Long‐term Outcomes of Catheter Ablation of Atrial Fibrillation: A Systematic Review and Meta‐analysis

Background In the past decade, catheter ablation has become an established therapy for symptomatic atrial fibrillation (AF). Until very recently, few data have been available to guide the clinical community on the outcomes of AF ablation at ≥3 years of follow‐up. We aimed to systematically review the medical literature to evaluate the long‐term outcomes of AF ablation. Methods and Results A structured electronic database search (PubMed, Embase, Web of Science, Cochrane) of the scientific literature was performed for studies describing outcomes at ≥3 years after AF ablation, with a mean follow‐up of ≥24 months after the index procedure. The following data were extracted: (1) single‐procedure success, (2) multiple‐procedure success, and (3) requirement for repeat procedures. Data were extracted from 19 studies, including 6167 patients undergoing AF ablation. Single‐procedure freedom from atrial arrhythmia at long‐term follow‐up was 53.1% (95% CI 46.2% to 60.0%) overall, 54.1% (95% CI 44.4% to 63.4%) in paroxysmal AF, and 41.8% (95% CI 25.2% to 60.5%) in nonparoxysmal AF. Substantial heterogeneity (I2>50%) was noted for single‐procedure outcomes. With multiple procedures, the long‐term success rate was 79.8% (95% CI 75.0% to 83.8%) overall, with significant heterogeneity (I2>50%).The average number of procedures per patient was 1.51 (95% CI 1.36 to 1.67). Conclusions Catheter ablation is an effective and durable long‐term therapeutic strategy for some AF patients. Although significant heterogeneity is seen with single procedures, long‐term freedom from atrial arrhythmia can be achieved in some patients, but multiple procedures may be required.

C atheter ablation of atrial fibrillation (AF) has become an established therapeutic modality for the treatment of patients with symptomatic AF. 1 To date, studies reporting outcomes of AF ablation have predominantly limited follow-up to 1 to 2 years after the index ablation procedure. [2][3][4] Although the long-term efficacy of AF ablation is less precisely defined, it is of critical relevance to individual patient prognosis, clinical decision making, and reimbursement policies for the procedure. Until recently, few series have presented the long-term outcomes of AF ablation at ≥3 years of follow-up. In the current study, we systematically reviewed the medical literature to evaluate the long-term single-and multiple-procedure efficacy of AF ablation.

Methods
The study was conducted in accordance with principles established for meta-analyses of observational studies. 5 We searched PubMed, Embase, Web of Science, and Cochrane Database for published articles describing long-term outcomes in patients undergoing catheter ablation of AF. The search design was conducted with the assistance of a research librarian, and the detailed search methodology is presented in Appendix S1. This search was supplemented by hand-searching bibliographies of published studies and relevant review articles. Citations were included if they involved an evaluation of percutaneous catheter ablation outcomes at ≥3 years after the index ablation procedure, with a mean/median follow-up of ≥24 months. Randomized controlled trials, case-control studies, cohort studies, and case series were included. Individual case reports, editorials, review articles, and meeting abstracts were excluded. Studies published in languages other than English were excluded. Studies involving surgical AF ablation and AV nodal ablation, or exclusive right atrial ablation, were excluded. The search was conducted on July 8, 2011. Citations were appraised by 3 independent reviewers (A.G., N.J.S., A.G.B.), with differences resolved by consensus. Selected publications were analyzed for the following outcomes: (1) primary ablation success-defined as cumulative survival free of recurrent atrial arrhythmia; (2) multiple-procedure success-defined as cumulative survival free of atrial arrhythmia, including patients receiving >1 ablation procedure; and (3) number of patients undergoing multiple procedures. We included data presented as Kaplan-Meier analyses or actuarial recurrence rates. Latest follow-up was defined as the latest follow-up time point with ≥30 patients at risk. The definitions of postprocedure blanking period and use of antiarrhythmic drugs were left to individual study design. If on-drug and drug-free success data were available, drug-free success data were included in the statistical analysis. Study data were clarified with original investigators if required. Study quality was assessed using a modified version of quality assessment criteria for case series. 6

Statistical Analysis
Cumulative survival data were obtained from each study and pooled at the 1-year follow-up and latest follow-up time points. For Kaplan-Meier data, arrhythmia-free survival rates were extracted using graphic digitization software (DigitizeIt). In the absence of standard errors for each Kaplan-Meier curve, the number at risk at the time point of interest was used to conservatively estimate the standard error. A pooled estimate of survival at 12 months and the latest follow-up was calculated, using random-effects models based on logit transformed proportions. 7 The time point of latest follow-up in a study was defined as the last time point reporting a minimum of 30 subjects at risk. A minimum of 3 studies was required to perform meta-analysis. Heterogeneity was assessed with the I 2 statistic, with 50% defined as the threshold for significant heterogeneity. 8 Subgroup analysis and random-effects metaregression were performed to explore possible reasons for heterogeneity of study outcomes. Evidence for publication bias was assessed graphically using funnel plots. For the number of procedures per patient, exact Poisson CIs were calculated around each study estimate. Study estimates and CIs were then pooled using random-effects models. Statistical analysis was performed with Comprehensive Meta-Analysis software, version 2 (Biostat) and STATA version 11 (StataCorp).

