a qualitative assessment of whether there is any anticoagulant effect remaining. Like other factor Xa inhibitors, apixaban affects INR results, thus these measurements may not be useful for determining the extent of anticoagulation when warfarin is coadministered with apixaban.⁷ Although not widely available, the modified prothrombin time and Heptest are more sensitive than prothrombin time and aPTT.⁴² The widely available Rotachrom^® heparin chromogenic anti-factor Xa assay (Diagnostica Stago Inc., Parsippany, NJ, USA) appears to be the most sensitive method for measuring apixaban concentrations.^44,46

Reversal of anticoagulation

Reversal agents such as protamine, fresh frozen plasma, and 3-factor and 4-factor prothrombin complex concentrate have successfully reversed the anticoagulant effects of heparin derivatives and warfarin.^5,47 There is no drug-specific antidote to rapidly reverse the drug effect of NOACs or induce hemostasis. Therefore, reduction of drug exposure mostly relies on the short half-lives of these agents (5–17 hours, Table 1), which culminate in rapid reductions of their anticoagulant effects compared with warfarin.^6–8

Dabigatran is dialyzable due to its relatively low (~60% of drug over 2–3 hours) plasma protein binding,⁶ although data for this treatment approach are limited. The majority of rivaroxaban and apixaban (92%–95% and 87%, respectively) is protein-bound in plasma, so dialysis is not a viable option to reverse anticoagulation.^7,8

Fresh frozen plasma may reverse the anticoagulant effects of dabigatran, rivaroxaban, and apixaban, but has shown limited effectiveness in reducing dabigatran-associated intracerebral hematoma in a murine intracranial hemorrhage model.⁴⁸ Activated charcoal has reduced absorption when administered within 8 hours of rivaroxaban or within 6 hours of apixaban ingestion.^49,50 Prothrombin complex concentrates have been suggested as possible therapies to reverse NOAC anticoagulation. In healthy volunteers, nonactivated prothrombin complex concentrates normalized coagulation test results in patients taking rivaroxaban but not in patients taking dabigatran.⁵¹ However, activated prothrombin complex concentrate reduced bleeding times in dabigatran-treated rats.⁴¹

A study of healthy volunteers (n=10) exposed to rivaroxaban and dabigatran found equivocal results for prothrombin complex concentrates, recombinant factor VIIa (rFVIIa), and FEIBA^® (anti-inhibitor coagulant complex, Baxter Healthcare Corporation, Deerfield, IL, USA).⁵² A recent in vitro investigation found variable effectiveness of prothrombin complex concentrate, activated prothrombin complex concentrate, and rFVIIa in reversing alterations of hemostatic mechanisms induced by apixaban.⁵³ Efficacy was greatest for rFVIIa and prothrombin complex concentrate, depending on the outcome measured. A Phase II proof-of-concept study has shown that the novel recombinant protein PRT064445 produces rapid, sustained, dose-related reversal of the anticoagulant effects of both apixaban and rivaroxaban.^54,55

Permanent discontinuation of NOACs

Some patients will require permanent discontinuation of a NOAC and will transition back to warfarin, and as with transitions from warfarin to a NOAC, adequate anticoagulation must be maintained. The FDA has issued boxed warnings for the three approved NOACs regarding the increased risk of thrombotic events following discontinuation of treatment, and recommends considering another anticoagulant when cessation of treatment is unrelated to pathological bleeding.^6–8 This warning ensued from the observation of increased frequency of thrombotic events following discontinuation of rivaroxaban and apixaban at the end of the ROCKET-AF and ARISTOTLE trials, respectively; however, additional analyses are needed to improve current understanding of these findings.^14,56–59 No clinical trial data are available on the conversion of patients from NOACs to warfarin, and it is not yet known which patients are at highest risk for thrombotic events following discontinuation of treatment. A suggested approach is to discontinue NOAC treatment and begin a parenteral anticoagulant and warfarin at the time the next dose would have been taken, discontinuing the parenteral anticoagulant when the INR is within the therapeutic range.^6–8 The American College of Chest Physicians guidelines define the risk of thromboembolism as high for patients with a CHADS₂ score of 5 or 6, a recent (<3 months) stroke or transient ischemic attack, or rheumatic valvular heart disease; moderate for patients with a CHADS₂ score of 3 or 4; and low for patients with a CHADS₂ score of 0 to 2 and no prior stroke or transient ischemic attack. Although no specific data are available for NOACs, this risk stratification scheme could provide guidance when considering which patients should receive bridging therapy.⁶⁰ Additional guidance on switching between specific antithrombotic regimens is provided in the EHRA practical guide.²² Careful patient monitoring is recommended when switching between anticoagulants, as a recent real-world study showed that patients who switched to dabigatran had an increased risk of MI when compared with those who remained on warfarin therapy during the early period after transition.⁶¹

