Realizations of kinetic differential equations

Gheorghe Craciun; Matthew D. Johnston; Gábor Szederkényi; Elisa Tonello; János Tóth; Polly Y. Yu

doi:10.3934/mbe.2020046

Realizations of kinetic differential equations

Gheorghe Craciun
, Matthew D. Johnston
, Gábor Szederkényi
, Elisa Tonello
, János Tóth
, Polly Y. Yu

Research output: Contribution to journal › Article › peer-review

Abstract

The induced kinetic differential equations of a reaction network endowed with mass action type kinetics is a system of polynomial differential equations. The problem studied here is: Given a system of polynomial differential equations, is it possible to find a network which induces these equations; in other words: is it possible to find a kinetic realization of this system of differential equations? If yes, can we find a network with some chemically relevant properties (implying also important dynamic consequences), such as reversibility, weak reversibility, zero deficiency, detailed balancing, complex balancing, mass conservation, etc.? The constructive answers presented to a series of questions of the above type are useful when fitting differential equations to datasets, or when trying to find out the dynamic behavior of the solutions of differential equations. It turns out that some of these results can be applied when trying to solve seemingly unrelated mathematical problems, like the existence of positive solutions to algebraic equations.

Original language	English (US)
Pages (from-to)	862-892
Number of pages	31
Journal	Mathematical Biosciences and Engineering
Volume	17
Issue number	1
DOIs	https://doi.org/10.3934/mbe.2020046
State	Published - 2020
Externally published	Yes

Keywords

Kinetic equations
Mass action kinetics
Reaction networks
Realizations
Reversibility
Weak reversibility

ASJC Scopus subject areas

Modeling and Simulation
General Agricultural and Biological Sciences
Computational Mathematics
Applied Mathematics

Online availability

10.3934/mbe.2020046

Library availability

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@article{ef28a9da0b384100be5720819595aef0,

title = "Realizations of kinetic differential equations",

abstract = "The induced kinetic differential equations of a reaction network endowed with mass action type kinetics is a system of polynomial differential equations. The problem studied here is: Given a system of polynomial differential equations, is it possible to find a network which induces these equations; in other words: is it possible to find a kinetic realization of this system of differential equations? If yes, can we find a network with some chemically relevant properties (implying also important dynamic consequences), such as reversibility, weak reversibility, zero deficiency, detailed balancing, complex balancing, mass conservation, etc.? The constructive answers presented to a series of questions of the above type are useful when fitting differential equations to datasets, or when trying to find out the dynamic behavior of the solutions of differential equations. It turns out that some of these results can be applied when trying to solve seemingly unrelated mathematical problems, like the existence of positive solutions to algebraic equations.",

keywords = "Kinetic equations, Mass action kinetics, Reaction networks, Realizations, Reversibility, Weak reversibility",

author = "Gheorghe Craciun and Johnston, \{Matthew D.\} and G{\'a}bor Szederk{\'e}nyi and Elisa Tonello and J{\'a}nos T{\'o}th and Yu, \{Polly Y.\}",

note = "The authors started to work on this paper when enjoying the hospitality of the Erwin Schr{\"o}dinger Institut in Vienna as participants of the meeting Advances in Chemical Reaction Network Theory, 15– 19 October, 2018. G{\'a}bor Szederk{\'e}nyi and J{\'a}nos T{\'o}th thank the support of the National Research, Development, and Innovation Office, Hungary (SNN 125739). Gheorghe Craciun and Polly Y. Yu have been supported by National Science Foundation grant DMS-1816238. Polly Y. Yu also by the Natural Sciences and Engineering Research Council of Canada. Elisa Tonello was supported by the Volkswagen Stiftung (Volkswagen Foundation) under the funding initiative Life? - A fresh scientific approach to the basic principles of life (project ID: 93063). We utilized the detailed comments of the reviewers gratefully. The authors started to work on this paper when enjoying the hospitality of the Erwin Schr{\"o}dinger Institut in Vienna as participants of the meeting Advances in Chemical Reaction Network Theory, 15- 19 October, 2018. G{\'a}bor Szederk{\'e}nyi and J{\'a}nos T{\'o}th thank the support of the National Research, Development, and Innovation Office, Hungary (SNN 125739). Gheorghe Craciun and Polly Y. Yu have been supported by National Science Foundation grant DMS-1816238. Polly Y. Yu also by the Natural Sciences and Engineering Research Council of Canada. Elisa Tonello was supported by the Volkswagen Stiftung (Volkswagen Foundation) under the funding initiative Life? - A fresh scientific approach to the basic principles of life (project ID: 93063). We utilized the detailed comments of the reviewers gratefully.",