Baseline Patient Characteristics
A total of 6167 patients were included from the 19 studies. The mean age of patients in the included studies ranged from 51 to 65 years (Table 1). All studies predominantly included male subjects, with the proportion of male subjects varying from 57% to 90% (Table 1).The mean left atrial diameter varied from 38 to 47 mm and the mean left ventricular ejection fraction varied from 53% to 70% (Table 1).

Catheter Ablation Approach
Pulmonary vein (PV) isolation using radiofrequency energy was the method of ablation in the majority of included studies ( Table 2). A wide area or PV antral circumferential ablation strategy was used in 10 studies. 11,14,15,17,18,[20][21][22]25,27 Segmental PV isolation was used in 4 studies. 11,13,14,23 The stepwise ablation technique was the procedure of choice in 2 studies. 24,26 Two studies used an anatomical electroanatomic map-guided ablation approach without PV isolation as an end point. 9,10 One study reported outcomes after selective ablation of arrhythmogenic veins defined by ectopic firing in the baseline state or presence of isoproterenol. 19 The 2 randomized controlled trials reported comparisons of ablation strategies. 14,15 Early studies tended to use nonirrigated conventional ablation catheters, with later published studies using predominantly irrigated ablation catheters.

Follow-up
The mean or median duration of follow-up in included studies varied from 28 to 71 months ( Table 2). Follow-up intensity differed between studies. The majority of studies (13/15) conducted a clinic visit with ≥24-hour Holter monitoring and electrocardiography on ≥4 occasions in the first year after index ablation. After the first year, follow-up intensity was generally reduced in most studies ( Table 2). Although some studies continued at least 3 to 6 monthly clinic visit and Holter monitoring, other studies reported outcome results beyond 1 year based on data from referring clinicians or direct contact by research personnel with patients. One study rehospitalized patients at 5 year for inpatient Holter, electrocardiographic, and exercise stress testing. 24 One study assessed AF recurrence based on a prospective AF registry. 25

Single-Procedure Efficacy of Catheter Ablation
Outcome data regarding the efficacy of catheter ablation of AF were available in all studies. Most studies provided singleprocedure success rates, defined as the percentage of patients free of atrial arrhythmia or not requiring a second procedure at 12 months. The pooled overall success rate was 64.2% (95% CI 57.5% to 70.3%, Figure 2A). The pooled 12month success rate for the 11 studies reporting outcomes for PAF patients was 66.6% (95% CI 58.2% to 74.2%, Figure 2A), and for the 6 studies reporting outcomes for NPAF patients, it was 51.9% (95% CI 33.8% to 69.5%, Figure 2A). Heterogeneity exceeded 50% in each of these groups. At late follow-up, the overall single-procedure success, defined as freedom from atrial arrhythmia at latest follow-up, was 53.1% (95% CI 46.2% to 60.0%, Figure 2B). Mean long-term success in the studies separately reporting PAF outcome was 54.1% (95% CI 44.4%  to 63.4%, Figure 2B), and in the 4 studies reporting NPAF outcome, it was 41.8% (95% CI 25.2% to 60.5%, P=0.3 versus PAF, Figure 2B). I 2 exceeded 50% for long-term singleprocedure outcome data, indicating significant heterogeneity ( Figure 2B). Long-term single-procedure outcomes for longstanding persistent AF were reported in 3 studies, 17,23,27 but meta-analysis was not performed due to small numbers (<10 patients) of patients at late-term follow-up in 2 of these studies. 23,27 We specifically evaluated the impact of segmental compared with circumferential PV isolation. There was no statistical difference in outcomes for segmental PV isolation (5 studies, 52.4% [95% CI 30.2% to 73.8%]) compared with wide antral circumferential PV isolation 51.6% (9 studies, 95% CI 42.7% to 60.4%, P=0.947).
We also specifically analyzed the impact of antiarrhythmic drugs by assessing late single-procedure outcomes in the subgroup of 14 studies reporting drug-free success. In this group, late single-procedure success was 57.4% (95% CI 50.9% to 63.8%), which was similar to overall clinical outcomes.

