Optimization of the hot balloon ablation strategy using real-time pulmonary vein potential monitoring.

INTRODUCTION: Optimal radiofrequency-generated thermal energy applications have not been established for hot balloon ablation (HBA) systems. We investigated the feasibility of real-time monitoring of pulmonary vein (PV) potentials and optimal time-to-isolation (TTI)-guided application strategies in HBAs. METHODS AND RESULTS: Real-time monitoring of PV potentials was performed using a four-electrode unidirectional catheter in 34 consecutive patients. Acute isolation was achieved when PV potentials disappeared during HBAs and were undetected by high-resolution mapping. The TTI, the difference between TTI and the time to reach target temperature (TTRT), and ablation time after isolation were examined for 177 applications in 136 PVs. Real-time monitoring of PV activity was obtained in 167 out of 177 applications (94.3%) and acute isolation was achieved in 97 out of 177 (54.8%) applications. TTI-TTRT was significantly shorter, and ablation times after isolation were significantly longer in the acute isolation group than in the other groups. TTI-TTRT <4.5 seconds and TTIs <33.5 seconds predicted acute isolation (sensitivity 74.2%, specificity 88.4%; sensitivity 76.3%, specificity 76.7%, respectively). Ablation time after isolation >148.5 seconds (sensitivity 93.6%, specificity 51.7%) and >120.5 seconds (sensitivity 84.0%, specificity 78.6%) predicted acute isolation in superior PVs and inferior PVs, respectively. CONCLUSIONS: Real-time assessment of PV isolation can be achieved during HBAs with single-shot techniques. (TTI-TTRT)s <4.5 seconds and TTIs <33.5 seconds predicted for acute isolation. Ablation time after isolation >148.5 seconds in superior PVs and >120.5 seconds in inferior PVs were effective application durations.

Optimal Force-Time Integral for Pulmonary Vein Isolation According to Anatomical Wall Thickness Under the Ablation Line.

BACKGROUND: Low contact force and force-time integral (FTI) during catheter ablation are associated with ineffective lesion formation, whereas excessively high contact force and FTI may increase the risk of complications. We sought to evaluate the optimal FTI for pulmonary vein (PV) isolation based on atrial wall thickness under the ablation line. METHODS AND RESULTS: Contact force parameters and FTI during anatomical ipsilateral PV isolation for atrial fibrillation and atrial wall thickness were assessed retrospectively in 59 consecutive patients for their first PV isolation procedure. The PV antrum was divided into 8 segments, and the wall thickness of each segment under the ablation line was determined using multidetector computed tomography. The FTI for each ablation point was divided by the wall thickness of the PV antrum segment where each point was located to obtain FTI/wall thickness. In total, 5335 radiofrequency applications were delivered, and 85 gaps in PV isolation ablation lines and 15 dormant conductions induced by adenosine were detected. The gaps or dormant conductions were significantly associated with low contact force, radiofrequency duration, FTI, and FTI/wall thickness. Among them, FTI/wall thickness had the best prediction value for gaps or dormant conductions by receiver operating characteristic curve analysis. FTI/wall thickness of <76.4 gram-seconds per millimeter (gs/mm) predicted gaps or dormant conductions with sensitivity (88.0%) and specificity (83.6%), and FTI/wall thickness of <101.1 gs/mm was highly predictive (sensitivity 97.0%; specificity 69.6%). CONCLUSIONS: FTI/wall thickness is a strong predictor of gap and dormant conduction formation in PV isolation. An FTI/wall thickness ≈100 gs/mm could be a suitable target for effective ablation.