The key objective of this work is the design of an unconditionally stable, robust, efficient, modular, and easily expandable finite element-based simulation tool for cardiac electrophysiology. In contrast to existing formulations, we propose a global-local split of the system of equations in which the global variable is the fast action potential that is introduced as a nodal degree of freedom, whereas the local variable is the slow recovery variable introduced as an internal variable on the integration point level. Cell-specific excitation characteristics are thus strictly local and only affect the constitutive level. We illustrate the modular character of the model in terms of the FitzHugh-Nagumo model for oscillatory pacemaker cells and t...
An accurate understanding of cardiac function necessitates the knowledge of regulation of electromec...
Computational modeling of the human heart allows us to predict how chemical, electrical, and mechani...
In this project, we develop a Finite Element Method (FEM) formulation that solves the cardiac electr...
The key objective of this work is the design of an unconditionally stable, robust, efficient, modula...
The objective of this work is the computational simulation of a patient-specific electrocardiogram (...
The objective of this work is the computational simulation of a patient-specific electrocardiogram (...
We propose a novel, efficient finite element solution technique to simulate the electrochemical resp...
This book covers the main mathematical and numerical models in computational electrocardiology, rang...
Computational modeling of the human heart allows us to predict how chemical, electrical, and mechani...
In this project, we develop a Finite Element Method (FEM) formulation that solves the cardiac electr...
In this project, we develop a Finite Element Method (FEM) formulation that solves the cardiac electr...
Abstract The modeling of the electrical activity of the heart is of great medical and scientific int...
We developed a finite element model of the electrical activity of the whole heart embedded in the to...
We developed a finite element model of the electrical activity of the whole heart embedded in the to...
The investigation and simulation of the main cardiac functions are increasingly using biophysically ...
An accurate understanding of cardiac function necessitates the knowledge of regulation of electromec...
Computational modeling of the human heart allows us to predict how chemical, electrical, and mechani...
In this project, we develop a Finite Element Method (FEM) formulation that solves the cardiac electr...
The key objective of this work is the design of an unconditionally stable, robust, efficient, modula...
The objective of this work is the computational simulation of a patient-specific electrocardiogram (...
The objective of this work is the computational simulation of a patient-specific electrocardiogram (...
We propose a novel, efficient finite element solution technique to simulate the electrochemical resp...
This book covers the main mathematical and numerical models in computational electrocardiology, rang...
Computational modeling of the human heart allows us to predict how chemical, electrical, and mechani...
In this project, we develop a Finite Element Method (FEM) formulation that solves the cardiac electr...
In this project, we develop a Finite Element Method (FEM) formulation that solves the cardiac electr...
Abstract The modeling of the electrical activity of the heart is of great medical and scientific int...
We developed a finite element model of the electrical activity of the whole heart embedded in the to...
We developed a finite element model of the electrical activity of the whole heart embedded in the to...
The investigation and simulation of the main cardiac functions are increasingly using biophysically ...
An accurate understanding of cardiac function necessitates the knowledge of regulation of electromec...
Computational modeling of the human heart allows us to predict how chemical, electrical, and mechani...
In this project, we develop a Finite Element Method (FEM) formulation that solves the cardiac electr...