Fast stochastic simulation of biochemical reaction systems by alternative formulations of the chemical Langevin equation
Fast stochastic simulation of biochemical reaction systems by alternative formulations of the chemical Langevin equation
The Chemical Langevin Equation (CLE), which is a stochastic differential equation driven by a multidimensional Wiener process, acts as a bridge between the discrete stochastic simulation algorithm and the deterministic reaction rate equation when simulating (bio)chemical kinetics. The CLE model is valid in the regime where molecular populations are abundant enough to assume their concentrations change continuously, but stochastic fluctuations still play a major role. The contribution of this work is that we observe and explore that the CLE is not a single equation, but a parametric family of equations, all of which give the same finite-dimensional distribution of the variables. On the theoretical side, we prove that as many Wiener processes are sufficient to formulate the CLE as there are independent variables in the equation, which is just the rank of the stoichiometric matrix. On the practical side, we show that in the case where there are m1 pairs of reversible reactions and m2 irreversible reactions there is another, simple formulation of the CLE with only m1+m2 Wiener processes, whereas the standard approach uses 2m1+m2. We demonstrate that there are considerable computational savings when using this latter formulation. Such transformations of the CLE do not cause a loss of accuracy and are therefore distinct from model reduction techniques. We illustrate our findings by considering alternative formulations of the CLE for a human ether a-go-go related gene ion channel model and the Goldbeter–Koshland switch
biochemistry, biology computing, differential equations, Markov processes, physiological models
164109
Mélykúti, Bence
5d01544d-082f-4ba9-9861-f54387395075
Burrage, Kevin
21828882-69b3-4763-abb0-b3109f0a1c24
Zygalakis, Konstantinos C.
a330d719-2ccb-49bd-8cd8-d06b1e6daca6
26 April 2010
Mélykúti, Bence
5d01544d-082f-4ba9-9861-f54387395075
Burrage, Kevin
21828882-69b3-4763-abb0-b3109f0a1c24
Zygalakis, Konstantinos C.
a330d719-2ccb-49bd-8cd8-d06b1e6daca6
Mélykúti, Bence, Burrage, Kevin and Zygalakis, Konstantinos C.
(2010)
Fast stochastic simulation of biochemical reaction systems by alternative formulations of the chemical Langevin equation.
The Journal of Chemical Physics, 132 (16), .
(doi:10.1063/1.3380661).
Abstract
The Chemical Langevin Equation (CLE), which is a stochastic differential equation driven by a multidimensional Wiener process, acts as a bridge between the discrete stochastic simulation algorithm and the deterministic reaction rate equation when simulating (bio)chemical kinetics. The CLE model is valid in the regime where molecular populations are abundant enough to assume their concentrations change continuously, but stochastic fluctuations still play a major role. The contribution of this work is that we observe and explore that the CLE is not a single equation, but a parametric family of equations, all of which give the same finite-dimensional distribution of the variables. On the theoretical side, we prove that as many Wiener processes are sufficient to formulate the CLE as there are independent variables in the equation, which is just the rank of the stoichiometric matrix. On the practical side, we show that in the case where there are m1 pairs of reversible reactions and m2 irreversible reactions there is another, simple formulation of the CLE with only m1+m2 Wiener processes, whereas the standard approach uses 2m1+m2. We demonstrate that there are considerable computational savings when using this latter formulation. Such transformations of the CLE do not cause a loss of accuracy and are therefore distinct from model reduction techniques. We illustrate our findings by considering alternative formulations of the CLE for a human ether a-go-go related gene ion channel model and the Goldbeter–Koshland switch
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Published date: 26 April 2010
Keywords:
biochemistry, biology computing, differential equations, Markov processes, physiological models
Organisations:
Applied Mathematics
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Local EPrints ID: 340574
URI: http://eprints.soton.ac.uk/id/eprint/340574
ISSN: 0021-9606
PURE UUID: f7734b08-4db6-4b9b-80d1-5460c6441e3c
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Date deposited: 25 Jun 2012 15:40
Last modified: 14 Mar 2024 11:26
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Author:
Bence Mélykúti
Author:
Kevin Burrage
Author:
Konstantinos C. Zygalakis
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