Feasibility of Machine Learned Intracardiac Electrograms to Predict Postinfarction Ventricular Scar Topography.

IF 9.8 1区医学 Q1 CARDIAC & CARDIOVASCULAR SYSTEMS

Circulation. Arrhythmia and electrophysiology Pub Date : 2025-07-01 Epub Date: 2025-06-13 DOI:10.1161/CIRCEP.124.013611

Kasun De Silva, Timothy G Campbell, Richard G Bennett, Samual Turnbull, Ashwin Bhaskaran, Robert D Anderson, Christopher Davey, Alexandra K O'Donohue, Aaron Schindeler, Dinesh Selvakumar, Yasuhito Kotake, Chi-Jen Hsu, James J H Chong, Eddy Kizana, Saurabh Kumar

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引用次数: 0

Abstract

Background: Accurate delineation of scar patterns is valuable for guiding catheter ablation of ventricular tachycardia. We hypothesized that scar and its pattern of distribution can be determined from intracardiac electrograms using computational signal processing and that further improvements in classification can be achieved with a convolutional neural network.

Methods: A total of 5 sheep underwent anteroseptal infarction (plus 1 healthy control) with electroanatomic mapping (129±12 days post-infarct). A whole-heart histological model of the postinfarction scar was created and coregistered to ventricular electrograms. Electrograms were matched to scar pattern categories; no scar, at least endocardial scar: at least intramural scar (intramural scar sparing the endocardium), or epicardial-only scar (epicardial scar sparing the endocardium/intramural space). A suite of signal-processing features was extracted from bipolar electrograms. Furthermore, bipolar and unipolar electrograms were used to train a time series convolutional neural network (InceptionTime).

Results: A total of 11 551 electrograms were matched to 451 biopsies. Bipolar and unipolar voltage alone were poor classifiers of scar patterns. For each of the scar labels, 20 bipolar electrogram features (predominantly within the frequency domain) yielded an area under the curve of 0.815, 0.810, 0.704, and 0.681 to predict no scar, at least endocardial scar, at least intramural scar, and epicardial-only scar, respectively. Substantial improvement was achieved with a convolutional neural network trained on unipolar electrograms: areas under the curve and accuracy (averaged across wavefronts) were 0.977 and 0.929 for no scar, 0.970 and 0.919 for at least endocardial scar, 0.909 and 0.959 for at least intramural scar and 0.926 and 0.958 for epicardial-only scar.

Conclusions: Convolutional neural network-derived analysis of unipolar electrogram data has excellent predictive value for determination of scar patterns. Computational analyses of electrogram data beyond voltage and other time-domain features are necessary to improve the identification of arrhythmogenic sites in the ventricle.

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机器学习心内电图预测梗死后心室瘢痕形貌的可行性。

背景：准确描绘瘢痕形态对指导导管消融室性心动过速有价值。我们假设疤痕及其分布模式可以通过计算信号处理从心内电图中确定，并且可以通过卷积神经网络进一步改进分类。方法：5只羊（外加1只健康对照）在梗死后129±12天进行电解剖作图。建立梗死后瘢痕的全心脏组织学模型，并与心室电图共登记。电图与疤痕类型相匹配；无瘢痕，至少心内膜瘢痕：至少壁内瘢痕（壁内瘢痕保留心内膜），或仅心外膜瘢痕（心外膜瘢痕保留心内膜/壁内空间）。从双极电图中提取了一套信号处理特征。此外，双极和单极电图被用来训练时间序列卷积神经网络（InceptionTime）。结果：与451例活检相匹配的电图共11 551张。双极电压和单极电压单独是瘢痕类型的较差分类。对于每个疤痕标签，20个双极电图特征（主要在频域内）产生的曲线下面积分别为0.815、0.810、0.704和0.681，预测无疤痕、至少心内膜疤痕、至少壁内疤痕和仅心外膜疤痕。在单极电图上训练卷积神经网络取得了显著的改善：无疤痕的曲线下面积和准确度（跨波前平均）分别为0.977和0.929，至少心内膜疤痕为0.970和0.919，至少壁内疤痕为0.909和0.959，仅心外膜疤痕为0.926和0.958。结论：基于卷积神经网络的单极电图分析对疤痕类型的确定具有很好的预测价值。计算分析心电图数据超越电压和其他时域特征是必要的，以提高识别心律失常的心室部位。

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

Circulation. Arrhythmia and electrophysiology 医学-心血管系统

CiteScore

13.70

自引率

4.80%

发文量

187

审稿时长

4-8 weeks

期刊介绍： Circulation: Arrhythmia and Electrophysiology is a journal dedicated to the study and application of clinical cardiac electrophysiology. It covers a wide range of topics including the diagnosis and treatment of cardiac arrhythmias, as well as research in this field. The journal accepts various types of studies, including observational research, clinical trials, epidemiological studies, and advancements in translational research.