折返性房性心动过速消融过程中行为的简单机制。

A simple mechanism underlying the behavior of reentrant atrial tachycardia during ablation.

机构信息

Bordeaux University Hospital (CHU), Cardiac Electrophysiology and Cardiac Stimulation Team, IHU Liryc, Electrophysiology and Heart Modeling Institute, Fondation Bordeaux Université, Bordeaux, France; Heart Rhythm Center, Tokyo Medical and Dental University, Tokyo, Japan.

出版信息

Heart Rhythm. 2019 Apr;16(4):553-561. doi: 10.1016/j.hrthm.2018.10.031. Epub 2018 Oct 31.

DOI:10.1016/j.hrthm.2018.10.031

PMID:30389441

Abstract

BACKGROUND

Ablation of complex atrial tachycardias (ATs) is difficult.

OBJECTIVE

The purpose of this study was to elucidate a mechanism underlying the behavior of ATs during ablation and to create an algorithm to predict it.

METHODS

An algorithm predicting termination/conversion of AT and the second AT circuit associated with the ablation site was developed from 52 index reentrant AT high-resolution activation maps in 45 patients (retrospective phase). First, the wavefront collision site was identified. Then, the N or N-1 beat was defined for each collision associated with the ablation site. When the AT involved wavefront collision solely between N-1/N-1 (N/N) beats, the AT would terminate during ablation. Conversely, when the AT included wavefront collision between N/N-1 beats, the index AT would convert to a second AT. The algorithm was then prospectively tested in 172 patients with 194 ATs (127 anatomic macroreentrant ATs [AMATs], 44 non-AMATs, 23 multiple-loop ATs).

RESULTS

Accuracy in predicting AT termination/conversion and the second AT circuit was 95.9% overall, 96.1% in AMATs, 95.5% in non-AMATs, and 95.7% in multiple-loop ATs. Median (25th-75th percentile) absolute variation between predicted and actually observed cycle length of the second AT was 6 (4-9) ms. Prediction failure occurred in 8 ATs; either the second AT used an unmapped chamber or structure in the index map (n = 7) or a line of block was misinterpreted as very slow conduction in the index map (n = 1).

CONCLUSION

A simple mechanism underlies the behavior of ATs during ablation, even in complex ATs. With a simple algorithm using high-resolution mapping, AT termination/conversion and the second AT circuit and cycle length may be predicted from the index activation map.

摘要

背景

消融复杂的房性心动过速（AT）较为困难。

目的

本研究旨在阐明 AT 消融过程中行为的发生机制，并创建一种预测其发生的算法。

方法

从 45 例患者的 52 例索引折返性 AT 高分辨率激活图中（回顾性阶段），开发出一种预测 AT 终止/转换和与消融部位相关的第二 AT 环的算法。首先，确定波阵面碰撞部位。然后，为与消融部位相关的每个碰撞定义 N 或 N-1 个心搏。当 AT 仅涉及 N-1/N-1（N/N）心搏之间的波阵面碰撞时，AT 将在消融过程中终止。相反，当 AT 包含 N/N-1 心搏之间的波阵面碰撞时，索引 AT 将转换为第二 AT。然后，前瞻性地在 172 例 194 例 AT 患者（127 例解剖性大折返性 AT[AMAT]，44 例非 AMAT，23 例多环 AT）中进行了测试。

结果

预测 AT 终止/转换和第二 AT 环的准确率总体为 95.9%，AMAT 为 96.1%，非 AMAT 为 95.5%，多环 AT 为 95.7%。预测和实际观察到的第二 AT 周期长度之间的绝对差异中位数（25%至 75%）为 6（4-9）ms。8 例 AT 预测失败；第二 AT 使用索引图中未映射的腔室或结构（n=7），或一条阻滞线被错误地解释为索引图中非常缓慢的传导（n=1）。

结论

即使在复杂的 AT 中，AT 消融过程中的行为也有一个简单的机制。通过使用高分辨率标测的简单算法，可以从索引激活图中预测 AT 的终止/转换、第二 AT 环和周期长度。

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折返性房性心动过速消融过程中行为的简单机制。

A simple mechanism underlying the behavior of reentrant atrial tachycardia during ablation.

机构信息

出版信息

BACKGROUND

OBJECTIVE

METHODS

RESULTS

CONCLUSION

背景

目的

方法

结果

结论

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