Evaluation of Activation Times in Ventricular Model with Realistic Geometry and Conduction System

2019 12th International Conference on Measurement Pub Date : 2019-05-27 DOI:10.23919/MEASUREMENT47340.2019.8779956

E. Cocherová, J. Svehlíková, M. Tysler

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Abstract

The goal of the article was to design a model of ventricles with a realistic patient geometry and with a proper representation of the conduction system of ventricles that enables to reach the total activation time of the whole ventricles in the physiological range of about 80 to 120 ms. Electrical activation was started in one region or in nine starting regions. The conduction system (branches and Purkinje fibers) was modeled as an endocardial layer with higher conductivity and a set of nine starting regions representing the earliest activated areas. The monodomain model of electrical activation propagation with the local tissue properties defined by modified FitzHugh-Nagumo equations was numerically solved in Comsol Multiphysics environment. The total activation time of the whole ventricles was evaluated for all models. Pathological total activation times of the whole ventricles higher than 120 ms were obtained for models with activation starting only in one region (ectopic beats). Realistic total activation time was obtained for model incorporating an endocardial conducting layer with nine starting regions representing the conduction system.

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用真实几何和传导系统评价心室模型的激活次数

本文的目标是设计一个具有真实患者几何形状的心室模型，并具有心室传导系统的适当表示，使整个心室的总激活时间在生理范围内约为80至120 ms。电激活在一个区域或九个启动区域开始。传导系统(分支和浦肯野纤维)被建模为具有较高电导率的心内膜层和一组代表最早激活区域的9个起始区域。利用修正的FitzHugh-Nagumo方程对具有局部组织特性的电激活传播单域模型在Comsol Multiphysics环境下进行了数值求解。评估各模型全心室总激活时间。仅从一个区域(异位搏)开始激活的模型，整个心室的病理总激活时间大于120 ms。采用心内膜传导层和代表传导系统的九个起始区域的模型得到了真实的总激活时间。

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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2019 12th International Conference on Measurement

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