Feasibility of unipolar signal-guided ablation in creating contiguous lines of conduction block: A proof-of-concept study.

IF 5.6 2区医学 Q1 CARDIAC & CARDIOVASCULAR SYSTEMS

Heart rhythm Pub Date : 2025-05-12 DOI:10.1016/j.hrthm.2025.05.010

Hagai D Yavin, Arwa Younis, Arsalan Derakhshan, Zachary Koch, Alison Krywanczyk, Hayley Bryce, Alexander Sean Esposito, Liad Naveh, Mohamed Kanj, Jakub Sroubek, Oussama Wazni, Pasquale Santangeli, Christine Tanaka-Esposito

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引用次数: 0

Abstract

Background: Modification of the atrial unipolar electrogram (Uni-_EGM) with loss of the near-field negative component in response to radiofrequency (RF) ablation reflects transmural loss of tissue conductivity.

Objective: This study sought to investigate the feasibility of Uni-_EGM morphology-guided RF ablation in generating contiguous, transmural lesions that result in conduction block. This method was compared with ablation guided by standard ablation index parameters.

Methods: In a beating heart swine model, linear transcaval ablation was performed using an irrigated ablation catheter with standard and high-power RF ablation. First, an optimal Uni-_EGM endpoint for predicting a transmural lesion was determined by single RF applications in the smooth and trabeculated portions of the right atrium. We compared termination of RF energy immediately upon observing consistent loss of the negative component (S wave) on the local Uni-_EGM vs extending RF delivery for an additional 3 seconds beyond (U₊₃). Next, linear ablation was achieved with either target ablation index of 400 or Uni-_EGM (U₊₃)-based techniques. The latter method relied upon Uni-_EGM morphology both to direct catheter positioning at sites of contiguous and viable tissue and to titrate RF delivery. Bidirectional block was demonstrated with standard EP pacing maneuvers, high-density activation mapping, and pathology.

Results: Extending RF delivery for 3 additional seconds (U₊₃) after consistent loss of the negative component on the Uni-_EGM proved an optimal endpoint, predicting a transmural lesion with 94% sensitivity and 100% specificity. It was observed that, with increasing distance from site of RF application, the near-field S wave on the Uni-_EGM grows in magnitude whereas an acute current of injury pattern diminishes. Uni-_EGM-based technique resulted in equal efficacy in producing ablation lines with complete bidirectional block compared with target AI-guided ablation. With standard power, Uni-_EGM-guided ablation resulted in significantly less energy delivered per RF application.

Conclusion: We demonstrate that Uni-_EGM can successfully guide ablation yielding conduction lines of block. Uni-_EGM morphology reflects local tissue activation, and its modification in response to thermal injury can serve as an endpoint to ensure adequate yet avoid excess RF delivery. The near-field S wave on the Uni-_EGM indicates viable tissue and, in conjunction with an acute current of injury, identified contiguous, conductive tissue for targeting. Characterization of Uni-_EGM morphology with respect to myocardial electrical properties and understanding its modification in response to injury may lend to the continued pursuit of safer, more effective ablation strategies.

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单极信号引导烧蚀在创建连续传导块线中的可行性：概念验证研究。

背景：射频消融导致心房单极电图（Uni-EGM）近场负分量损失的改变反映了组织电导率的跨壁损失。目的：本研究旨在探讨Uni-EGM形态学引导射频消融（RFA）在产生连续、跨壁病变导致传导阻滞的可行性。并与标准消融指标指导下的消融方法进行了比较。方法：在猪心脏跳动模型中，使用标准和高功率RFA冲洗消融导管进行线性经颅消融。首先，预测跨壁病变的最佳Uni-EGM终点是通过在右心房平滑部分和小梁部分进行单次射频应用确定的。我们比较了在观察到局部单极电图（U+0）上负分量（s波）的一致损失后立即终止射频能量与将射频传输延长3秒（U+3）之后的情况。接下来，通过靶烧蚀指数（AI400）或单极电图（U+3）技术实现线性烧蚀。后一种方法依靠Uni-EGM形态学来直接将导管定位在连续和活组织的位置，并滴定射频输送。通过标准心电起搏、高密度激活图谱和病理检查证实双向阻滞。结果：在Uni-EGM上的阴性成分持续丢失后，延长RF递送3秒（U+3）被证明是最佳终点，预测跨壁病变的灵敏度为94%，特异性为100%。观察到，随着距离射频应用部位的增加，Uni-EGM上的近场s波强度增大，而损伤模式的急性电流减弱。与目标AI引导消融相比，基于Uni-EGM的技术在产生完全双向阻滞的消融线方面效果相同。在标准功率下，Uni-EGM引导消融导致每次射频应用的能量显著减少。结论：我们证明Uni-EGM可以成功地引导块体产生传导线的消融。Uni-EGM形态反映了局部组织的激活，其对热损伤的改变可以作为一个终点，以确保足够但避免过量的射频输送。Uni-EGM上的近场s波表明有活力的组织，并结合急性损伤电流确定了连续的导电组织作为目标。单极电图形态学对心肌电特性的表征，以及对心肌电特性在损伤后的改变的理解，可能有助于继续寻求更安全、更有效的消融策略。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Heart rhythm 医学-心血管系统

CiteScore

10.50

自引率

5.50%

发文量

1465

审稿时长

24 days

期刊介绍： HeartRhythm, the official Journal of the Heart Rhythm Society and the Cardiac Electrophysiology Society, is a unique journal for fundamental discovery and clinical applicability. HeartRhythm integrates the entire cardiac electrophysiology (EP) community from basic and clinical academic researchers, private practitioners, engineers, allied professionals, industry, and trainees, all of whom are vital and interdependent members of our EP community. The Heart Rhythm Society is the international leader in science, education, and advocacy for cardiac arrhythmia professionals and patients, and the primary information resource on heart rhythm disorders. Its mission is to improve the care of patients by promoting research, education, and optimal health care policies and standards.