Cholinergic Atrial Fibrillation in a Computer Model of a Two-Dimensional Sheet of Canine Atrial Cells With Realistic Ionic Properties

Circulation Research: Journal of the American Heart Association Pub Date : 2002-05-17 DOI:10.1161/01.RES.0000019783.88094.BA

James F. Kneller, Renqiang Zou, E. Vigmond, Zhiguo Wang, L. J. Leon, S. Nattel

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引用次数: 289

Abstract

Classical concepts of atrial fibrillation (AF) have been rooted in Moe’s multiple-wavelet hypothesis and simple cellular-automaton computer model. Recent experimental work has raised questions about the multiple-wavelet mechanism, suggesting a discrete “driver region” underlying AF. We reexplored the theoretical basis for AF with a 2-dimensional computer model of a 5×10-cm sheet of atrial cells with realistic ionic and coupling properties. Vagal actions were formulated based on patch-clamp studies of acetylcholine (ACh) effects. In control, a single extrastimulus resulted in a highly meandering unstable spiral wave. Simulated electrograms showed fibrillatory activity, with a dominant frequency (DF, 6.5 Hz) that correlated with the mean rate. Uniform ACh reduced core meander of the spiral wave by ≈70% (as measured by the standard deviation of spiral-wave tip position) and accelerated the DF to 17.0 Hz. Simulated vagally induced refractoriness heterogeneity caused wavefront breakup as accelerated reentrant activity in regions of short refractoriness impinged on regions unable to respond in a 1:1 fashion because of longer refractoriness. In 7 simulations spanning the range of conditions giving sustained AF, 5 were maintained by single dominant spiral waves. On average, 3.0±1.3 wavelets were present (range, 1 to 7). Most wavelets were short-lived and did not contribute to AF maintenance. In contrast to predictions of the multiple-wavelet hypothesis, but in agreement with recent experimental evidence, our model indicates that AF can result from relatively stable primary spiral-wave generators and is significantly organized. Our results suggest that vagal AF may arise from ACh-induced stabilization of the primary spiral-wave generator and disorganization of the heterogeneous tissue response. The full text of this article is available at http://www.circresaha.org.

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具有真实离子特性的犬心房细胞二维计算机模型中的胆碱能性心房颤动

古典心房颤动(房颤)的概念已经根植于Moe multiple-wavelet假说和简单的细胞自动机的计算机模型。最近的实验工作提出了关于多小波机制的问题，表明心房颤动存在离散的“驱动区域”。我们利用具有真实离子和偶联特性的5×10-cm心房细胞片的二维计算机模型重新探索心房颤动的理论基础。迷走神经的作用是根据乙酰胆碱(ACh)效应的膜片钳研究制定的。在控制中，单一的额外刺激导致高度弯曲的不稳定螺旋波。模拟电图显示了纤颤活动，其主导频率(DF, 6.5 Hz)与平均频率相关。均匀ACh使螺旋波的核心曲度降低约70%(以螺旋波尖端位置的标准差测量)，并使DF加速到17.0 Hz。模拟迷走神经诱导的耐火度非均匀性导致波前破裂，因为短耐火度区域的重入活动加速，冲击了由于较长耐火度而无法以1:1方式响应的区域。在7个模拟中，有5个模拟是由单一的主导螺旋波维持的。平均存在3.0±1.3个小波(范围1 ~ 7)。大多数小波是短暂的，对AF维持没有贡献。与多小波假设的预测相反，但与最近的实验证据一致，我们的模型表明AF可以由相对稳定的初级螺旋波发生器产生，并且具有显著的组织性。我们的研究结果表明迷走神经房颤可能是由乙酰胆碱诱导的初级螺旋波发生器的稳定和异质组织反应的紊乱引起的。本文全文可在http://www.circresaha.org找到。

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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Circulation Research: Journal of the American Heart Association

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