Transition between NOACs

An area of uncertainty in clinical care is the lack of practical guidance on how to transition patients from one NOAC to another. This is driven by the absence of head-to-head trials between NOACs. If patients develop side effects from a NOAC and wish to convert to another one, no published protocols are available to assist practitioners with this process. Since the half-lives of the NOACs are between 5 and17 hours (Table 1), it is reasonable to discontinue NOACs dosed twice daily, such as dabigatran or apixaban, after taking the evening dose and starting the first dose of the new agent the following morning. If taking rivaroxaban once daily, it is sensible to advise patients to take their daily evening dose and start one of the NOACs dosed twice daily the next evening. As real-world experience accumulates with NOACs and conversion between agents becomes more common, guidelines will likely emerge to set standards for this transition.

Temporary interruption of NOACs

Clinical situations such as catheter ablation and emergency surgery may require temporary interruption of anticoagulant treatment. Providers familiar with managing patients on warfarin may have uncertainty when faced with the same situations in patients treated with a NOAC, where limited data are available to guide treatment decisions. The American College of Cardiology guidelines state that in patients with AF (without a mechanical heart valve) who require interruption of warfarin or NOAC treatment, the need for bridging therapy with unfractionated or low-molecular-weight heparin should balance the risks of stroke and bleeding and the duration of time a patient will not be anticoagulated.⁶² The prescribing information for apixaban states that bridging anticoagulation during the 24–48 hours after stopping apixaban and prior to elective surgery or invasive procedures is not generally required and that apixaban should be restarted as soon as adequate hemostasis has been established.⁷ No guidance on whether or not to use bridging therapy has been provided for dabigatran or rivaroxaban.

Catheter ablation

Patients with AF undergoing catheter ablation are generally anticoagulated prior to the procedure. A recent trend has been to continue warfarin uninterrupted through the ablation periprocedural period, but appropriate timing for NOAC discontinuation remains uncertain. Data for NOAC discontinuation prior to ablation are limited. Studies investigating use of NOACs in patients undergoing catheter ablation have been conducted using differing trial designs, which makes it difficult to interpret their conflicting results.^57,63–67 In a multicenter registry of patients (n=290) undergoing radiofrequency ablation for nonvalvular AF, warfarin therapy was not interrupted, whereas dabigatran was held on the morning of the procedure and resumed within 3 hours of hemostasis.⁵⁷ Rates of total and major bleeding were significantly higher in the dabigatran group than in the warfarin group (14% versus 6%, P=0.031, and 6% versus 1%, P=0.019, respectively). Conversely, a single-center study (n=123) in which warfarin was discontinued 5 days before ablation and dabigatran was stopped 36–60 hours before the procedure based on glomerular filtration rate recorded no hemorrhagic or thrombotic events in dabigatran-treated patients.⁶⁷ A prospective observational study of 259 real-world patients with nonvalvular AF undergoing catheter ablation was performed to assess the longer-term safety, efficacy, and acceptance of NOACs.⁶³ Patients were treated for at least 3 months with NOACs post-ablation; 38% received dabigatran 110 mg twice daily, 56% received dabigatran 150 mg twice daily, and 6% received rivaroxaban 20 mg once daily. Of the four periprocedural thromboembolic and major bleeding complications (1.5%), none occurred in patients treated with NOACs prior to ablation, and no stroke, systemic embolism, or major bleeding events occurred during long-term follow-up. Hence, the authors concluded that, in this population, anticoagulation with NOACs following AF catheter ablation was safe and effective at long-term follow-up.⁶³

