Left Atrial Appendages Occlusion: Current Status and Prospective.

Stroke continues to be a major cause of morbidity and mortality in atrial fibrillation (AF) patients. Oral anticoagulation (OAC) provides protection against stroke and peripheral embolization in AF but significant proportion of patients could not be started on anticoagulation because of bleeding complications. Left atrial appendage harbors clot in about 90% of nonvalvular AF. The advent of left atrial appendage occlusion (LAAO) techniques has provided these patients with alternative to OAC for stroke prophylaxis. Multiple LAAO devices are currently available with Watchman and Amulet being the most commonly used in clinical practice. Randomized studies are available for Watchman device only. Data on Amplatzer Cardiac Plug, Amulet and Lariat devices are limited by the paucity of randomized data. Long-term data on different LAAO techniques are showing promising results. Device related thrombosis continues to be a serious complication associated with LAAO. Future studies should look into comparative effectiveness between different LAAO techniques, optimal patient selection, risk of complications, and anticoagulant treatment after LAAO. This article aims to provide current available evidence on efficacy and safety of different LAAO devices and future prospective.

INTRODUCTION

Atrial fibrillation (AF) is a very common medical issue, that is estimated to have affected anywhere from 3 to 6 million Americans.1)2) Projections indicate that the prevalence of AF will triple in the United States by 2050, with similar increases expected in Europe.3) AF significantly increases the risk of ischemic stroke, with varying degree depending on the individual patient's stroke risk factors. Warfarin and novel oral anticoagulants (NOACs) are used to prevent stroke and peripheral embolization in patient with nonvalvular AF. Oral anticoagulation (OAC) decreases the risk of stroke by ≈64%.4) However, a significant percentage of patients could not be started on anticoagulation because of bleeding issues. Elderly patients are more likely to be not started on anticoagulation although studies have indicated that they can also benefit from anticoagulants.5)

Left atrial appendage occlusion (LAAO) was introduced as an alternative for stroke prophylaxis to AF patients who cannot take warfarin or NOACs. Left atrial appendage (LAA) harbors clots in 57% valvular and 90% of nonvalvular AF which is the source of embolic disease.6)7) LAAO is thus an appealing option for patients with nonvalvular AF for stroke prevention.7)8)

LEFT ATRIAL APPENDAGE OCCLUSION DEVICES

Watchman device

The Watchman device (Boston Scientific, Marlborough, MA, USA) is the most extensively studied and the only device approved by Food and Drug Administration (FDA) in United States (Figure 1). It is a self-expanding nitinol occlusion device and involves catheter-based implantation into left atrium with the guidance of transesophageal echocardiography (TEE). The device is inserted through femoral vein and is passed into left atrium through a small interatrial puncture hole that usually disappears within 6 months. The device has been implanted since 2002 in Europe and 2003 in the United States. U.S. FDA approved LAAO with Watchman to reduce the risk of stroke in patients with nonvalvular AF in March 2015.9) Approval of Watchman was driven by 2 pivotal trials: PROTECT AF and PREVAIL.

Figure 1

Major features and images of most commonly used LAAO devices.

ACP = Amplatzer Cardiac Plug; CE = Conformite Europeenne; FDA = Food and Drug Administration; LAAO = left atrial appendage occlusion.

In the PROTECT AF non-inferiority trial, 707 patients ≥18 years with nonvalvular AF with CHADS2 risk score of ≥1 were randomized to LAAO with Watchman implantation or dose-adjusted warfarin in 2:1 fashion. The primary efficacy endpoint of stroke, cardiovascular death and systemic embolism was not different between 2 groups (relative risk [RR], 0.62; 95% confidence interval [CI], 0.35–1.25). The probability of non-inferiority of the LAAO was more than 99.9%. Primary safety events including major bleeding, pericardial effusion and device embolization were more frequent in the LAAO group than in the warfarin group (7.4 per 100 patient years, 95% CI, 5.5–9.7 vs. 4.4 per 100 patient-years, 95% CI, 2.5–6.7; RR, 1.69, 1.01–3.19).10)

Compared to the PROTECT AF trial in the follow up PREVAIL trial, 407 patients with higher mean CHADS2 score were randomized in 2:1 ratio to Watchman and warfarin. Designed to show non-inferiority the PREVAIL met the safety endpoint of a composite of cardiac perforation, pericardial effusion with tamponade, ischemic stroke, device embolization, and other vascular complications occurring in the first 7 days after implant. It met non-inferiority for one efficacy endpoint of late-ischemic efficacy endpoint of stroke or systemic embolization >7 days post-randomization.11) Procedural complications decreased from 8.7% in PROTECT AF to 4.2% in PREVAIL (p=0.004).

