AbstractWe propose a new biological framework, spatial networks of hybrid input/output automata (SNHIOA), for the efficient modeling and simulation of excitable-cell tissue. Within this framework, we view an excitable tissue as a network of interacting cells disposed according to a 2D spatial lattice, with the electrical behavior of a single cell modeled as a hybrid input/ouput automaton. To capture the phenomenon that the strength of communication between automata depends on their relative positions within the lattice, we introduce a new, weighted parallel composition operator to specify the influence of one automata over another.The purpose of the SNHIOA model is to efficiently capture the spatiotemporal behavior of wave propagation in 2D...
Background: Computational modeling of biological cells usually ignores their extracellular fields, a...
Investigation of cellular and network dynamics in the brain by means of modeling and simulation has ...
Cardiac and uterine muscle cells and tissue can be either autorhythmic or excitable. These behaviour...
AbstractWe propose a new biological framework, spatial networks of hybrid input/output automata (SNH...
We propose a new biological framework, spatial networks of hybrid input/output automata (SNHIOA), fo...
The main goal of this thesis was to investigate the use of HA as a unifying systems biology approach...
AbstractWe propose a new biological framework based on the Lynch et al. theory of Hybrid I/O Automat...
Background Brain, heart and skeletal muscle share similar properties of excitable tissue, featuring ...
The heart tissue is an excitable media. A Cellular Automata is a type of model that can be used to m...
International audienceIt has been suggested in the literature that a disorganization of cardiac tiss...
In this paper, we explore from an experimental point of view the possibilities and limitations of th...
Copyright © 2008 The Biophysical SocietyJournal ArticleWe aim to understand the formation of abnorma...
Investigation of cellular and network dynamics in the brain by means of modeling & simulation has ev...
This open access volume presents a novel computational framework for understanding how collections o...
This paper is motivated by two aims. Firstly, we want to describe a method for simulations of two-di...
Background: Computational modeling of biological cells usually ignores their extracellular fields, a...
Investigation of cellular and network dynamics in the brain by means of modeling and simulation has ...
Cardiac and uterine muscle cells and tissue can be either autorhythmic or excitable. These behaviour...
AbstractWe propose a new biological framework, spatial networks of hybrid input/output automata (SNH...
We propose a new biological framework, spatial networks of hybrid input/output automata (SNHIOA), fo...
The main goal of this thesis was to investigate the use of HA as a unifying systems biology approach...
AbstractWe propose a new biological framework based on the Lynch et al. theory of Hybrid I/O Automat...
Background Brain, heart and skeletal muscle share similar properties of excitable tissue, featuring ...
The heart tissue is an excitable media. A Cellular Automata is a type of model that can be used to m...
International audienceIt has been suggested in the literature that a disorganization of cardiac tiss...
In this paper, we explore from an experimental point of view the possibilities and limitations of th...
Copyright © 2008 The Biophysical SocietyJournal ArticleWe aim to understand the formation of abnorma...
Investigation of cellular and network dynamics in the brain by means of modeling & simulation has ev...
This open access volume presents a novel computational framework for understanding how collections o...
This paper is motivated by two aims. Firstly, we want to describe a method for simulations of two-di...
Background: Computational modeling of biological cells usually ignores their extracellular fields, a...
Investigation of cellular and network dynamics in the brain by means of modeling and simulation has ...
Cardiac and uterine muscle cells and tissue can be either autorhythmic or excitable. These behaviour...