In addition to these studies, a meta-analysis was conducted to evaluate the efficacy and safety of dabigatran in 5513 patients (dabigatran, n=2137; warfarin, n=3376) undergoing catheter ablation.⁶⁵ The results showed that the risk of stroke or transient ischemic attack (odds ratio 3.94; 95% CI 1.54–10.08) and of all thromboembolic events was higher with dabigatran than with warfarin (odds ratio 2.81; 95% CI 1.23–6.45), with no major differences in risk of major bleeding (odds ratio 0.99; 95% CI 0.55–1.78).⁶⁵

A study evaluating the risk of bleeding and thromboembolic complications associated with NOAC use during ablation compared the use of uninterrupted warfarin (n=114), dabigatran (n=89), and rivaroxaban (n=98).⁶⁶ Dabigatran was held for 24 hours and rivaroxaban for 36 hours prior to the procedure; heparin infusion was initiated 6 hours post-procedure, and NOAC treatment was resumed the morning after the procedure. Two thromboembolic events and 17 bleeding events occurred; however, there was no significant difference between the groups with regard to the combined thromboembolic/bleeding risk (warfarin, 6.2%; dabigatran, 6.7%; rivaroxaban, 6.0%; P=0.82). A further single-center study compared VKAs (n=192), rivaroxaban (n=188), and dabigatran (n=176) in patients undergoing catheter ablation.⁶⁴ In the 30 days following ablation, the rates of thromboembolic events (VKA, 2.1%; dabigatran, 0.6%; rivaroxaban, 1.1%; P=0.410) and major bleeding (VKA, 4.2%; dabigatran, 1.1%; rivaroxaban, 1.6%; P=0.112) were low and comparable between treatments.⁶⁴

Based on the available data, the EHRA guide suggests that to reduce bleeding and catheter ablation complications in patients taking NOACs, a strategy of bridging and restarting anticoagulation may be safe when appropriately executed. They caution, however, that an aggressively shortened periprocedural cessation of NOACs and/or no bridging may be less safe when compared with ablation performed with uninterrupted VKA administration and a therapeutic INR between 2.0 and 3.0.²²

Surgical procedures

Approximately 10% of patients receiving oral anticoagulants require interruption of treatment for surgery or elective invasive procedures.⁶⁰ Standard guidance is to withhold anticoagulant treatment for at least 4–6 half-lives prior to surgery. In addition, the EHRA guide suggests considering the bleeding risk of surgery when deciding how to manage anticoagulation treatment.²² Dabigatran should be discontinued 1–2 days prior to invasive or surgical procedures in patients with creatinine clearance ≥50 mL per minute, or 3–5 days prior in patients with creatinine clearance <50 mL per minute.⁶ Rivaroxaban should be discontinued at least 24 hours prior to surgical or other procedures.⁸ Apixaban should be discontinued at least 48 hours prior to elective surgery or invasive procedures with a moderate-to-high risk of unacceptable or clinically relevant bleeding, and at least 24 hours before similar procedures with a low risk of bleeding or where the bleeding would be noncritical in location and easily controlled.⁷

In a subanalysis of RE-LY, the risks of periprocedural complications, perioperative bleeding, and thrombotic events in patients taking dabigatran were comparable with those in patients taking warfarin, even among patients having major or urgent surgery. Furthermore, dabigatran facilitated a shorter interruption of anticoagulation than warfarin.⁶⁸ In ROCKET-AF, temporary discontinuation of rivaroxaban was equivalent to warfarin in terms of stroke risk, but this analysis did not evaluate differences in perioperative bleeding or thrombotic risks related to invasive procedures (eg, major surgery).⁵⁸ In ARISTOTLE, rates of stroke and major bleeding during the 30 days following procedures were low and comparable in warfarin-treated and apixaban-treated patients.⁶⁹

Other clinical scenarios

Cardioversion

The European Society of Cardiology guidelines suggest that patients with an AF duration >48 hours who undergo elective cardioversion should receive anticoagulation for at least 3 weeks prior to the procedure, or transesophageal echocardiography should be performed to rule out left atrial thrombus if anticoagulant treatment is less than the mandatory 3 weeks.¹ After cardioversion, anticoagulation should be continued for at least 4 weeks. Cardioversion protocols for patients taking NOACs are lacking. Currently, information is limited to the protocols and results from the major NOAC trials. Patients in RE-LY continued the study drug prior to cardioversion, unless the investigator deemed another approach was necessary. To exclude the presence of left atrial thrombus, a transesophageal echocardiogram was recommended if cardioversion was planned within 60 days of randomization.⁷⁰ The ROCKET-AF protocol excluded patients scheduled to have a cardioversion, and few patients underwent the procedure in that trial.¹⁴ In ARISTOTLE, patients received blinded oral anticoagulation within therapeutic INR ranges for at least 3 weeks prior to elective cardioversion, and transesophageal echocardiography was used to evaluate patients at higher risk of left atrial appendage thrombus.¹³

