Background Brain, heart and skeletal muscle share similar properties of excitable tissue, featuring both discrete behavior (all-or-nothing response to electrical activation) and continuous behavior (recovery to rest follows a temporal path, determined by multiple competing ion flows). Classical mathematical models of excitable cells involve complex systems of nonlinear differential equations. Such models not only impair formal analysis but also impose high computational demands on simulations, especially in large-scale 2-D and 3-D cell networks. In this paper, we show that by choosing Hybrid Automata as the modeling formalism, it is possible to construct a more abstract model of excitable cells that preserves the properties of interest whil...
In this thesis, a cellular automata based modelling software is developed for studying the electrica...
Electrically excitable cells, e.g., neurons, cardiac cells, and pancreatic -cells, must function pro...
AbstractElectrically excitable cells, e.g., neurons, cardiac cells, and pancreatic β-cells, must fun...
Background Brain, heart and skeletal muscle share similar properties of excitable tissue, featuring ...
The main goal of this thesis was to investigate the use of HA as a unifying systems biology approach...
This open access volume presents a novel computational framework for understanding how collections o...
AbstractWe propose a new biological framework, spatial networks of hybrid input/output automata (SNH...
<div><p>To understand how excitable tissues give rise to arrhythmias, it is crucially necessary to u...
In this paper, we explore from an experimental point of view the possibilities and limitations of th...
To understand how excitable tissues give rise to arrhythmias, it is crucially necessary to understan...
The faithful reproduction and accurate prediction of the phe-notypes and emergent behaviors of compl...
AbstractWe propose a new biological framework based on the Lynch et al. theory of Hybrid I/O Automat...
Computational models of the heart, from cell-level models, through one-, two- and three-dimensional ...
Background: Computational modeling of biological cells usually ignores their extracellular fields, a...
We propose a new biological framework, spatial networks of hybrid input/output automata (SNHIOA), fo...
In this thesis, a cellular automata based modelling software is developed for studying the electrica...
Electrically excitable cells, e.g., neurons, cardiac cells, and pancreatic -cells, must function pro...
AbstractElectrically excitable cells, e.g., neurons, cardiac cells, and pancreatic β-cells, must fun...
Background Brain, heart and skeletal muscle share similar properties of excitable tissue, featuring ...
The main goal of this thesis was to investigate the use of HA as a unifying systems biology approach...
This open access volume presents a novel computational framework for understanding how collections o...
AbstractWe propose a new biological framework, spatial networks of hybrid input/output automata (SNH...
<div><p>To understand how excitable tissues give rise to arrhythmias, it is crucially necessary to u...
In this paper, we explore from an experimental point of view the possibilities and limitations of th...
To understand how excitable tissues give rise to arrhythmias, it is crucially necessary to understan...
The faithful reproduction and accurate prediction of the phe-notypes and emergent behaviors of compl...
AbstractWe propose a new biological framework based on the Lynch et al. theory of Hybrid I/O Automat...
Computational models of the heart, from cell-level models, through one-, two- and three-dimensional ...
Background: Computational modeling of biological cells usually ignores their extracellular fields, a...
We propose a new biological framework, spatial networks of hybrid input/output automata (SNHIOA), fo...
In this thesis, a cellular automata based modelling software is developed for studying the electrica...
Electrically excitable cells, e.g., neurons, cardiac cells, and pancreatic -cells, must function pro...
AbstractElectrically excitable cells, e.g., neurons, cardiac cells, and pancreatic β-cells, must fun...