A partial-propensity formulation of the stochastic simulation algorithm for chemical reaction networks with delays

Several real-world systems, such as gene expression networks in biological cells, contain coupled chemical reactions with a time delay between reaction initiation and completion. The non-Markovian kinetics of such reaction networks can be exactly simulated using the delay stochastic simulation algor...

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Bibliographic Details
Published in:The Journal of chemical physics Vol. 134; no. 1; p. 014106
Main Authors: Ramaswamy, Rajesh, Sbalzarini, Ivo F
Format: Journal Article
Language:English
Published: United States 07.01.2011
Subjects:
Algorithms
Kinetics
Molecular Dynamics Simulation
ISSN:1089-7690, 1089-7690
Online Access:Get more information
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Summary:Several real-world systems, such as gene expression networks in biological cells, contain coupled chemical reactions with a time delay between reaction initiation and completion. The non-Markovian kinetics of such reaction networks can be exactly simulated using the delay stochastic simulation algorithm (dSSA). The computational cost of dSSA scales with the total number of reactions in the network. We reduce this cost to scale at most with the smaller number of species by using the concept of partial reaction propensities. The resulting delay partial-propensity direct method (dPDM) is an exact dSSA formulation for well-stirred systems of coupled chemical reactions with delays. We detail dPDM and present a theoretical analysis of its computational cost. Furthermore, we demonstrate the implications of the theoretical cost analysis in two prototypical benchmark applications. The dPDM formulation is shown to be particularly efficient for strongly coupled reaction networks, where the number of reactions is much larger than the number of species.
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ISSN:1089-7690
1089-7690
DOI:10.1063/1.3521496