Evolution of Epicardial Rotors into Breakthrough Waves During Atrial Fibrillation in 3D Canine Biatrial Model with Detailed Fibre Orientation

2021 Computing in Cardiology (CinC) Pub Date : 2021-09-13 DOI:10.23919/cinc53138.2021.9662910

Ataollah Tajabadi, Aditi Roy, M. Varela, O. Aslanidi

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Abstract

Atrial fibrillation (AF) is the most common arrhythmia, but its mechanisms are still unclear. Commonly observed phenomena during AF are epicardial re-entrant drivers (rotors) and breakthrough waves. This study aims to elucidate AF mechanisms, including links between rotors and breakthroughs. We used 3D canine atrial models based on micro-CT reconstruction of biatrial geometry combined with region-specific electrophysiology models. Hence, the 3D model included ionic and structural heterogeneities in the entire atria, with special focus on the right atrium (RA) and pectinate muscles (PM). Results were visualized through 3D atrial membrane voltage maps (VM), 2D isochronal maps (IM), and wave maps (WM). AF episodes were initiated in the atria and were maintained by several epicardial rotors in the PV and RA. Transmural rotors were also seen to propagate through the PM and reemerge at the RA epicardium during these episodes. IM and WM revealed multiple breakthroughs at the region where the PM connect to the RA. The VM simulations, as well as electrogram-based IM and WM, showed that the complex AF patterns seen experimentally can be explained by the interactions of epicardial and transmural rotors.

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具有详细纤维定向的犬双房三维模型心房颤动时心外膜旋翼向突破波的演变

心房颤动(AF)是最常见的心律失常，但其机制尚不清楚。房颤中常见的现象是心外膜再入驱动(旋翼)和突破波。本研究旨在阐明AF机制，包括转子与突破之间的联系。我们采用基于微ct双房几何重建结合区域特异性电生理模型的犬心房三维模型。因此，3D模型包括整个心房的离子和结构异质性，特别关注右心房(RA)和果胶肌(PM)。结果通过三维心房膜电压图(VM)、二维等时图(IM)和波图(WM)显示。房颤发作始于心房，由PV和RA的几个心外膜转盘维持。在这些发作期间，也可以看到跨壁转子通过PM传播并在RA心外膜上重新出现。IM和WM揭示了PM与RA连接的区域的多项突破。VM模拟以及基于电图的IM和WM显示，实验中看到的复杂AF模式可以通过心外膜和跨壁转子的相互作用来解释。

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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2021 Computing in Cardiology (CinC)

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