Trial subanalyses suggest that such approaches were sufficient. A post hoc analysis of patients who had undergone cardioversion in RE-LY found no significant differences between dabigatran and warfarin for the risk of stroke or systemic embolism or the risk of major bleeding within 30 days of the procedure.⁷¹ A ROCKET-AF subanalysis that adjusted for baseline differences showed that the long-term risks of stroke or systemic embolism, cardiovascular death, and all-cause mortality were similar before and after cardioversion or AF ablation in rivaroxaban-treated and warfarin-treated patients.⁵⁹ Finally, an ARISTOTLE subanalysis found very low rates of major clinical events (stroke, systemic embolism, MI, major bleeding) during the first 90 days after cardioversion, and results were similar in apixaban-treated and warfarin-treated patients.⁷²

The EHRA guide suggests that, as no anticoagulation assay is available for the NOACs to provide information on anticoagulation over the 3 weeks prior to cardioversion, clinicians should explicitly ask patients about adherence over the weeks prior to procedures and document their answers.²² If doubts arise regarding patient compliance, then transesophageal echocardiography should be considered prior to cardioversion.

Percutaneous coronary intervention

Possibly the most challenging situation for cardiologists is how to use NOACs in clinical conditions where coadministration of antiplatelet therapy is required (ie, dual or triple therapy), especially after percutaneous coronary intervention. The 2014 American College of Cardiology/American Heart Association/Heart Rhythm Society guidelines recommend that bare metal stents may be considered in patients with AF undergoing percutaneous coronary intervention to minimize the required duration of dual antiplatelet therapy, and that anticoagulation may be interrupted at the time of the procedure to reduce the risk of bleeding at the site of peripheral arterial puncture.⁶²

In a subanalysis of RE-LY, patients on dual antiplatelet therapy and dabigatran had a 43% higher risk of major bleeding than patients not taking any antiplatelet therapies.²⁶ Since the RE-LY trial results were published, new antiplatelet therapies have emerged, including ticagrelor and prasugrel; however, the impact of these agents on increased bleeding risk in patients concurrently taking dabigatran is unknown. In general, for patients requiring dual antiplatelet therapy, exposure to triple therapy should be limited when possible by encouraging the use of bare metal stents in appropriate patients. Notably, the prescribing information for the NOACs warn of an increased risk of bleeding when they are used with antiplatelet therapies.^6–8 With greater use of NOACs in clinical practice, studies will address these issues and provide guidance about appropriate use of NOACs in select populations. Reducing the time patients are exposed to either dual or triple therapy should be a key consideration for clinicians when selecting from among the different antithrombotic agents.²²

Patient selection

It is critical to select appropriate patients for treatment with NOACs to reduce the risk of adverse events. A thorough patient history is imperative, including a review of prior bleeding episodes from any source. Reconciliation of all prescription and nonprescription medications and a current assessment of kidney function are essential to avoiding concomitant drug interactions (Table 1). These steps will help identify which patients are candidates for NOACs and reduce the risk of major adverse events, particularly bleeding complications.

Whether a patient with a stable INR should transition to NOAC treatment is an evolving clinical question, and decisions related to patient selection are probably least relevant for patients who are on steady doses of a VKA without wide fluctuations in their INR. A center-based subanalysis of RE-LY found that when warfarin-treated patients had a time-in-therapeutic range of >65.5%, dabigatran was no longer superior in terms of risk of stroke or systemic embolism.⁷³ Rivaroxaban was not superior to warfarin for the prevention of stroke or systemic embolism; however, the treatment effect of rivaroxaban compared with warfarin was consistent across center-based time-in-therapeutic range quartiles.¹⁴ An analysis using predicted center-based and individual time-in-therapeutic ranges found that, regardless of the quality of INR control, apixaban offered a benefit versus warfarin with respect to risk of stroke or systemic embolism, bleeding, and mortality.⁷⁴ Some argue that warfarin is associated with a much higher risk of intracranial hemorrhage, which justifies switching such patients to one of the NOACs, and although this is a valid point, the overall risk of intracranial hemorrhage is relatively low (Table 3).^11–15 Others contend that even well controlled, younger warfarin-treated patients should be switched to a NOAC because of the substantially reduced risk of devastating intracranial hemorrhage.

