The bidomain model is based on effective parameters to include the myocardial tissue properties into models of propagation of depolarization. In this study we examine whether these properties can be derived from histology by generating a geometrical model of cardiac tissue and com-puting the effective conductivity. We tested this hypothesis by generating a detailed model of cardiac tissue in which we simulated the propagation of depolarization directly, using the so-called microdomain approach. We compared both the the conduction across and along the fiber of the myocardium under both healthy and ischemic conditions. Under healthy conditions both the microdomain and bido-main approximation resulted in conduction velocities that were within ...
Abstract—A bidomain reaction-diffusion model of the human heart was developed, and potentials result...
International audienceWe present a new mathematical model of the electric activity of the heart. In ...
Parallel numerical simulations of excitation and recovery in three dimensional myocardial domains ar...
The bidomain model is often used to simulate the electrical activity in cardiac tissue. It has appli...
Bidomain equations are the standard way to model the electric potential in cardiac tissue. They are ...
Bidomain equations are the standard way to model the electric potential in cardiac tissue. They are ...
When modelling tissue-level cardiac electrophysiology, a continuum approximation to the discrete cel...
Tissue level cardiac electrophysiology is usually modelled by the bidomain equations, or the monodom...
Advanced multiscale models in computational electrocardiology offer a detailed representation of the...
The standard bidomain model is based on the fact that electrically active cardiomyocytes are present...
Abstract We derive the values for the intracellular and extracellular conductivities needed for bido...
International audienceIntroduction: The most used model in the elctrophysiology of theheart, known a...
The bidomain reaction-diffusion model is a set of equations (1), (2) that model how currents propaga...
Parallel numerical simulations of excitation and recovery in three-dimensional myocardial domains ar...
Bidomain equations are the standard way to model the electric potential in cardiac tissue. We propos...
Abstract—A bidomain reaction-diffusion model of the human heart was developed, and potentials result...
International audienceWe present a new mathematical model of the electric activity of the heart. In ...
Parallel numerical simulations of excitation and recovery in three dimensional myocardial domains ar...
The bidomain model is often used to simulate the electrical activity in cardiac tissue. It has appli...
Bidomain equations are the standard way to model the electric potential in cardiac tissue. They are ...
Bidomain equations are the standard way to model the electric potential in cardiac tissue. They are ...
When modelling tissue-level cardiac electrophysiology, a continuum approximation to the discrete cel...
Tissue level cardiac electrophysiology is usually modelled by the bidomain equations, or the monodom...
Advanced multiscale models in computational electrocardiology offer a detailed representation of the...
The standard bidomain model is based on the fact that electrically active cardiomyocytes are present...
Abstract We derive the values for the intracellular and extracellular conductivities needed for bido...
International audienceIntroduction: The most used model in the elctrophysiology of theheart, known a...
The bidomain reaction-diffusion model is a set of equations (1), (2) that model how currents propaga...
Parallel numerical simulations of excitation and recovery in three-dimensional myocardial domains ar...
Bidomain equations are the standard way to model the electric potential in cardiac tissue. We propos...
Abstract—A bidomain reaction-diffusion model of the human heart was developed, and potentials result...
International audienceWe present a new mathematical model of the electric activity of the heart. In ...
Parallel numerical simulations of excitation and recovery in three dimensional myocardial domains ar...