Since the FDA approval of Watchman, the reported rate of procedure-related complications has been relatively low, including an approximately 1% rate of pericardial tamponade even though 70% of physicians implanting the device were previously inexperienced with the procedure. This initial post-FDA approval U.S. clinical experience with LAAO using the Watchman device in 3,822 consecutive patients implanted by 382 physicians revealed excellent procedural success rate (95.6%) and favorable complication rates with pericardial tamponade, procedure-related stroke, and mortality rates of only approximately 1%, 0.08%, and 0.08%, respectively.12) More recent data from CAP,13) CAP 2,12)14) EWOLUTION15) and UK16) registries show improved procedural safety (Table 1). In addition, the device has been found to result in improved quality of life.17) Cost-effectiveness analysis of LAAO with Watchman device has shown it to be more cost-effective and cost-saving solution than warfarin or newer oral anticoagulants for stroke risk reduction in patients with nonvalvular AF who are at risk of stroke but have contraindications to warfarin.18)19)

Table 1

Major studies for different types of LAAO devices: Watchman

	PROTECT AF†10)	PREVAIL†11)	CAP registry13)	CAP 2 registry12)14)	EWOLUTION15)	UK registry16)
Study types	Randomized trial	Randomized trial	Prospective registry	Prospective registry	Prospective registry	Retrospective
Population	463/244	269/138	460	579	1,021	371 (watchman=234, ACP=129, Lariat=6, Coherex Wavecrest =2)
Implantation success rate (%)	91	95.1	95	94.8	98.5	92.5
CHA2DS2-Vasc	≥1*	Mean 3.8*	Mean 2.4	2.7	4.5	4.2
HAS-BLED score				≥1 in 97%	2.3	3.3
Anticoagulation used	Warfarin for 45 days post implantation followed by aspirin and Plavix × 6 months then aspirin alone	Warfarin for 45 days post implantation followed by aspirin and Plavix × 6 months then aspirin alone	Warfarin for 45 days post implantation followed by aspirin and Plavix × 6 months then aspirin alone	Warfarin for 45 days post implantation followed by aspirin and Plavix × 6 months then aspirin alone	27% treated with OAC, 59% on dual antiplatelets, 7% single APT, 6% without any therapy	OAC-20%, DAPT 50%, OAC plus single APT-20%, single APT-10%
Ischemic stroke (%)	2.2/1.6	1.9/0.7	-	-	-	0.1
Hemorrhagic stroke (%)	0.1/1.6	0.4/0	-	-	-	0.5
Major bleeding (%)	3.5/4.1	0.4/NA	0.7	-	0.7	0.5
Pericardial effusion/tamponade (%)	4.8/0	0.4/0	2.2	2.4	0.5	0.8
Device embolization (%)	0.6/0	0.7/0	0	0	0.2	1.3
Procedure-related stroke (%)	1/0	0.4/0	0	-	-	-

ACP = Amplatzer Cardiac Plug; APT = antiplatelet therapy; DAPT = dual antiplatelet therapy; LAAO = left atrial appendage occlusion; NA = not available; OAC = oral anticoagulation.

*CHADS2; †Randomized studies, n/n=LAAO/warfarin arms.

Amplatzer Cardiac Plug and Amulet

Amplatzer Cardiac Plug (ACP; St. Jude Medical, St. Paul, MN, USA) is a self-expanding double-disc device that is implanted via femoral access into LAA via transseptal puncture (Figure 1). The Amulet device is the second generation of ACP with improvements in the implantation apparatus. Data from large multicenter ACP study consisting of 1,047 patients with an average follow up of 13 months showed annual rate of systemic thromboembolism of 2.3% (59% risk reduction based on patient stroke risk scores) and major bleeding of 2.1% (representing 61% risk reduction).20) Long-term data from cumulative experience of 2 Italian centers obtained from a relatively large cohort treated with LAAO using the ACP device with a follow up period of up to 4 years had demonstrated similar reduced annual rate of systemic thromboembolism and major bleeding (2.5% and 1.3%) respectively.21) A recent global prospective registry of large cohort of AF patients (n=1,088) at high risk for ischemic stroke as well as bleeding, implanted with the Amulet device demonstrated a high implantation success (99.0%) and adequate LAAO in almost all patients who received a device (99.8%). The clinically relevant major adverse events during implantation and subsequent hospitalization was 3.2%.22) Major findings from the other ACP and Amulet registries23)24)25)26)27) are shown in Table 2. Comparative studies have shown similar results obtained with the ACP and Amulet devices in terms of safety, implantation success and appropriate closure of the LAA.28)29)