Predictors of Recurrent Arrhythmia
We evaluated predictors of success using meta-regression to explore study-level covariates responsible for between-study heterogeneity. We modeled the late single-procedure success and multiple-procedure success considering mean age, left atrial size, sex, and proportion of PAF as study-level covariates. None of the study-level covariates was predictive of single-procedure or multiple-procedure success. Thirteen individual studies reported predictors of recurrence in AF ablation in univariate and/or multivariate analysis (Table 3). Commonly identified variables predictive of AF recurrence included NPAF, left ventricular systolic dysfunction or heart failure, structural or valvular heart disease, and duration of AF.

Mechanisms of Recurrence
Mechanisms of recurrence were reported in 5 studies. 16,17,19,21,22 In these 5 studies, 3 of which reported data exclusively from PAF patients, PV reconnection was noted in 417 of 423 patients who underwent repeat ablation; the rate of ≥1 PV reconnection was 97.2% (95% CI 92.7% to 99.0%). Insufficient data were available in these studies to report on the proportion of PVs undergoing reconnection or to permit stratification of reconnection rates based on type of AF or ablation strategy or technology.

Periprocedural Complications
Periprocedural complications were reported heterogeneously across studies. Reported complications are shown in Table 4. Serious complications noted in the studies included cerebrovascular accident, PV stenosis, atrioesophageal fistula, and cardiac tamponade. Overall rates of serious complications appeared to be low (Table 4).

Publication Bias
To evaluate the included studies for publication bias, we constructed funnel plots for 12-month success, late success, and multiple-procedure late success (Appendix). There was some suggestion of an association between the log odds of  success and the standard error of the log odds, particularly for late success, with larger, more precise studies tending to report higher success rates.

Discussion
In this systematic review, we found that AF ablation may lead to long-term freedom from atrial arrhythmia that is maintained at follow-up of ≥3 years. The principal findings were that (1) a single ablation procedure may be sufficient to achieve freedom from atrial arrhythmia in 50% of patients, although substantial heterogeneity was noted (I 2 ≥50%); (2) multiple procedures will be required to achieve control of AF in many patients, but 80% of patients will achieve long-term freedom from atrial arrhythmia; and (3) although there is an incidence of late recurrence in initially successfully ablated patients, there is relative stability of arrhythmia-free survival at late-term follow-up of 5 years.

Long-term Ablation Efficacy
Until very recently, few data have been available on AF ablation outcomes beyond 3 years after the index procedure. Indeed, current guidelines define "very late" recurrence as atrial arrhythmia >1 year after ablation and recommend follow-up until 2 years. 2 In our study, we addressed the issue of AF ablation outcomes at ≥3 years of follow-up. We used drug-free success data, where available, and follow-up intensity was determined by individual study design. A particular consideration in a study such as this one is that the studies were reports generated at highly experienced referral centers with considerable experience in the application of AF abation. Ablation procedures were performed by experienced operators in selected AF patients. An interesting observation in our study was that the funnel plots of procedure outcomes in larger studies tended to have higher rates of success, perhaps reflecting an experience effect. However, an alternative interpretation raised by these data is that of ascertainment bias, with the possibility that different results would be achieved for procedures undertaken in lowervolume, less-experienced clinical centers. Single-procedure ablation success was achieved in 50% of patients, although, importantly, there was significant heterogeneity in single-procedure outcomes in the included studies. With the inclusion of multiple procedures, 80% of patients achieved long-term freedom from atrial arrhythmia.
To evaluate the long-term stability of AF ablation success, we evaluated the annualized arrhythmia-free success of AF ablation from 1 to 5 years. Both single-and multiple-procedure success rates showed relative stability at >3 years after index ablation. Including multiple procedures, 80% of patients in the included studies were free of atrial arrhythmia at long-term follow-up. These data combined suggest that medium-term ablation success appears to portend relative stability of longterm efficacy of AF ablation but with a significant residual risk of recurrence affecting a significant minority of patients.

Impact of Type of AF
The results of our study confirm previous data on the importance of AF classification to outcomes after AF ablation. The PAF ablation cohort had superior single-procedure success compared with NPAF patients. A minority of NPAF patients in the current study achieved rhythm control with a single procedure, with long-term rhythm control typically requiring multiple procedures. In our study, NPAF singleprocedure outcomes were surprisingly statistically not different compared with PAF outcomes. It appears that this unexpected finding is related to the substantial between-study heterogeneity of procedural outcomes in both PAF and NPAF cohorts, as NPAF outcomes were significantly worse than those for PAF patients in all studies reporting success data for both types of patients. It should also be emphasized that longterm outcome data for NPAF patients that were available were derived from a subset of included studies. Importantly, 80% of PAF and NPAF patients achieved durable sinus rhythm control at long-term follow-up, with the inclusion of multiple procedures. Few studies reported long-term outcomes beyond 3 years in NPAF patients, suggesting that further data may be required to definitively assess the long-term efficacy of ablation in this group.

