A computational approach to linear conjugacy in a class of power law kinetic systems

Cortez, Mark Jayson; Nazareno, Allen L.; Mendoza, Eduardo

doi:10.1007/s10910-017-0796-y

Cited by 3 publications

(7 citation statements)

References 17 publications

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“…Savageau [15] and Voit [18,19] highlighted the advantages of using power-law formalism for modelling biochemical systems. In this light, many CRN-based results on PLK systems are established ( [6,11,13,17] among others), some of which are extensions or modifications of existing results on MAK systems.…”

Section: Introductionmentioning

confidence: 99%

A Deficiency-One Algorithm for power-law kinetic systems with reactant-determined interactions

et al. 2018

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Robustness against the presence of environmental disruptions can be observed in many systems of chemical reaction network. However, identifying the underlying components of a system that give rise to robustness is often elusive. The influential work of Shinar and Feinberg established simple yet subtle network-based conditions for absolute concentration robustness (ACR), a phenomena in which a species in a mass-action system has the same concentration for any steady state the network may admit. In this contribution, we extend this result to embrace kinetic systems more general than mass-action systems, namely, powerlaw kinetic systems with reactant-determined interactions (denoted by "PL-RDK"). In PL-RDK, the kinetic order vectors (which we call "interactions") of reactions with the same reactant complex are identical. As illustration, we considered a scenario in the pre-industrial state of global carbon cycle. A power-law approximation of the dynamical system of this scenario is found to be dynamically equivalent to an ACR-possessing PL-RDK system.

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Section: Introductionmentioning

confidence: 99%

A Deficiency-One Algorithm for power-law kinetic systems with reactant-determined interactions

et al. 2018

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“…Different networks could generate the same set of ODEs making them dynamically equivalent. In the past few years, various authors have pioneered the use of MILP algorithms for determining linear conjugacy between MAK systems (5 , 13 , 25 , 27 ), between rational functions systems (26 ), between GMAK systems (28 ) and between PL-RDK systems (7 ). In the work of (7 ), they extended the JSC for linear conjugacy from MAK systems to PL-RDK systems.…”

Section: Resultsmentioning

confidence: 99%

“…In relation to linear conjugacy, if the mapping h is trivial, M and M are said to be dynamically equivalent (7 ) .…”

Section: Fundamentals Of Chemical Kinetic Systemsmentioning

confidence: 99%

“…The sparse linear conjugate of (N * , K * ) was obtained using the MILP algorithm, described in (7 ). The algorithm seeks to generate linearly conjugate realizations for a class of power-law kinetic systems, i.e., PL-RDK.…”

Section: A Solution To the Linear Conjugacy Problem Of Rid Kinetic Sy...mentioning

confidence: 99%

“…The three groups then collaborated in extending the MILP approach to linear conjugacy (a detailed discussion of the work up to 2013 can be found in (5 )). Further developments included the extension to "Bio-CRNs" (whose rate functions are mass action functions divided by positive polynomials in the species variables) by Gábor et al (6 ) and to complex factorizable power law kinetic systems (denoted by PL-RDK) by Cortez et al (7 ).…”

Section: Introductionmentioning

confidence: 99%

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Linear conjugacy of chemical kinetic systems

Nazareno

Eclarin

Mendoza

et al. 2019

Mathematical Biosciences and Engineering

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Two networks are said to be linearly conjugate if the solution of their dynamic equations can be transformed into each other by a positive linear transformation. The study on dynamical equivalence in chemical kinetic systems was initiated by Craciun and Pantea in 2008 and eventually led to the Johnston-Siegel Criterion for linear conjugacy (JSC). Several studies have applied Mixed Integer Linear Programming (MILP) approach to generate linear conjugates of MAK (mass action kinetic) systems, Bio-CRNs (which is a subset of hill-type kinetic systems when the network is restricted to digraphs), and PL-RDK (complex factorizable power law kinetic) systems. In this study, we present a general computational solution to construct linear conjugates of any "rate constant-interaction function decomposable" (RID) chemical kinetic systems, wherein each of its rate function is the product of a rate constant and an interaction function. We generate an extension of the JSC to the complex factorizable (CF) subset of RID kinetic systems and show that any noncomplex factorizable (NF) RID kinetic system can be dynamically equivalent to a CF system via transformation. We show that linear conjugacy can be generated for any RID kinetic systems by applying the JSC to any NF kinetic system that are transformed to CF kinetic system.In the definition, c ∧ d is the bivector of c and d in the exterior algebra of R S . Once a kinetics is associated with a CRN, we can determine the rate at which the concentration of each species evolves at composition c.Power-law kinetics is defined by an r × m matrix F = [Fij], called the kinetic order matrix, and vector k ∈ R R , called the rate vector. In power-law formalism, the kinetic orders of the species concentrations are real numbers.Definition 7. A kinetics K : R S > → R R is a power-law kinetics (PLK) ifKi(x) = kix F i ∀i = 1, ..., r

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