Oscillatory regime in excitatory media with global coupling: Application to cardiac dynamics

2008 Computers in Cardiology Pub Date : 2008-09-01 DOI:10.1109/CIC.2008.4749009

E. Alvarez-Lacalle, J. F. Rodriguez, B. Echebarria

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引用次数: 3

Abstract

The goal of this paper is to describe the effects of simple electro-mechanical coupling in isotropic two-dimensional (2D) cardiac tissue. To this aim, we show that the Nash-Panfilov two variable model [PRL 95, 258104 (2005)] for electrical activation, which couples active stress directly to transmembrane potential, can be reduced in the linearly elastic regime to an excitatory system with global coupling. In the linear limit, numerical simulations of both models give the same dynamic evolution, including the appearance of an ectopic focus with origin at the center. Indeed, after an initial excitation, mechano-electrical coupling can generate sustained oscillations in the form of successive waves originated at the center. These oscillations have a large basin of attraction for different sample lengths and values of the stretching current, specially when the recovery time of the excitatory cells is short. We finally present and discuss the appearance of oscillatory waves whose origin is not the center of the 2D sample but a ring of tissue around it. These waves appear spontaneously under some conditions even when the first excitation is generated at the center.

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具有全局耦合的兴奋性介质中的振荡机制:在心脏动力学中的应用

本文的目的是描述简单的电-机械耦合在各向同性二维(2D)心脏组织中的影响。为此，我们证明了电激活的Nash-Panfilov二变量模型[PRL 95,258104(2005)]可以在线性弹性状态下简化为具有全局耦合的兴奋系统，该模型将主动应力直接耦合到跨膜电位。在线性极限下，两种模型的数值模拟都得到了相同的动态演化，包括出现一个中心原点的异位焦点。事实上，在初始激励之后，机电耦合可以产生持续的振荡，其形式是起源于中心的连续波。这些振荡对不同样品长度和拉伸电流值具有较大的吸引力，特别是当兴奋细胞恢复时间较短时。我们最后提出并讨论了振荡波的出现，其起源不是二维样品的中心，而是周围的一圈组织。在某些条件下，即使在中心产生了第一个激发，这些波也会自发地出现。

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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2008 Computers in Cardiology

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