Introduction
Hypertrophic cardiomyopathy (HCM) is one of the most common hereditary cardiovascular diseases [
1‐
4] characterized by asymmetrical myocardial hypertrophy, cardiomyocyte disarray, and interstitial fibrosis [
5]. These pathophysiologic abnormalities lead to increased risks of outflow tract obstruction, heart failure, arrhythmia, stroke, and death [
6]. Compared with the general population, patients with HCM are at a significantly higher risk of developing AF, which might be attributed to atrial cardiomyopathy and atrial enlargement due to left ventricular diastolic dysfunction [
7‐
10]. Atrial fibrillation (AF) is the most common supraventricular arrhythmia in patients with HCM [
1,
11].
The coexistence of HCM and AF is associated with an elevated incidence of thromboembolic events, resulting in adverse clinical outcomes and heavy healthcare burdens [
7,
9,
12‐
14]. Current clinical guidelines recommend that patients with HCM and AF should be anticoagulated with vitamin K antagonists (VKA) regardless of their CHA
2DS
2-VASc scores [
3,
4]. Direct oral anticoagulants (DOAC) have been recommended for patients with non-valvular AF according to evidence of their non-inferiority or superiority over VKA [
5]. However, the benefit-risk profile of DOAC therapy in patients with HCM and AF has not been well established yet. Due to the lack of randomized controlled trials, high-quality evidence on the use of DOAC for primary and secondary stroke prevention in this population is still quite limited. In recent years, several observational studies regarding anticoagulant therapy in patients with HCM and AF have been published [
15‐
21], which might shed some light on this issue. Therefore, we undertook a meta-analysis of all available studies to evaluate the efficacy and safety of DOAC compared with VKA in patients with HCM and AF.
Discussion
In the present study, we have undertaken a systematic review of studies on the efficacy and safety of DOAC versus VKA in patients with HCM and AF. In this meta-analysis of 9395 patients with HCM and AF, the incidences of thromboembolic events, ischemic stroke, major bleeding, major or clinically relevant bleeding, and gastrointestinal bleeding were comparable between the DOAC group and the VKA group. In addition, DOAC therapy was superior to VKA therapy in reducing the risk of all-cause death, cardiovascular death, and intracranial hemorrhage.
AF is the most prevalent sustained arrhythmia in patients with HCM [
1,
11]. During a follow-up of 10 years, about 22% to 30% of patients with HCM would develop AF [
8,
9,
12]. The probability of developing AF in patients with HCM is fourfold to sixfold higher than that in the general population [
7‐
10]. Patients with HCM have a remarkably elevated thromboembolic risk when complicated by AF. The annual incidence of stroke is estimated to be 4%, and about 27% of patients with HCM and AF would experience a thromboembolic event during their lifetime [
12]. Given the severe thromboembolic risk, clinical guidelines suggested that all patients with HCM and AF should receive lifetime anticoagulation therapy when no contraindication exists. The commonly-used CHA
2DS
2-VASc score is not recommended for stroke risk evaluation in patients with HCM and AF [
3,
4].
Previous studies showed that VKA therapy could significantly reduce the incidence of thromboembolic events in patients with HCM and AF [
8,
11]. However, VKA is related to several shortcomings including narrow therapeutic windows, dosage variations, frequent monitoring, and drug-food interactions [
24]. The superiority or non-inferiority of DOAC versus VKA has been confirmed in patients with nonvalvular AF [
25‐
28]. However, evidence on the use of DOAC in patients with non-valvular AF could not be directly generalized to patients with AF and HCM since different patterns of structural cardiac abnormalities might result in variant responses to anticoagulant therapy. Previous studies demonstrated that hypertrophic obstructive cardiomyopathy might lead to blood stagnation [
9,
29] and enhance the thrombogenesis of endothelium [
30]. Meanwhile, it’s detected that some cell lines of HCM patients could produce thrombosis-inducing anti-cardiolipin antibodies when AF occurs [
31]. These factors might contribute to the distinctive characteristics of patients with HCM and AF in thromboembolic risk and treatment response. A post-hoc analysis of the RE-LY study showed that left ventricular hypertrophy was related to reduced antithrombotic efficacy of warfarin in AF patients, but not of dabigatran [
32]. The number of HCM patients included in existing DOAC trials is presumed to be low, since these patients tend to be younger and do not exhibit typical thromboembolic risk factors demanded to participate in DOAC trials [
25‐
28]. Therefore, data on the efficacy and safety of DOAC in patients with HCM and AF is lacking. Since there is no randomized controlled trial on DOAC therapy in patients with HCM and AF, the efficacy and safety of DOAC in these patients are still controversial.
