In this paper a microscopic model for a signalling process in the left ventricular wall of the heart, comprising a non-periodic brous microstructure, is considered. To derive the macroscopic equations the non-periodic microstructure is approximated by the corresponding locally-periodic microstructure. Then applying the methods of locally-periodic homogenization (the locallyperiodic (l-p) unfolding operator, locally-periodic two-scale (l-t-s) convergence on oscillating surfaces and l-p boundary unfolding operator) we obtain the macroscopic model for a signalling process in the heart tissue
Tissue microstructure, in particular the alignment of myocytes (fibre direction) and their lateral o...
The myocardium is composed of interconnected cardiac fibres which are responsible for contraction of...
Biological tissue is distinguished from materials described historically by continuum mechanical the...
In this paper a microscopic model for a signalling process in the left ventricular wall of the heart...
In this paper we generalize the periodic unfolding method and the notion of two-scale convergence on...
We present and analyze a model for cell signaling processes in biological tissues. The model include...
We study, by means of the periodic unfolding technique, the homogenization of a modified bidomain mo...
A novel multiple scales method is formulated that can be applied to problems which have an almost pe...
International audienceIn the present paper, a new three-scale asymptotic homogenization method is pr...
International audienceIn this paper we study how mesoscopic heterogeneities affect electrical signal...
International audienceWe study the homogenization of a novel microscopic tridomain system, allowing ...
International audienceThanks to their geometrical organization at the cell level, soft biological ti...
International audienceIn this paper, we are dealing with a rigorous homogenization result at two dif...
The uniformity of the mechanical load of the cardiac fibers in the wall is maintained by continuous ...
tational models to help interpret their ex-perimental studies of the electromechani-cal properties o...
Tissue microstructure, in particular the alignment of myocytes (fibre direction) and their lateral o...
The myocardium is composed of interconnected cardiac fibres which are responsible for contraction of...
Biological tissue is distinguished from materials described historically by continuum mechanical the...
In this paper a microscopic model for a signalling process in the left ventricular wall of the heart...
In this paper we generalize the periodic unfolding method and the notion of two-scale convergence on...
We present and analyze a model for cell signaling processes in biological tissues. The model include...
We study, by means of the periodic unfolding technique, the homogenization of a modified bidomain mo...
A novel multiple scales method is formulated that can be applied to problems which have an almost pe...
International audienceIn the present paper, a new three-scale asymptotic homogenization method is pr...
International audienceIn this paper we study how mesoscopic heterogeneities affect electrical signal...
International audienceWe study the homogenization of a novel microscopic tridomain system, allowing ...
International audienceThanks to their geometrical organization at the cell level, soft biological ti...
International audienceIn this paper, we are dealing with a rigorous homogenization result at two dif...
The uniformity of the mechanical load of the cardiac fibers in the wall is maintained by continuous ...
tational models to help interpret their ex-perimental studies of the electromechani-cal properties o...
Tissue microstructure, in particular the alignment of myocytes (fibre direction) and their lateral o...
The myocardium is composed of interconnected cardiac fibres which are responsible for contraction of...
Biological tissue is distinguished from materials described historically by continuum mechanical the...