Table 2

Major studies for different types of LAAO devices: Amplatzer Cardiac Plug and Amulet

Characteristics	Tzikas et al.20)	Koskinas et al.25)	Berti et al.24)	López Mínguez et al.27)	Kleinecke et al.26)	Urena et al.23)
Study type/device used	Retrospective/ACP	Prospective/ACP 408, Amulet 92	Prospective/ACP 91, Amulet 17	Prospective/ACP	Retrospective/Amulet	Retrospective/ACP
Population	1,047	500	108	167	50	52
Implantation success rate (%)	97.3	97.8	100	94.6	98	98.1
CHA2DS2-Vasc score	4.5	4.3	4.3	4	5.2	5 (median)
HAS-BLED score	3.1	2.9	3.4	3	3.5	4 (median)
Anticoagulation used	16% treated with warfarin, otherwith variable combinations of aspirin, clopidogrel, LMWH	DAPT with aspirin for 5 months plus clopidogrel for 1–6 months	-	DAPT with asprin and clopidogrel. Aspirin for 6–12 months and clopidogrel for 3–6 months	DAPT with clopidogrel × 3 months and aspirin for at least 6 months	DAPT or single APT for 1–6 months followed by single APT
Annual Ischemic stroke (%)	2.3	-	2.2	3.9	6.1	1.9
Annual hemorrhagic stroke (%)	2	-	1.1	-	-	-
Major bleeding (%)	1.2	3.2	0.9	5.7	4	3.8
Pericardial effusion/tamponade (%)	1.24	3.2*	2.7	1.2	4	1.9
Device embolization (%)	0.7	2	0	-	2	1.9
Procedure related stroke (%)	0.8	1	-	1.2	-	0

ACP = Amplatzer Cardiac Plug; APT = antiplatelet therapy; DAPT = dual antiplatelet therapy; LAAO = left atrial appendage occlusion; LMWH = low molecular weight heparin.

*Hemodynamically significant pericardial effusion.

Currently, the Watchman and the Amulet are the most commonly implanted devices for catheter-based LAAO, with a higher penetration of the Amulet device within Europe compared with non-European geographies.21) They are increasingly being tried in different subset of population. Recent preliminary study of LAAO with ACP and Watchman has shown promising result in hemodialysis patients with high CHA2DS2-VASCs and HASBLED scores were 4.0 (1.5) and 4.4 (0.9), over short term follow up.30) A recent Korean multicenter registry in nonvalvular AF patients with LAA thrombus found Watchman and ACP devices may be a safe and feasible alternative to anticoagulation in select patients at a high risk of bleeding or contraindication to anticoagulation, or in whom anticoagulation failed to prevent stroke.31)

Lariat device

Alternative epicardial approaches for LAAO have also been studied and are of particular value in patients who cannot tolerate any anticoagulation and do not have suitable LAA anatomy for endocardial occlusion. The procedure is characterized by delivery of a pre-tied suture loop over the LAA by means of guidance from dual-wire access from femoral and epicardial approach. The largest experience is with the LARIAT device (SentreHEART, Redwood, CA, USA) which is a hybrid procedure with transseptal endocardial and pericardial access used to place a ligature around the LAA (Figure 1). Recent studies also suggest LAA as a non-pulmonary vein focus of origin of AF. Epicardial based exclusion procedures can electrically isolate the LAA and there might be a benefit of reducing AF burden in addition to stroke prevention especially in nonparoxysmal AF. The largest prospective registry on Lariat showed the success rate of >95% with low risk of procedure-related mortality (0.14%).32) The most common serious complication was found to be cardiac perforation related to epicardial access which was significantly reduced with the use of micropuncture needle for pericardial access. Similarly, use of micropuncture needle was associated with lower rate of bleeding complications.32) Table 3 show the details of other 2 available large studies33)34) on Lariat device.