In recent years, accumulative observational studies have indicated the potential of DOAC in patients with HCM and AF, with a comparable thromboembolic risk and a reduced bleeding risk versus VKA [
15‐
21]. Noseworthy, et al. used a large United States commercial insurance database to provide a glimpse at real-world clinical outcomes of DOAC use in patients with HCM and AF for the first time. A total of 2198 patients with HCM and AF were included. After propensity-score matching, patients treated with DOAC (
n = 568) displayed a similar risk of stroke or systemic embolism (1.93 vs. 2.03 per 100 person-years) and a nonsignificant lower incidence of major bleeding (4.18 vs. 5.38 per 100 person-years) compared with those using warfarin (
n = 859) [
15]. A small multicenter study conducted in Spain indicated that patients receiving DOAC therapy (
n = 99) showed similar embolic and bleeding incidences compared with those treated with VKA (
n = 433). But patients receiving DOAC therapy reported better treatment satisfaction [
16]. So far, data on this issue with the largest sample size were provided by South Korea [
17,
18,
21]. Jung et al. identified 955 warfarin-treated and 1504 DOAC-treated patients with HCM and AF (1:2 propensity-matched) from the Korean National Health Insurance Service database. During a median follow-up of 16 months, the incidences of ischemic stroke and major bleeding were comparable between the two groups. But DOAC therapy was related to a remarkably lower risk of all cause-mortality [HR (95% CI): 0.43 (0.32–0.57)] and composite fatal cardiovascular events [HR (95% CI): 0.39 (0.18–0.82)] compared with warfarin therapy [
17]. In another real-world Korean study involving 2397 patients with HCM and AF, DOAC was indicated to be superior to warfarin in both effectiveness and safety. This superiority was constant disregarding DOAC dose. In addition, separate analysis for individual DOAC showed that significantly reduced risks of ischemic stroke and the composite outcome could be observed in all DOAC [
17]. Evidence on DOAC therapy in Chinese patients with HCM and AF was still limited. A small retrospective study including 124 Chinese patients with HCM and AF demonstrated that DOAC had a lower incidence of clinically relevant bleeding and a similar risk of all-cause death, cardiovascular death, and thromboembolic events compared with warfarin [
19]. Liu et al. undertook a prospective, multicenter registry study that enrolled 393 patients with AF and HCM. During a median follow-up of 42 months, the risk of thromboembolism [(HR (95%CI): 1.21 (0.42–3.50)] and major bleeding [HR (95%CI): 1.50 (0.27–8.41)] were similar between the DOAC-treated group (
n = 133) and the warfarin-treated group (
n = 260) [
33].
There are two meta-analyses focused on DOAC therapy in patients with HCM and AF so far [
34,
35]. They were published in 2019 and 2020 respectively. Zhou et al. undertook a meta-analysis of 4 observational studies and found that DOAC therapy was associated with reduced incidences of ischemic stroke, all-cause death, and intracranial hemorrhage. But there was no difference in the risk of stroke or systemic embolism, major or clinically relevant bleeding, and gastrointestinal bleeding in DOAC-treated patients compared with VKA-treated patients [
34]. Another meta-analysis of three retrospective cohort studies showed that patients receiving DOAC therapy had a significantly lower incidence of all-cause death but a similar risk of ischemic stroke, major bleeding, and intracranial bleeding compared with patients using VKA [
35]. Recently, several observational studies on this issue, including two conducted on Chinese patients, have been published [
19‐
21]. To the best of our knowledge, our meta-analysis of 7 studies has provided a comprehensive, updated, integrated conclusion on the efficacy and safety of DOAC therapy in patients with HCM and AF.
The above-mentioned evidence has contributed to the improvement of recommendation levels for DOAC in present guidelines. In the 2020 American Heart Association/American College of Cardiology Foundation guideline for HCM, anticoagulation is recommended with direct-acting oral anticoagulants (DOAC) as the first-line option and vitamin K antagonists as the second-line option in patients with HCM and clinical AF (Class I, level of evidence B) [
4]. Despite the absence of randomized controlled trials, accumulative evidence from observational studies showed that DOACSs might be effective and safe in patients with HCM and AF [
15‐
21]. Therefore, the 2021 European Heart Rhythm Association guideline recommended that patients with HCM might be eligible for DOAC therapy [
36]. However, it must be pointed out that these recommendations were based on evidence from observational studies. Further randomized controlled trials on the efficacy and safety of DOAC in patients with HCM and AF might shed more light on this issue.
Several limitations should be noted in this meta-analysis. First, some of the included studies were conducted in a single center with small sample sizes and short follow-up time, leading to underpowered results and unreliable conclusions. Second, heterogeneity existed in study design and endpoint definitions across the 7 included studies, which might have an impact on the results to some extent. Third, due to the observational nature of included studies, the relevant confounders could hardly be exhaustive. The results should be interpreted with caution. In addition, due to the limited data, we could not perform the subgroup analysis according to DOAC types, DOAC dosages, time in the therapeutic range, and HCM phenotypes. Finally, although an extensive search of databases has been undertaken, some studies might not be included.
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