Does mapping-integrated pulsed-field ablation (PFA) demonstrate high procedural efficiency, safety, and a short learning curve in patients undergoing first-time pulmonary vein isolation for atrial fibrillation?
Mapping-integrated pulsed-field ablation for pulmonary vein isolation is highly effective and safe acutely, featuring a steep learning curve that plateaus in procedural efficiency after just five cases.
Abstract Background Real-world evidence assessing the learning curve and procedural efficiency of the pentaspline pulsed-field ablation (PFA) system with novel mapping-integrated capabilities remains limited. Purpose To evaluate the learning curve associated with mapping-integrated PFA technology and to assess its impact on procedural efficiency and acute procedural outcomes in pulmonary vein isolation (PVI). Methods This multicenter observational study included all consecutive patients undergoing atrial fibrillation (AF) ablation using Farapulse PFA integrated with a novel mapping system (Faraview) across 18 centers. Only patients undergoing their first PVI procedure were analyzed; cases involving additional ablation targets were excluded. Procedural parameters were analyzed in relation to operator experience. Operators were asked to predefine their ablation strategy before each case and to document any deviations from the planned approach and the rationale for these modifications. Data are presented as median interquartile range. Results A total of 244 patients were included (paroxysmal AF: 88.1%). Of these, 171 (70.1%) procedures were performed by operators with prior experience of 10 PFA cases and were included in the learning curve analysis. Total cath lab utilization, skin-to-skin, and fluoroscopy times were 10080–120 min, 6050–75 min, and 128–17min, respectively. Acute PVI was achieved in 100% of patients, with a median of 4438–54 PFA applications. The learning curve was steep, with significant improvements observed after only five cases per operator, while no further improvement was detected beyond ten cases: cath lab utilization: 11090–150 min (first 5 cases) vs. 9570–120 min (after first 5 cases), p=0.011; skin-to-skin time: 7565–95 min vs. 6050–70 min, p=0.001, fluoroscopy time: 1611–19 min vs. 118–16 min, p=0.009. No differences were found in the number of PFA deliveries (4238–54 vs. 4438–54, p=0.876). The actual number of PFA deliveries was higher than initially planned (3232–40 vs. 4438–54; p0.001; difference: 62–13). In 8.2% of cases, fewer deliveries were performed than planned; in 11.1%, the number matched the plan; and in 80.7%, more deliveries were delivered than initially intended. A standard PVI strategy was used in 82 cases (48.0%), while 69 cases (52.0%) included an additional peri-PV lesion set: consolidative in 28 (31.5%), extensive in 24 (27.0%), and mixed in 31 (34.8%) procedures. No major complications were reported. No clinically relevant hemolysis, stroke, pericarditis or acute ST-T change was observed. Conclusion In this first multicenter real-world experience, the pentaspline mapping-integrated PFA system demonstrated high procedural efficiency, safety, and acute effectiveness in both paroxysmal and persistent AF patients. The learning curve was remarkably short, with significant improvements in procedural metrics observed after only a few cases.
Mitacchione et al. (Mon,) studied this question.