Models of cardiac electrical activity cover a wide range of spatial scales, from the genesis of the ionic currents in individual cardiomyocytes to the generation of electrocardiograms on the torso. The level of detail that is appropriate and practicable depends on the problem investigated and the scope of the computations that are required. We briefly present three examples of modelling: the dynamics of the entrainment of a single cell, the impact of fibrosis on electrical propagation in a piece of tissue and the generation of ECG in human. In each case, the methods, results and limitations are discussed
The work deals with the foundations of bioelectric phenomena cardiomyocyte, then it is also part of ...
In this paper, we study a mathematical model of cardiac tissue based on explicit representation of i...
International audienceThis chapter presents a concise overview of various mathematical and numerical...
This work is focused on different aspects within the loop of multiscale modeling:On the cellular lev...
We developed a finite element model of the electrical activity of the whole heart embedded in the to...
Remodelling of cardiac tissue structure, including intercellular electrical coupling, is a major det...
Comprehension of the beating of the human heart is important for cardiac research and will improve m...
The development of mathematical models of the heart has been an ongoing concern for many decades. Th...
We developed a three-dimensional finite element model of the electrical activity of the whole heart ...
An accurate understanding of cardiac function necessitates the knowledge of regulation of electromec...
For over 100 years cardiac electrophysiology has been measured in the clinic. The electrical signals...
The inclusion of nonconducting media, mimicking cardiac fibrosis, in two models of cardiac tissue pr...
International audienceThis work is dedicated to the simulation of full cycles of the electrical acti...
Computational simulations of cardiac electrophysiology provide detailed information on the depolariz...
This book covers the main mathematical and numerical models in computational electrocardiology, rang...
The work deals with the foundations of bioelectric phenomena cardiomyocyte, then it is also part of ...
In this paper, we study a mathematical model of cardiac tissue based on explicit representation of i...
International audienceThis chapter presents a concise overview of various mathematical and numerical...
This work is focused on different aspects within the loop of multiscale modeling:On the cellular lev...
We developed a finite element model of the electrical activity of the whole heart embedded in the to...
Remodelling of cardiac tissue structure, including intercellular electrical coupling, is a major det...
Comprehension of the beating of the human heart is important for cardiac research and will improve m...
The development of mathematical models of the heart has been an ongoing concern for many decades. Th...
We developed a three-dimensional finite element model of the electrical activity of the whole heart ...
An accurate understanding of cardiac function necessitates the knowledge of regulation of electromec...
For over 100 years cardiac electrophysiology has been measured in the clinic. The electrical signals...
The inclusion of nonconducting media, mimicking cardiac fibrosis, in two models of cardiac tissue pr...
International audienceThis work is dedicated to the simulation of full cycles of the electrical acti...
Computational simulations of cardiac electrophysiology provide detailed information on the depolariz...
This book covers the main mathematical and numerical models in computational electrocardiology, rang...
The work deals with the foundations of bioelectric phenomena cardiomyocyte, then it is also part of ...
In this paper, we study a mathematical model of cardiac tissue based on explicit representation of i...
International audienceThis chapter presents a concise overview of various mathematical and numerical...