Physically consistent simulation of mesoscale chemical kinetics: The non-negative FIS-{alpha} method

Physically consistent simulation of mesoscale chemical kinetics: The non-negative FIS-{alpha} method

Biochemical pathways involving chemical kinetics in medium concentrations (i.e., at mesoscale) of the reacting molecules can be approximated as chemical Langevin equations (CLE) systems. We address the physically consistent non-negative simulation of the CLE sample paths as well as the issue of non-...

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Veröffentlicht in:Journal of computational physics 2011-10, Vol.230 (24)
Hauptverfasser: Dana, Saswati, Raha, Soumyendu
Format: Artikel
Sprache:eng
Schlagworte:
CALCULATION METHODS
CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS
COMPUTERIZED SIMULATION
DIFFERENTIAL EQUATIONS
EQUATIONS
KINETICS
LANGEVIN EQUATION
MATHEMATICAL MODELS
ORGANIC COMPOUNDS
PROTEINS
SIMULATION
STOCHASTIC PROCESSES
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Zusammenfassung:Biochemical pathways involving chemical kinetics in medium concentrations (i.e., at mesoscale) of the reacting molecules can be approximated as chemical Langevin equations (CLE) systems. We address the physically consistent non-negative simulation of the CLE sample paths as well as the issue of non-Lipschitz diffusion coefficients when a species approaches depletion and any stiffness due to faster reactions. The non-negative Fully Implicit Stochastic {alpha} (FIS {alpha}) method in which stopped reaction channels due to depleted reactants are deleted until a reactant concentration rises again, for non-negativity preservation and in which a positive definite Jacobian is maintained to deal with possible stiffness, is proposed and analysed. The method is illustrated with the computation of active Protein Kinase C response in the Protein Kinase C pathway.
ISSN:0021-9991
1090-2716
DOI:10.1016/j.jcp.2011.07.032