Mechanisms of Recurrence
The mechanism of recurrence in included studies was overwhelmingly related to PV reconnection, derived from the subset of studies reporting procedural data on this outcome. High rates of PV reconnection appear to occur in both PAF and NPAF patients. This would suggest that improvement in overall outcomes of the procedure may require improvements in both technique and technology. The extent of data available did not allow identification of other factors that may contribute to recurrence in these studies. Nevertheless, a number of studies have demonstrated the importance of patient substrate factors including type of AF, left atrial diameter, structural heart disease, left ventricular dysfunction, hypertension, obesity, and obstructive sleep apnea. [28][29][30][31] Clinical Parameters Related to Between-Study Heterogeneity In the current study, substantial heterogeneity was observed in single-procedure outcome (Figure 2), with a significant risk of late recurrence after index ablation ( Figure 4A). The wide disparity in reported success rates between the included studies is in itself an outcome of significant importance. We explored possible reasons for recurrence with a metaregression analysis using age, sex, percentage of PAF patients, left atrial diameter, and mean left ventricular ejection fraction as moderator variables. None of the study variables was found to be statistically predictive of short-or late-term success outcomes after AF ablation. At the study level, a wide array of covariates were found to be associated with ablation outcomes ( Table 3), suggesting that further information is required to precisely predict factors related to prognosis in individual patients. Although we were not able to provide a statistical explanation for between-study heterogeneity, we suggest that several areas of clinical difference between studies may account for differences in outcomes: (1) differences in patient population receiving ablation, (2) differences in technique and technology used during ablation, (3) differences in the use and reporting of antiarrhythmic drug therapy after ablation, (4) follow-up frequency and intensity, (5) definitions of procedural success or failure, and (6) differences in the availability and timing of repeat procedures. Standardization of reporting of these clinical parameters is an area that may need to be addressed in future revisions to current clinical guidelines. An area that may require particular emphasis is the need for longterm follow-up of AF ablation patients, which we believe may need to be extended beyond the 12-month window postprocedure recommended in current clinical guidelines. 2

Comparisons to Previous Meta-analyses
Over the years, a number of studies have addressed the shorter-term outcomes, 32-34 predictors of recurrence, 28,29 or impact of specific types of ablation strategy. 35,36 The current study, for the first time, addresses the significant clinical issue of the long-term clinical outcomes of AF ablation, which has only recently become possible due to the availability of longterm clinical follow-up data after AF ablation.

Clinical Implications
The long-term results of AF ablation are critically important not only for individual patient prognosis and clinical decision making but also for determining the role of reimbursement policy for the procedure. The data presented in the current study suggest that long-term freedom of atrial arrhythmia can be achieved in the majority of AF cases, taking into account the need for multiple procedures in a significant proportion of patients.

Study Limitations
The results of this report were compiled using meta-analyses of primarily nonrandomized observational data, rather than randomized controlled trial data, with significant limitations in study quality, thereby having some risk of bias. 5,37 The technique of meta-analysis was originally developed for prospectively conducted randomized controlled trials, which represent the highest quality of evidence evaluating the efficacy of clinical interventions. In recent years, however, meta-analysis has become accepted in the literature to aggregate results from observational data, to facilitate synthesis of available evidence and generation of new hypotheses. 37,38 In the case of AF ablation, the procedure is relatively new, with significant ongoing innovation in technology and technique, necessitating the inclusion of case series as well as randomized controlled trial data. In addition, the limitation of included data to published studies may lead to a risk of publication or "file drawer" bias, which may favor the publication of studies showing an improvement in outcomes. 39 Significant heterogeneity was identified, although lack of similarity in reporting of outcome and moderator variables limited the opportunity for more detailed subgroup analyses. However, we specifically acknowledge the limitations and inherent bias that may occur with this approach. A further limitation of our study is that periprocedural complications, a critical consideration in evaluating the risks and benefits of the procedure, were variably reported in terms of level of detail, and in some studies not reported at all. The conclusions of our study are therefore predicated on explicit acknowledgment of these possible limitations in the study design.

Conclusions
The data presented in this review showed encouraging rates of success at long-term follow-up after early experience with catheter ablation of AF. Although single-procedure outcomes were associated with significant heterogeneity, with the inclusion of multiple procedures, long-term freedom from atrial arrhythmia was achievable in the majority of patients.