Karli Gillette, Benjamin Winkler, Stefan Kurath-Koller, Daniel Scherr, Edward J Vigmond, Markus Bär, Gernot Plank
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We first introduce a cardiac model of electrophysiology that was specifically tailored to represent antegrade APs in the form of a short atrio-ventricular bypass tract. Locations of antegrade APs were then automatically swept across both ventricles in the virtual model to generate a synthetic ECG database consisting of 9271 signals. Regional grouping of antegrade APs revealed overarching morphological patterns originating from diverse cardiac regions. We then applied variance-based sensitivity analysis relying on polynomial chaos expansion on the ECG database to mathematically quantify how variation in AP location and timing relates to morphological variation in the 12 lead ECG. We utilized our mechanistic virtual model to showcase limitations of AP localization using standard ECG-based algorithms and provide mechanistic explanations through exemplary simulations. Our findings highlight the potential of virtual models of cardiac electrophysiology not only to deepen our understanding of the underlying mechanisms of Wolff-Parkinson-White syndrome but also to potentially enhance the diagnostic accuracy of ECG-based algorithms and facilitate personalized treatment planning.","PeriodicalId":11720,"journal":{"name":"EP Europace","volume":"12 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-09-11","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"A computational study on the influence of antegrade accessory pathway location on the 12-lead electrocardiogram in Wolff-Parkinson-White syndrome\",\"authors\":\"Karli Gillette, Benjamin Winkler, Stefan Kurath-Koller, Daniel Scherr, Edward J Vigmond, Markus Bär, Gernot Plank\",\"doi\":\"10.1093/europace/euae223\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Wolff-Parkinson-White syndrome is a cardiovascular disease characterized by abnormal atrio-ventricular conduction facilitated by accessory pathways (APs). 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引用次数: 0
摘要
沃尔夫-帕金森-怀特综合征是一种心血管疾病,其特征是由附属通路(AP)引起的房室传导异常。有创导管消融 AP 是主要的治疗方式。AP 的准确定位对成功消融至关重要,但目前基于 12 导联心电图(ECG)的诊断算法往往难以精确确定 AP 的位置。为了深入了解当前诊断算法中观察到的定位失败的内在机制,我们采用了一个虚拟心脏模型来阐明 AP 位置与心电图形态之间的关系。我们首先引入了一个心脏电生理学模型,该模型是专门为表示短的房室旁路束形式的逆行 AP 而定制的。然后,在虚拟模型中自动扫描两个心室的逆行 AP 位置,生成由 9271 个信号组成的合成心电图数据库。对前向 APs 进行区域分组显示了源自不同心脏区域的总体形态模式。然后,我们利用多项式混沌扩展对心电图数据库进行了基于方差的敏感性分析,从数学角度量化了 AP 位置和时间的变化与 12 导联心电图形态变化的关系。我们利用机理虚拟模型展示了使用基于心电图的标准算法进行 AP 定位的局限性,并通过示例模拟提供了机理解释。我们的研究结果凸显了心脏电生理学虚拟模型的潜力,它不仅能加深我们对沃尔夫-帕金森-怀特综合征内在机制的理解,还能潜在地提高基于心电图算法的诊断准确性,促进个性化治疗计划的制定。
A computational study on the influence of antegrade accessory pathway location on the 12-lead electrocardiogram in Wolff-Parkinson-White syndrome
Wolff-Parkinson-White syndrome is a cardiovascular disease characterized by abnormal atrio-ventricular conduction facilitated by accessory pathways (APs). Invasive catheter ablation of the AP represents the primary treatment modality. Accurate localization of APs is crucial for successful ablation outcomes, but current diagnostic algorithms based on the 12 lead electrocardiogram (ECG) often struggle with precise determination of AP locations. In order to gain insight into the mechanisms underlying localization failures observed in current diagnostic algorithms, we employ a virtual cardiac model to elucidate the relationship between AP location and ECG morphology. We first introduce a cardiac model of electrophysiology that was specifically tailored to represent antegrade APs in the form of a short atrio-ventricular bypass tract. Locations of antegrade APs were then automatically swept across both ventricles in the virtual model to generate a synthetic ECG database consisting of 9271 signals. Regional grouping of antegrade APs revealed overarching morphological patterns originating from diverse cardiac regions. We then applied variance-based sensitivity analysis relying on polynomial chaos expansion on the ECG database to mathematically quantify how variation in AP location and timing relates to morphological variation in the 12 lead ECG. We utilized our mechanistic virtual model to showcase limitations of AP localization using standard ECG-based algorithms and provide mechanistic explanations through exemplary simulations. Our findings highlight the potential of virtual models of cardiac electrophysiology not only to deepen our understanding of the underlying mechanisms of Wolff-Parkinson-White syndrome but also to potentially enhance the diagnostic accuracy of ECG-based algorithms and facilitate personalized treatment planning.