OTHER METHODS OF LEFT ATRIAL APPENDAGE OCCLUSION

Articlip system

The Atriclip LAA occlusion devices (Articure Inc., Mason, OH, USA) (Figure 2A) have been evaluated for LAA closure at the time of concomitant open heart surgery under direct visualization. High closure success was demonstrated in the Exclusion of the Left Atrial Appendage with a Novel Device: Early Results of a Multicenter Trial (EXCLUDE) trial by TEE or computed tomographic angiography (CTA) at 90-day follow up. With 95.7% implantation success rate the trial met its safety (major bleeding) and efficacy endpoint (ischemic stroke).35)

Figure 2

Images of (A) Articlip, (B) Ultraseal and (C) Wavecrest devices.

Ultraseal left atrial appendage device

The Ultraseal LAA device (Cardia, Inc., Eagan, MN, USA) is a percutaneous, transcatheter device (Figure 2B) that consists of a distal soft bulb and a proximal sail attached by an articulating joint that allows a high degree of device conformability to the different variations of the LAA anatomy. The device can be retrieved and redeployed multiple times in a single procedure without replacing the device or delivery sheath. Initial experience of Ultraseal device from Canada showed successful implantations in all patients (n=12) without periprocedural complications. No episodes of bleeding, stroke, pericardial effusion or device embolization were noted at 45-day follow up.36)

Wavecrest device

Wavecrest LAAO system (Coherex medical Inc., Salt Lake City, UT, USA) is the latest development in LAAO devices. It consists of a nitinol frame with retractable coils and anchors to enable optimal device positioning (Figure 2C). The device is relatively short and is designed for more proximal deployment in the LAA. Coherex WAVECREST I trial, a prospective observational study to establish the safety and efficacy of Coherex Wavecrest device for LAA closure has been completed and results are awaited.37)

SURGICAL REMOVAL WITH OTHER CARDIAC PROCEDURES

The LAA can also be surgically removed simultaneously with other cardiac procedures. Meta-analysis of 2 randomized trials and five observational studies of surgical LAA closure in the setting of cardiac arterial bypass grafting or mitral valve surgery (n=3,653 patients) suggests that LAA closure is associated with a lower incidence of stroke at 30-day follow up (0.95% vs. 1.9%; odds ratio [OR], 0.46; p=0.005).38)

ANTICOAGULATION MANAGEMENT DURING LEFT ATRIAL APPENDAGE OCCLUSION

Despite these favorable results with LAAO, some serious side effects, such as device-associated strokes, are described. A recently published prospective registry from 8 French centers with 469 patients with AF undergoing LAAO (272 Watchman and 197 Amplatzer devices) with mean follow up of 13 months found an annual incidence of device-related thrombus at 7.2% per year.39) In particular, the first 45 days after implantation are a critical transition period. Anticoagulation with coumadin is warranted for 45 days post-implantation after which complete endothelization of the device is expected.10)40) Once the device is completely endothelized (no gaps around the device larger than 5 mm with communication to the appendage) anticoagulation is stopped and patients are started on aspirin and clopidogrel for 6 months. At 6 months post-implantation, aspirin is recommended indefinitely. However, endothelization might take more time in some patients; consequently they can develop device related thrombus after discontinuation of anticoagulation.41) In PROTECT trial warfarin was prescribed for at least 45 days after successful device implantation. In subsequent studies with Watchman device dual antiplatelet therapy (DAPT) for at least 6 months after implantation was shown to be safe in patients with contraindications for OAC.42)43) DAPT was shown to be safe and effective in one study with regard to the ACP device as well.23) Newer studies are showing the feasibility of NOACs in LAAO. A pilot study from Germany found LAAO with NOACs compared to DAPT shows similar rate of all-cause mortality, major adverse cardiac and cerebrovascular events and major bleeding at 45-day follow up.44) A recently published retrospective multicenter study found the use of NOACs in the post-WATCHMAN period to be feasible alternative with similar rates of bleeding events (0.5% vs. 0.9%, p=0.6) and composite of device-related thrombosis or thromboembolism (1.4% vs. 0.9%, p=1) compared with uninterrupted warfarin.45)

