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A higher-order numerical framework for stochastic simulation of chemical reaction systems

BACKGROUND: In this paper, we present a framework for improving the accuracy of fixed-step methods for Monte Carlo simulation of discrete stochastic chemical kinetics. Stochasticity is ubiquitous in many areas of cell biology, for example in gene regulation, biochemical cascades and cell-cell intera...

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Autores principales: Székely, Tamás, Burrage, Kevin, Erban, Radek, Zygalakis, Konstantinos C
Formato: Online Artículo Texto
Lenguaje:English
Publicado: BioMed Central 2012
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3529698/
https://www.ncbi.nlm.nih.gov/pubmed/23256696
http://dx.doi.org/10.1186/1752-0509-6-85
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author Székely, Tamás
Burrage, Kevin
Erban, Radek
Zygalakis, Konstantinos C
author_facet Székely, Tamás
Burrage, Kevin
Erban, Radek
Zygalakis, Konstantinos C
author_sort Székely, Tamás
collection PubMed
description BACKGROUND: In this paper, we present a framework for improving the accuracy of fixed-step methods for Monte Carlo simulation of discrete stochastic chemical kinetics. Stochasticity is ubiquitous in many areas of cell biology, for example in gene regulation, biochemical cascades and cell-cell interaction. However most discrete stochastic simulation techniques are slow. We apply Richardson extrapolation to the moments of three fixed-step methods, the Euler, midpoint and θ-trapezoidal τ-leap methods, to demonstrate the power of stochastic extrapolation. The extrapolation framework can increase the order of convergence of any fixed-step discrete stochastic solver and is very easy to implement; the only condition for its use is knowledge of the appropriate terms of the global error expansion of the solver in terms of its stepsize. In practical terms, a higher-order method with a larger stepsize can achieve the same level of accuracy as a lower-order method with a smaller one, potentially reducing the computational time of the system. RESULTS: By obtaining a global error expansion for a general weak first-order method, we prove that extrapolation can increase the weak order of convergence for the moments of the Euler and the midpoint τ-leap methods, from one to two. This is supported by numerical simulations of several chemical systems of biological importance using the Euler, midpoint and θ-trapezoidal τ-leap methods. In almost all cases, extrapolation results in an improvement of accuracy. As in the case of ordinary and stochastic differential equations, extrapolation can be repeated to obtain even higher-order approximations. CONCLUSIONS: Extrapolation is a general framework for increasing the order of accuracy of any fixed-step stochastic solver. This enables the simulation of complicated systems in less time, allowing for more realistic biochemical problems to be solved.
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spelling pubmed-35296982013-01-03 A higher-order numerical framework for stochastic simulation of chemical reaction systems Székely, Tamás Burrage, Kevin Erban, Radek Zygalakis, Konstantinos C BMC Syst Biol Methodology Article BACKGROUND: In this paper, we present a framework for improving the accuracy of fixed-step methods for Monte Carlo simulation of discrete stochastic chemical kinetics. Stochasticity is ubiquitous in many areas of cell biology, for example in gene regulation, biochemical cascades and cell-cell interaction. However most discrete stochastic simulation techniques are slow. We apply Richardson extrapolation to the moments of three fixed-step methods, the Euler, midpoint and θ-trapezoidal τ-leap methods, to demonstrate the power of stochastic extrapolation. The extrapolation framework can increase the order of convergence of any fixed-step discrete stochastic solver and is very easy to implement; the only condition for its use is knowledge of the appropriate terms of the global error expansion of the solver in terms of its stepsize. In practical terms, a higher-order method with a larger stepsize can achieve the same level of accuracy as a lower-order method with a smaller one, potentially reducing the computational time of the system. RESULTS: By obtaining a global error expansion for a general weak first-order method, we prove that extrapolation can increase the weak order of convergence for the moments of the Euler and the midpoint τ-leap methods, from one to two. This is supported by numerical simulations of several chemical systems of biological importance using the Euler, midpoint and θ-trapezoidal τ-leap methods. In almost all cases, extrapolation results in an improvement of accuracy. As in the case of ordinary and stochastic differential equations, extrapolation can be repeated to obtain even higher-order approximations. CONCLUSIONS: Extrapolation is a general framework for increasing the order of accuracy of any fixed-step stochastic solver. This enables the simulation of complicated systems in less time, allowing for more realistic biochemical problems to be solved. BioMed Central 2012-07-15 /pmc/articles/PMC3529698/ /pubmed/23256696 http://dx.doi.org/10.1186/1752-0509-6-85 Text en Copyright ©2012 Székely et al.; licensee BioMed Central Ltd. http://creativecommons.org/licenses/by/2.0 This is an Open Access article distributed under the terms of the Creative Commons Attribution License ( http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
spellingShingle Methodology Article
Székely, Tamás
Burrage, Kevin
Erban, Radek
Zygalakis, Konstantinos C
A higher-order numerical framework for stochastic simulation of chemical reaction systems
title A higher-order numerical framework for stochastic simulation of chemical reaction systems
title_full A higher-order numerical framework for stochastic simulation of chemical reaction systems
title_fullStr A higher-order numerical framework for stochastic simulation of chemical reaction systems
title_full_unstemmed A higher-order numerical framework for stochastic simulation of chemical reaction systems
title_short A higher-order numerical framework for stochastic simulation of chemical reaction systems
title_sort higher-order numerical framework for stochastic simulation of chemical reaction systems
topic Methodology Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3529698/
https://www.ncbi.nlm.nih.gov/pubmed/23256696
http://dx.doi.org/10.1186/1752-0509-6-85
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