We present a method for mesoscopic, dynamic Monte Carlo simulations of pattern formation in excitable reaction–diffusion systems. Using a two-level parallelization approach, our simulations cover the whole range of the parameter space, from the noise-dominated low-particle number regime to the quasi-deterministic high-particle number limit. Three qualitatively different case studies are performed that stand exemplary for the wide variety of excitable systems. We present mesoscopic stochastic simulations of the Gray-Scott model, of a simplified model for intracellular Ca2z oscillations and, for the first time, of the Oregonator model. We achieve simulations with up to 1010 particles. The software and the model files are freely available and ...
Copyright © 2014 Daniele D’Agostino et al. This is an open access article distributed under the Crea...
With the observation that stochasticity is important in biological systems, chemical kinetics have b...
Stochasticity (that is, randomness) is an inherent property of many biological systems. For example,...
We present a method for mesoscopic, dynamic Monte Carlo simulations of pattern formation in excitabl...
We propose a stochastic cellular automaton method to simulate chemical reactions in small systems. U...
A stochastic cellular automaton is developed for modeling waves in excitable media. A scale of key f...
In this paper, we address the question of the discretization of stochastic partial differential equa...
In this dissertation, we introduce a novel accelerated-stochastic simulation method, known as the ‘p...
The dynamic Monte Carlo method has been used to simulate the 2 A + B-2 --> 2 AB reaction catalyzed b...
Abstract: Computational modeling and simulation have become invaluable tools for the biological scie...
Stochastic simulations of reaction-diffusion processes are used extensively for the modeling of comp...
There is an increasing awareness of the pivotal role of noise in biochemical processes and of the ef...
Abstract. We provide numerical simulations for nonlinear reaction-diusion systems, which arise from ...
The effective method of simulation of stochastic excitable media by en ensemble of Brownian particl...
Quantitative descriptions of reaction kinetics formulated at the stochastic mesoscopic level are fre...
Copyright © 2014 Daniele D’Agostino et al. This is an open access article distributed under the Crea...
With the observation that stochasticity is important in biological systems, chemical kinetics have b...
Stochasticity (that is, randomness) is an inherent property of many biological systems. For example,...
We present a method for mesoscopic, dynamic Monte Carlo simulations of pattern formation in excitabl...
We propose a stochastic cellular automaton method to simulate chemical reactions in small systems. U...
A stochastic cellular automaton is developed for modeling waves in excitable media. A scale of key f...
In this paper, we address the question of the discretization of stochastic partial differential equa...
In this dissertation, we introduce a novel accelerated-stochastic simulation method, known as the ‘p...
The dynamic Monte Carlo method has been used to simulate the 2 A + B-2 --> 2 AB reaction catalyzed b...
Abstract: Computational modeling and simulation have become invaluable tools for the biological scie...
Stochastic simulations of reaction-diffusion processes are used extensively for the modeling of comp...
There is an increasing awareness of the pivotal role of noise in biochemical processes and of the ef...
Abstract. We provide numerical simulations for nonlinear reaction-diusion systems, which arise from ...
The effective method of simulation of stochastic excitable media by en ensemble of Brownian particl...
Quantitative descriptions of reaction kinetics formulated at the stochastic mesoscopic level are fre...
Copyright © 2014 Daniele D’Agostino et al. This is an open access article distributed under the Crea...
With the observation that stochasticity is important in biological systems, chemical kinetics have b...
Stochasticity (that is, randomness) is an inherent property of many biological systems. For example,...