IEEE Trans Biomed Eng. 2021 Mar;68(3):914-925. doi: 10.1109/TBME.2020.2990655. Epub 2021 Feb 18.
Atrial flutter (AFl) is a common arrhythmia that can be categorized according to different self-sustained electrophysiological mechanisms. The non-invasive discrimination of such mechanisms would greatly benefit ablative methods for AFl therapy as the driving mechanisms would be described prior to the invasive procedure, helping to guide ablation. In the present work, we sought to implement recurrence quantification analysis (RQA) on 12-lead ECG signals from a computational framework to discriminate different electrophysiological mechanisms sustaining AFl.
20 different AFl mechanisms were generated in 8 atrial models and were propagated into 8 torso models via forward solution, resulting in 1,256 sets of 12-lead ECG signals. Principal component analysis was applied on the 12-lead ECGs, and six RQA-based features were extracted from the most significant principal component scores in two different approaches: individual component RQA and spatial reduced RQA.
In both approaches, RQA-based features were significantly sensitive to the dynamic structures underlying different AFl mechanisms. Hit rate as high as 67.7% was achieved when discriminating the 20 AFl mechanisms. RQA-based features estimated for a clinical sample suggested high agreement with the results found in the computational framework.
RQA has been shown an effective method to distinguish different AFl electrophysiological mechanisms in a non-invasive computational framework. A clinical 12-lead ECG used as proof of concept showed the value of both the simulations and the methods.
The non-invasive discrimination of AFl mechanisms helps to delineate the ablation strategy, reducing time and resources required to conduct invasive cardiac mapping and ablation procedures.
心房颤动(AFl)是一种常见的心律失常,可以根据不同的自维持电生理机制进行分类。这种机制的非侵入性区分将极大地有益于 AFl 治疗的消融方法,因为在侵入性程序之前将描述驱动机制,有助于指导消融。在本工作中,我们试图在计算框架中对 12 导联心电图信号实施递归定量分析(RQA),以区分维持 AFl 的不同电生理机制。
在 8 个心房模型中生成了 20 种不同的 AFl 机制,并通过正向解将其传播到 8 个体干模型中,从而产生了 1256 组 12 导联心电图信号。对 12 导联心电图进行主成分分析,并从两种不同方法中最显著的主成分得分中提取 6 个基于 RQA 的特征:单个成分 RQA 和空间简化 RQA。
在两种方法中,基于 RQA 的特征对不同 AFl 机制下的潜在动态结构均具有高度敏感性。当区分 20 种 AFl 机制时,达到了高达 67.7%的命中率。对临床样本进行的 RQA 特征估计表明,与计算框架中的结果具有高度一致性。
RQA 已被证明是一种在非侵入性计算框架中区分不同 AFl 电生理机制的有效方法。作为概念验证使用的临床 12 导联心电图显示了模拟和方法的价值。
AFl 机制的非侵入性区分有助于描绘消融策略,减少进行侵入性心脏映射和消融程序所需的时间和资源。
