心房颤动消融计算机模拟的经验教训。
Lessons from computer simulations of ablation of atrial fibrillation.
作者信息
Jacquemet Vincent
机构信息
Department of Molecular and Integrative Physiology, Faculty of Medicine, Université de Montréal, Montréal, QC, Canada.
Centre de Recherche, Hôpital du Sacré-Cœur, Montréal, QC, Canada.
出版信息
J Physiol. 2016 May 1;594(9):2417-30. doi: 10.1113/JP271660. Epub 2016 Mar 4.
Abstract
This paper reviews the simulations of catheter ablation in computer models of the atria, from the first attempts to the most recent anatomical models. It describes how postulated substrates of atrial fibrillation can be incorporated into mathematical models, how modelling studies can be designed to test ablation strategies, what their current trade-offs and limitations are, and what clinically relevant lessons can be learnt from these simulations. Drawing a parallel between clinical and modelling studies, six ablation targets are considered: pulmonary vein isolation, linear ablation, ectopic foci, complex fractionated atrial electrogram, rotors and ganglionated plexi. The examples presented for each ablation target illustrate a major advantage of computer models, the ability to identify why a therapy is successful or not in a given atrial fibrillation substrate. The integration of pathophysiological data to create detailed models of arrhythmogenic substrates is expected to solidify the understanding of ablation mechanisms and to provide theoretical arguments supporting substrate-specific ablation strategies.
摘要
本文回顾了在心房计算机模型中进行导管消融的模拟研究,从最初的尝试到最新的解剖模型。它描述了如何将假定的房颤基质纳入数学模型,如何设计建模研究来测试消融策略,它们目前的权衡和局限性是什么,以及可以从这些模拟中吸取哪些临床相关的经验教训。通过将临床研究和建模研究进行类比,考虑了六个消融靶点:肺静脉隔离、线性消融、异位灶、复杂碎裂心房电图、转子和神经节丛。针对每个消融靶点给出的例子说明了计算机模型一个主要优点,即能够确定在给定的房颤基质中一种治疗方法成功或失败的原因。整合病理生理数据以创建心律失常基质的详细模型,有望加深对消融机制的理解,并提供支持基于基质的消融策略的理论依据。
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