A PFA index was developed that accurately predicted lesions ≥4 mm in depth and ≥5 mm in width with 94% accuracy using specified energy delivery parameters.
Does a PFA index combining bursts, contact force, and impedance change predict therapeutic lesion dimensions in an acute swine model?
A novel PFA index incorporating burst number, contact force, and impedance change accurately predicts therapeutic lesion dimensions in a preclinical model.
Tasa de eventos absoluta: 0% vs 0%
Abstract Background Pulsed field ablation (PFA) is a novel energy modality; factors predicting lesion diameter and transmurality are not well understood. Realtime integration of factors associated with lesion formation is crucial to maximizing procedural efficacy and efficiency. Purpose To identify individual factors that predict PFA lesion growth and to derive a multivariable model to predict lesions suitable for contiguous and transmural atrial ablation using a force sensing flexible, irrigated tip catheter. Methods In an acute swine model, 152 ventricular lesions were created with PFA using the TactiFlex SE PFA catheter. The number of bursts and contact forces were varied. A multifactorial probabilistic model was fitted to lesion dimensions and optimized using an ROC approach to predict likelihood of a therapeutic atrial lesion (depth ≥4 mm, width ≥ 5mm; A). Results The 3 most predictive factors to attain the above dimensions were number of bursts delivered, percentage of time that the contact force is at least 5g, and change in local bipolar tissue impedance. The incorporation of these factors into a model, the PFA index (PI), scored 0-100, resulted in high prediction accuracy for applications of an R-wave gated 5-burst, 2400V waveform (AUC=94%, n=85; B). PI values increase across individual bursts (C, D) and successive applications at the same site (E, F). The mean PI value for 5 bursts delivered with a mean force ≥ 5g was 70 (n=48), and the median depth was 5.2 mm with a median absolute deviation (MAD) of 2.3 mm (N=9). 94% of lesions (47/50) with PI ≥ 70 met the dimensional criteria. The median depth at 10 bursts (2 applications) delivered with a mean force ≥ 5g was 6.8 mm, with a MAD of 1.75 mm (N=12). A PI of ≥ 90 was obtained after at least 10 bursts delivered with a mean force ≥ 5g in 93% of lesions (50/54). Conclusions The PI algorithm combines PFA bursts, contact force, and local impedance change to accurately predict lesions sufficient for pulmonary vein isolation and linear ablation. Prospective studies are planned to confirm the impact on procedural outcomes.Figure
Friedman et al. (Sat,) reported a other. A PFA index was developed that accurately predicted lesions ≥4 mm in depth and ≥5 mm in width with 94% accuracy using specified energy delivery parameters.