Three Scale Unfolding Homogenization Method Applied to Cardiac Bidomain Model

TL;DR

This paper develops a rigorous three-scale homogenization method for the cardiac bidomain model, deriving a macroscopic reaction-diffusion system from complex meso-microscopic structures using unfolding operators.

Contribution

It introduces a novel three-scale unfolding homogenization approach for the bidomain model, capturing intracellular and extracellular interactions at multiple levels.

Findings

Derived a macroscopic reaction-diffusion system from detailed meso-microscopic models.

Established convergence of nonlinear interface fluxes using boundary unfolding and compactness techniques.

Unified intracellular and extracellular media into a single homogenized model.

Abstract

In this paper, we are dealing with a rigorous homogenization result at two different levels for the bidomain model of cardiac electro-physiology. The first level associated with the mesoscopic structure such that the cardiac tissue consists of extracellular and intracellular domains separated by an interface (the sarcolemma). The second one related to the microscopic structure in such a way that the intracellular medium can only be viewed as a periodical layout of unit cells (mitochondria). At the interface between intra-and extracellular media, the fluxes are given by nonlinear functions of ionic and applied currents. A rigorous homogenization process based on unfolding operators is applied to derive the macroscopic (homogenized) model from our meso-microscopic bidomain model. We apply a three-scale unfolding method in the intracellular problem to obtain its homogenized equation at two levels. The first level upscaling of the intracellular structure yields the mesoscopic equation. The second step of the homogenization leads to obtain the intracellular homogenized equation. To prove the convergence of the nonlinear terms, especially those defined on the microscopic interface, we use the boundary unfolding method and a Kolmogorov-Riesz compactness's result. Next, we use the standard unfolding method to homogenize the extracellular problem. Finally, we obtain, at the limit, a reaction-diffusion system on a single domain (the superposition of the intracellular and extracellular media) which contains the homogenized equations depending on three scales. Such a model is widely used for describing the macroscopic behavior of the cardiac tissue, which is recognized to be an important messengers between the cytoplasm (intracellular) and the other extracellular inside the biological cells. Contents 2020 Mathematics Subject Classification. 65N55 and 35A01 and 35B27 and 35K57 and 65M..