The 2014 guidelines from the American College of Cardiology/American Heart Association recommend that in patients with AF, antithrombotic therapy should be individualized based on shared decision-making after discussion about the absolute and relative risks of stroke and bleeding and the patient’s values and preferences.⁶² A focused 2012 update of the European Society of Cardiology guidelines for management of AF states that the approved NOACs are broadly preferable to VKAs in the majority of patients with nonvalvular AF when used as studied in clinical trials.⁷⁵ The wide therapeutic window and convenience of no routine monitoring make the NOACs desirable first-line options; however, patients taking these drugs still require close follow-up, with frequent renal function assessments to ensure their safe use. The EHRA recommends that patients on NOACs should be assessed every 3 months, with their first follow-up one month after initiation of therapy.²²

Dabigatran

Data from RE-LY and subsequent postmarketing analyses have revealed that elderly patients and those with renal dysfunction are most susceptible to bleeding.^11,23,24,26 Gastrointestinal bleeding appears to be the most common serious side effect of dabigatran therapy.^11,26 Careful screening of patients for a history of gastrointestinal bleeding and current use of nonsteroidal anti-inflammatory drugs, including aspirin, is essential. Additionally, thorough education about storage and handling of dabigatran is imperative. Patient education on the importance of adherence to dosing schedules is important, as shown by a cross-sectional cohort study of 103 patients who had been treated with dabigatran for at least 3 months, which found that 12% of patients had inadequate adherence.⁷⁶ Based on current evidence, the best candidates for this treatment include patients <75 years of age with normal or near-normal renal function and no history of gastrointestinal bleeding.²⁶ A nationwide study of patients with AF in Denmark found that deviations from the recommended use of dabigatran were frequent, and that treatment of VKA-naive patients with dabigatran was safe; however, there was an increased risk of thromboembolism and bleeding in VKA-experienced patients taking dabigatran.⁷⁷ The authors concluded that this may be due to inappropriate patient selection or transitioning patients from VKA therapy to dabigatran.⁷⁷

Rivaroxaban

Rivaroxaban is also an alternative to warfarin in appropriately selected patients with nonvalvular AF.⁷⁵ Two prespecified secondary analyses of ROCKET-AF found older age and decreased renal function to be associated with a higher bleeding risk; however, no differences were seen between rivaroxaban-treated and warfarin-treated patients.^32,78 In bleeding patients with moderately impaired renal function, critical organ (intracranial, spinal, ocular, pericardial, articular, retroperitoneal, or intramuscular with compartment syndrome⁷⁹) and fatal bleeding were less frequent with rivaroxaban than with warfarin.^32,78 Because gastrointestinal bleeding is more frequent in patients treated with rivaroxaban than in those treated with warfarin,¹⁴ careful screening of patients for a history of prior bleeding and concurrent nonsteroidal anti-inflammatory drug or antiplatelet therapy is vital.

Patients unable to tolerate dabigatran because of side effects, such as dyspepsia, are suitable candidates for rivaroxaban. Furthermore, patients with adherence issues on twice-daily medication schedules may be potential candidates for rivaroxaban. Based on the available clinical data,⁸ patients younger than 75 years of age with good renal function and no history of gastrointestinal bleeding are the most appropriate candidates for rivaroxaban.

