0029: Redo-ablations of atrial fibrillation: procedural characteristics depending on the choice of cryoenergy or radiofrequency ablation as the first line therapy

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• 作者：Vincent Galand ; ^{vincent.galand35@gmail.com" class="auth_mail" title="E-mail the corresponding author} ; Dominique Pavin ; Jean-Claude Daubert ; Philippe Mabo ; Raphael Martins
• 关键词：atrial fibrillation ; ablation ; cryoablation ; radiofrequency ; redo
• 刊名：Archives of Cardiovascular Diseases Supplements
• 出版年：2016
• 出版时间：January 2016
• 年：2016
• 卷：8
• 期：1
• 页码：72
• 全文大小：54 K

文摘

Pulmonary vein (PV) isolation has become a cornerstone therapy for symptomatic paroxysmal AF refractory to anti-arrhythmic drugs. Nowadays, the most common energies used to achieve PV isolation are cryoenergy and radiofrequency (RF). However, approximately one third of the patients have recurrences, mainly due to PV reconnections.

Little is known about the characteristics of the redo procedure, depending on the choice of the initial energy.

Methods

Patients referred to our center for a RF redo ablation procedure of symptomatic paroxysmal AF (PxAF) between 2010 and 2014 were retrospectively enrolled.

Demographic data and characteristics of the initial ablation, i.e. cryoenergy or RF ablations, were collected. Number and location of PV gaps, and redo characteristics were reviewed.

Results

74 patients scheduled for a redo ablation of AF were included, 38 and 36 using RF or cryoablation for the first procedure, respectively. For the initial ablation, procedural and fluoroscopy times were significantly shorter when using cryoenergy (147.8±52.6 vs. 226.6±64.3 min, p<0.001, and 37.0±17.7 vs. 50.8±22.7 min, p=0.005, respectively). Overall, an identical number of gaps were found during redo procedures of cryo and RF ablations. However, a significantly higher number of gaps were located in the right superior PV (RSPV) for patient first ablated with RF (0.9±1.0 vs. 0.5±0.9, p=0.009). The location of gaps was different, predominantly found in the anterior and superior parts of the left superior PV (LSPV), the anterior and inferior part of the left inferior PV (LIPV), the superior part of the right superior PV (RSPV), and in the postero-inferior part of the right inferior PV (RIPV) when using RF as the initial energy. For patient first ablated with cryoenergy, gaps were predominantly found in the anterior part of the left PV, evenly distributed in the RSPV, and in the postero-inferior part of the RIPV. Although not significant, redo procedures of cryoablations were slightly shorter and needed less RF duration times to achieve PV isolation (160.0±55.7 vs. 175.7±59.1 min, p=NS, and 954.1±796.7vs. 1476.7±1269.6, p=NS).

Conclusion

During redo procedures, gaps location pattern is different for patients first ablated with cryo or RF energy, and RSPV reconnections occur more frequently after RF ablation, probably due to poor contact in this region. Procedural characteristics of the redo ablation are similar.