LONG-TERM DATA AND HEAD TO HEAD STUDIES

Patient level meta-analysis from 5-year follow up of PROTECT and PREVAIL trials showed beneficial effect of LAAO watchman device over coumadin for nonvalvular AF with similar stroke reduction but significant reduction in major bleeding including hemorrhagic stroke and mortality.46) Similarly a recently published results of the Iberian registry of LAAO with a total of 598 patients (1,093 patient-years) with a contraindication for anticoagulants and mean follow up of 23 months showed significantly reduced rate of stroke and bleeding events.47) The rate of ischemic stroke was 1.6% (vs. 8.5% expected according to CHA2DS2-VASc; p<0.001); intracranial hemorrhage 0.8%; gastrointestinal bleeding 3.2%; severe bleeding 3.9% (vs. 6.3% expected by HAS-BLED, p=0.002). Further improvement in the outcomes were demonstrated in the subgroup of 176 patients with follow up >24 months (mean follow up 46.6 months, 683 patient-years). LAAO using the ACP device in 134 patients from 2 Italian centers had demonstrated favorable outcome with annual rate of systemic thromboembolism and major bleeding (2.5% and 1.3%) at 4-year follow up.21) A single center study with 10-year experience of LAAO with ACP with a mean follow up of about 3-year showed 7% incidence of safety events. However, the study found excellent intermediate-term outcome once the procedural risk is overcome.48) A recent study involving high risk elderly population (average age 76) with CHA2DS2-VASc of 5 and HAS-BLED of 4 followed for 4 years showed stroke rate of 6.9%. The reported long-term mortality rate was high in the study at 33.7%.49)

Comparative studies between different LAAO devices is sparse. In a multicenter observational study with a total of 479 patients (Watchman=219, Lariat=259) and 12-month of follow up, the Watchman group was found to have statistically higher incidence (21% vs. 13%, p=0.01) and mean leak size (3.10±1.1 mm vs. 2.15±1.4 mm; p<0.001) than did the Lariat group.50) However, there was similar rate of thromboembolism (3.7% vs. 1.6%, p=0.23) and stroke rate (1.3% vs. 1.1%, p=0.99) between Watchman and Lariat.

CURRENT GUIDELINES BY PROFESSIONAL SOCIETIES

The latest American Heart Association/American College of Cardiology guidelines from 2014 suggest that surgical excision of the LAA may be considered in patients undergoing cardiac surgery or thoracoscopic AF surgery (grade IIB).51) However, the guideline does not make any recommendation regarding use of LAAO devices for stroke prevention citing the lack of clinical trials. This guideline was released prior to Watchman's approval by FDA. On the other hand, the current European Society of Cardiology Guidelines recommend that LAAO may be considered for stroke prevention in patients with AF and contraindications for long-term OAC (e.g., those with a previous life-threatening bleed without a reversible cause) (IIb, LOE B) despite the lack of randomized data on safety and efficacy of LAAO in patients with contraindications to OAC.52) We believe that it is time to revise these guidelines to make LAA occlusion a class I indication.

FUTURE STUDIES AND NEWER APPLICATIONS OF LEFT ATRIAL APPENDAGE EXCLUSION

Since the first LAAO device in 2002, rapidly growing studies have supported the strategy and it is gaining popularity. The only randomized controlled trials on LAAO (on Watchman) available until now have excluded patients with contraindications to OAC therapy. However, current data stemming from numerous registry studies may seem to justify LAAO in patients with nonvalvular AF who have contraindications to OAC. On the other hand, evidence for ACP, Amulet and Lariat device are driven by non-randomized retrospective and prospective studies only which has limited its impact. Furthermore, there were several other exclusion criteria in these randomized and non-randomized studies restricting generalization to whole spectrum of AF patients. Thus, randomized studies involving different subsets of AF patients might be warranted in the future.

Emerging data highlight the impact of various LAAO approaches in different physiological functions (Figure 3). Although LAA is considered to be a cardiac vestige, its influence on various physiologic aspects of cardiac vascular systems seems to be pretty broad. LAA may have impact on the neurohormonal, left atrial function and even be a potential source of cardiac arrhythmias. Previous surgical data showed that LAA is a rich source of atrial natriuretic peptide (ANP) which is important for fluid and sodium balance in the body. Elimination of the same may result in significant fluid retention. There are also questions whether LAA functions as a reservoir chamber to accommodate volume changes in the human body. Endocardial ablation of the LAA was shown to significantly improve the overall success rates in non-paroxysmal AF patients.

Figure 3

Physiological impact of different LAAO approaches.

LAA = left atrial appendage; LAAO = left atrial appendage occlusion.

