Does high power output/short duration radiofrequency ablation reduce procedure time compared to conventional low power/long duration ablation in patients with atrial fibrillation?
High power, short duration radiofrequency ablation for pulmonary vein isolation significantly reduces procedure and fluoroscopy times while maintaining similar efficacy to conventional ablation.
AIMS: Segmental pulmonary vein (PV) isolation by radiofrequency (RF) catheter ablation has become a curative therapy for atrial fibrillation (AF). However, the long procedure time limits the wide application of this procedure. The aim of the current study was to compare a novel ablation technique with a high power output and short application time vs. a conventional technique using a low power output and long application time. METHODS AND RESULTS: The study included 90 consecutive patients (age 53+/-10 years; 66 men). Segmental PV isolation was performed by irrigated RF catheter ablation in both groups. In the conventional group (Group 1, 45 patients), the power output was limited to 30 W with a target temperature of 50 degrees C and an RF preset duration of 120 s. In the novel group (Group 2, 45 patients), the maximum power output was preset to 45 W, with a target temperature of 55 degrees C and duration of 20 s. In Group 2, a significant reduction in the PV isolation time (127+/-57 vs. 94+/-33 min, P<0.02), mean fluoroscopy time (73+/-23 vs. 55+/-16 min, P<0.001), and radiation dose was observed. According to the application time and number, Group 2 showed a reduction in RF application time, but a higher number of RF applications were required for creation of complete PV isolation. During a mean follow-up of 15+/-7 months, a total of 74% of patients in Group 1 and 76% of patients in Group 2 demonstrated stable SR. CONCLUSION: Segmental PV isolation using a high power output and short application time is safe and effective in PV isolation in patients with AF. This technique can significantly reduce the procedure and fluoroscopy time compared with a low-power output technique.
Nilsson et al. (Tue,) studied this question.