Jump-Diffusion Approximation of Stochastic Reaction Dynamics: Error bounds and Algorithms

Biochemical reactions can happen on different time scales and also the abundance of species in these reactions can be very different from each other. Classical approaches, such as deterministic or stochastic approach, fail to account for or to exploit this multi-scale nature, respectively. In this p...

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Veröffentlicht in:	arXiv.org 2014-09
Hauptverfasser:	Ganguly, Arnab, Altintan, Derya, Koeppl, Heinz
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Sprache:	eng
Schlagworte:	Algorithms Approximation Computer simulation Computing time Differential equations Errors Gene expression Markov chains Mathematical analysis Signal transduction
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description	Biochemical reactions can happen on different time scales and also the abundance of species in these reactions can be very different from each other. Classical approaches, such as deterministic or stochastic approach, fail to account for or to exploit this multi-scale nature, respectively. In this paper, we propose a jump-diffusion approximation for multi-scale Markov jump processes that couples the two modeling approaches. An error bound of the proposed approximation is derived and used to partition the reactions into fast and slow sets, where the fast set is simulated by a stochastic differential equation and the slow set is modeled by a discrete chain. The error bound leads to a very efficient dynamic partitioning algorithm which has been implemented for several multi-scale reaction systems. The gain in computational efficiency is illustrated by a realistically sized model of a signal transduction cascade coupled to a gene expression dynamics.
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subjects	Algorithms Approximation Computer simulation Computing time Differential equations Errors Gene expression Markov chains Mathematical analysis Signal transduction
title	Jump-Diffusion Approximation of Stochastic Reaction Dynamics: Error bounds and Algorithms
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