Apixaban

Apixaban may have the best efficacy and safety profile among the NOACs based on currently available data. Apixaban appears to carry a lower risk of major bleeding when compared with warfarin for both older patients and those with renal impairment.^13,34 Data indicate that patients who are most susceptible to stroke, including older patients (age >75 years) and those with moderately impaired renal function (creatinine clearance 30–50 mL per minute), may be the best candidates for apixaban.^13,34

Cost-effectiveness

Cost is an important factor in the use and selection of NOAC therapies. Many patients requiring anticoagulation are older, on fixed incomes, and already taking a number of prescription medications.⁸⁰ Data comparing the cost-effectiveness of the NOACs are limited; however, several studies have shown reduced costs associated with NOACs in comparison with warfarin.^81–84 A study from a US payer perspective investigating medical cost reductions associated with use of individual NOACs (dabigatran, rivaroxaban, and apixaban) showed that use of NOACs may be associated with reduced medical costs relative to warfarin, with apixaban having the most substantial cost reduction.⁸⁵ Additionally, an indirect comparison study has evaluated the pharmacoeconomic impact of apixaban versus dabigatran and rivaroxaban over a lifetime, from a UK National Health Services perspective.⁸⁶ The results showed that apixaban may be a cost-effective alternative to dabigatran 150 mg (reduced to 110 mg in patients aged ≥80 years), dabigatran 110 mg, and rivaroxaban 20 mg for the long-term reduction of stroke risk in patients with nonvalvular AF.⁸⁶

Discussion

Until recently, effective reduction of stroke risk in patients with nonvalvular AF has been limited to the VKAs, but several recently approved NOACs now offer alternative treatment options. While the uptake of these agents has been robust, enthusiasm has been tempered by safety concerns prompted by reports of bleeding complications. Recent registry data found that about half of patients with AF received oral anticoagulant therapy, and among those treated, about 13% received one of the NOACs.⁸⁷ Despite the known risks associated with VKAs, bleeding complications are common, and clinicians are not usually surprised by these outcomes. Although the risks of bleeding are similar or even lower with NOACs, clinicians with limited clinical exposure to them will need to become more comfortable with these agents and their associated risks. Many advantages distinguish NOACs from VKAs, including fewer drug interactions and no need for food restriction or routine anticoagulant monitoring; however, issues similar to those seen with VKAs exist with the NOACs, including how to safely discontinue treatment and when to use bridging therapy or make dose adjustments. Thus, greater oversight of NOAC treatment may be necessary initially until clinicians become familiar with their use. Expanding the role of anticoagulation clinics may help reduce the occurrence of some bleeding events by creating systematic oversight of these agents in clinical practice.

Based on current data for the NOACs and because of the many unresolved clinical issues, clinicians should employ a stepwise approach when using these agents for patients with nonvalvular AF. Appropriate patient selection is critical, and requires diligence by the medical provider in eliciting any history of bleeding episodes and thorough medication reconciliation that may alter the therapeutic effects of these new agents.

As clinicians gain experience using these new anticoagulation options to reduce the risk of stroke in patients with nonvalvular AF, they should remind themselves that they are not trying to “hit the ball out of the park” by first using these therapies for their most challenging patients. Instead, they should start these treatments in patients who have nonvalvular AF and several stroke risk factors but for whom treatment is expected to be uncomplicated; for example, patients with normal renal function, average body weight, no history of gastrointestinal bleeding, and no concomitant medications associated with drug interactions. Once clinicians have established a comfort level in using NOACs to treat these patients, they can expand to treat a wider patient population with more complex risks.

Summary

• The wide therapeutic window and convenience of no routine monitoring make the NOACs desirable first-line options

• Patients taking these drugs require close follow-up with frequent renal function assessments to ensure their safe use

• Among patients with nonvalvular AF treated with warfarin or NOACs, bleeding is more common in patients with low body weight, advanced age, and renal impairment

• Care should be taken to ensure continuous anticoagulation when stopping, interrupting, or switching between anticoagulants to avoid an increased risk of stroke

• Practitioners can identify appropriate patients for treatment with NOACs and avoid adverse events by taking a thorough history and performing a comprehensive review of prior bleeding episodes

• The most appropriate candidates for dabigatran or rivaroxaban include patients younger than 75 years with normal or near-normal renal function and no history of gastrointestinal bleeding

• Rivaroxaban should be considered in patients with adherence issues on twice-daily dosing regimens

• The best candidates for apixaban are older patients (age >75 years) and those with moderately impaired renal function (creatinine clearance 30–50 mL per minute).

Disclosure

Professional medical writing and editorial assistance was provided by Claire Hall and Nicole Draghi of Caudex Medical, and was funded by Bristol-Myers Squibb Company and Pfizer Inc. The author has been a consultant and/or on the advisory boards of AstraZeneca, Bristol-Myers Squibb Company, and Pfizer Inc.