year = "2020",

doi = "10.3934/mbe.2020046",

language = "English (US)",

volume = "17",

pages = "862--892",

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AU - Craciun, Gheorghe

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AU - Szederkényi, Gábor

AU - Tonello, Elisa

AU - Tóth, János

AU - Yu, Polly Y.

N1 - The authors started to work on this paper when enjoying the hospitality of the Erwin Schrödinger Institut in Vienna as participants of the meeting Advances in Chemical Reaction Network Theory, 15– 19 October, 2018. Gábor Szederkényi and János Tóth thank the support of the National Research, Development, and Innovation Office, Hungary (SNN 125739). Gheorghe Craciun and Polly Y. Yu have been supported by National Science Foundation grant DMS-1816238. Polly Y. Yu also by the Natural Sciences and Engineering Research Council of Canada. Elisa Tonello was supported by the Volkswagen Stiftung (Volkswagen Foundation) under the funding initiative Life? - A fresh scientific approach to the basic principles of life (project ID: 93063). We utilized the detailed comments of the reviewers gratefully. The authors started to work on this paper when enjoying the hospitality of the Erwin Schrödinger Institut in Vienna as participants of the meeting Advances in Chemical Reaction Network Theory, 15- 19 October, 2018. Gábor Szederkényi and János Tóth thank the support of the National Research, Development, and Innovation Office, Hungary (SNN 125739). Gheorghe Craciun and Polly Y. Yu have been supported by National Science Foundation grant DMS-1816238. Polly Y. Yu also by the Natural Sciences and Engineering Research Council of Canada. Elisa Tonello was supported by the Volkswagen Stiftung (Volkswagen Foundation) under the funding initiative Life? - A fresh scientific approach to the basic principles of life (project ID: 93063). We utilized the detailed comments of the reviewers gratefully.

PY - 2020

Y1 - 2020

N2 - The induced kinetic differential equations of a reaction network endowed with mass action type kinetics is a system of polynomial differential equations. The problem studied here is: Given a system of polynomial differential equations, is it possible to find a network which induces these equations; in other words: is it possible to find a kinetic realization of this system of differential equations? If yes, can we find a network with some chemically relevant properties (implying also important dynamic consequences), such as reversibility, weak reversibility, zero deficiency, detailed balancing, complex balancing, mass conservation, etc.? The constructive answers presented to a series of questions of the above type are useful when fitting differential equations to datasets, or when trying to find out the dynamic behavior of the solutions of differential equations. It turns out that some of these results can be applied when trying to solve seemingly unrelated mathematical problems, like the existence of positive solutions to algebraic equations.

AB - The induced kinetic differential equations of a reaction network endowed with mass action type kinetics is a system of polynomial differential equations. The problem studied here is: Given a system of polynomial differential equations, is it possible to find a network which induces these equations; in other words: is it possible to find a kinetic realization of this system of differential equations? If yes, can we find a network with some chemically relevant properties (implying also important dynamic consequences), such as reversibility, weak reversibility, zero deficiency, detailed balancing, complex balancing, mass conservation, etc.? The constructive answers presented to a series of questions of the above type are useful when fitting differential equations to datasets, or when trying to find out the dynamic behavior of the solutions of differential equations. It turns out that some of these results can be applied when trying to solve seemingly unrelated mathematical problems, like the existence of positive solutions to algebraic equations.

KW - Kinetic equations

KW - Mass action kinetics

KW - Reaction networks

KW - Realizations

KW - Reversibility

KW - Weak reversibility

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SN - 1547-1063

VL - 17

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EP - 892

JO - Mathematical Biosciences and Engineering

JF - Mathematical Biosciences and Engineering

IS - 1

ER -

Realizations of kinetic differential equations

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Keywords

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