Abstract
Cardiac fibrosis occurs in many forms of heart disease. It is well established that the spatial pattern of fibrosis, its texture, substantially affects the onset of arrhythmia. However, in most modelling studies fibrosis is represented by multiple randomly distributed short obstacles that mimic only one possible texture, diffuse fibrosis. An important characteristic feature of other fibrosis textures, such as interstitial and patchy textures, is that fibrotic inclusions have substantial length, which is suggested to have a pronounced effect on wave propagation. In this paper, we study the effect of the elongation of inexcitable inclusions (obstacles) on wave propagation in a 2D model of cardiac tissue described by the TP06 model for human ventricular cells. We study in detail how the elongation of obstacles affects various characteristics of the waves. We quantify the anisotropy induced by the textures, its dependency on the obstacle length and the effects of the texture on the shape of the propagating wave. Because such anisotropy is a result of zig-zag propagation we show, for the first time, quantification of the effects of geometry and source-sink relationship, on the zig-zag nature of the pathway of electrical conduction. We also study the effect of fibrosis in the case of pre-existing anisotropy and introduce a procedure for scaling of the fibrosis texture. We show that fibrosis can decrease or increase the preexisting anisotropy depending on its scaled texture.
Highlights
Cardiac fibrosis occurs in many forms of heart disease
Because the main feature of patchy and interstitial fibrosis is the presence of elongated obstacles, it is important to understand the possible effects of such elongation on wave propagation in cardiac tissue
We studied the propagation of the excitation wave for fibrosis textures with various obstacle lengths
Summary
Cardiac fibrosis occurs in many forms of heart disease. It is well established that the spatial pattern of fibrosis, its texture, substantially affects the onset of arrhythmia. Because the main feature of patchy and interstitial fibrosis is the presence of elongated obstacles, it is important to understand the possible effects of such elongation on wave propagation in cardiac tissue. In a low - dimensional model of cardiac tissue it was shown that the texture of inexcitable elongated obstacles can produce a directional difference in (dV∕dt)max, which should be absent in the case of continuous propagation. This effect becomes pronounced if the parameter L∕W has a value of 2–3, where L is the length of the obstacle and W is the spatial length of the wavefront. The aim of this paper is to study in detail effects of randomly generated textures with various lengths and percentages of obstacles on wave propagation in cardiac tissue
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