While both endocardial and epicardial approaches reduce stroke risk and improve left atrial reservoir function its role in neurohormonal regulation and arrhythmia burden reduction has been elucidated in studies with epicardial suture delivery approach brain natriuretic peptides (BNPs) and ANP levels were shown to decrease after epicardial LAA isolation.53)54) The impact of such neurohormonal changes in hemodynamics was tested in the LAA HOMEOSTASIS study which demonstrated that epicardial LAAO results in significant decrease in blood pressure at 24 hour and 3 months.55) Similarly, recent studies also suggest LAA as a non-pulmonary vein focus of origin of AF. Epicardial based exclusion procedures can electrically isolate the LAA and there might be a benefit of reducing AF burden in addition to stroke prevention especially in nonparoxysmal AF.56)57)58) The ongoing a MAZE trial (NCT02513797) will give further data regarding the benefit of such a strategy in persistent AF.59) This sets the foundation for a large body of research that needs to happen in this space that was once thought to be irrelevant to cardiac function.

Optimizing safety and efficacy in the real world

LAA has a highly variable anatomical structure and may offer various procedural challenges. Newer studies are showing promising results with increased operator experience and lower rate of complications in the real-world setting. However, comprehensive patient assessment prior to undergoing LAA closure should be encouraged. This should be able to identify patients at high risk of procedural complications and overall prognosis. Besides, future registries and clinical studies should continue to contribute to further design improvement of LAA closure devices.

Data on usefulness of NOACs is sparse. Future studies should look into the role of NOACs in LAAO. Clinical studies should be undertaken not only to compare LAAO versus NOACs but to explore the superiority of different types of NOACs in LAAO for stroke prevention.

There is clear evidence to show the long-term cost-effectiveness of the Watchman device. The LAAO surpasses NOACs in their cost effectiveness after a 4-year mark. Robust clinical and financial models that would help us understand the long-term economic impact of these devices should be undertaken as their use increases.

Currently, there are a few important undergoing studies that can potentially change the practice and utilization of LAAO. The Amplatzer Amulet LAA Occluder trial (Amulet IDE) is a prospective randomized multicenter worldwide trial that started enrolling patients in August 2016, randomizing patients in a 1:1 fashion to either the Amulet device or the Watchman device. The Amulet device will be evaluated for safety and efficacy by demonstrating its performance is non-inferior to Watchman LAA closure device in patients with nonvalvular AF (NCT02879448).60) The primary safety endpoint is a composite of procedure-related complications or all-cause death or major bleeding through 12 months, and the primary efficacy endpoint is a composite of ischemic stroke or systemic embolism through 18 months.

Another important study that is recruiting patient is Interventional Left Atrial Appendage Closure vs. Novel Anticoagulation Agents in High-risk Patients with Atrial Fibrillation (PRAGUE-17 Study, NCT02426944). This randomized multicenter open label trial is recruiting a total of 400 patients into LAAO (Watchman or Amulet) and NOAC group. The primary endpoint is the combination of stroke, other systemic cardiovascular event, clinically significant bleeding, cardiovascular death or procedure or device-related complications. The trial is expected to be completed by May 2020.61)

A randomized clinical trial Assessment of the Watchman Device in Patients Unsuitable for Oral Anticoagulation (ASAP-TOO; NCT02928497) of patients with nonvalvular AF at increased risk of stroke but who are not candidates for any anticoagulation has been initiated, randomizing patients to either Watchman and aspirin/clopidogrel or conservative medical therapy alone with aspirin and/or clopidogrel. With estimated enrollment of 888 patients the study seeks to evaluate the primary safety endpoint (7-day combined rate of death, ischemic stroke, systemic embolism and complications requiring major cardiovascular or endovascular intervention) and efficacy endpoint (comparison of time to first event of ischemic stroke and systemic embolism).62)

Finally, as more data on LAAO becomes available expert consensus document from professional societies on both sides of the Atlantic is anticipated for best practice guidelines.

Table 3

Major studies for different types of LAAO devices: Lariat

Characteristics	Lakkireddy et al.32)	Price et al.34)	Bartus et al.33)
Study type	Prospective registry	Retrospective	Prospective
Population	712	154	89
Ligation success rate (%)	98	94	96
CHA2DS2-Vasc score	3.9	4	2.8
HAS-BLED	3.4	3	2.4
Anticoagulation used	21% OAC, 80% on single antiplatelet, 20% on DAPT	24% OAC, 24% DAPT, aspirin alone 31%, no therapy 21%	61% on OAC at 1-year follow up
Annual ischemic stroke (%)	-	-	-
Hemorrhagic stroke (%)	-	-	1.1
Major bleeding (%)	0	9.1	-
Pericardial effusion/tamponade (%)	-	10.4	-
Device embolization (%)	-	-	0
Procedure related stroke (%)	0	0	0

DAPT = dual antiplatelet therapy; LAAO = left atrial appendage occlusion; OAC = oral anticoagulation.