Litcius/Paper detail

Modular dynamic biomolecular modelling with bond graphs: the unification of stoichiometry, thermodynamics, kinetics and data

P.J. Gawthrop, Michael Pan, Edmund J. Crampin

2021Journal of The Royal Society Interface20 citationsDOIOpen Access PDF

Abstract

Renewed interest in dynamic simulation models of biomolecular systems has arisen from advances in genome-wide measurement and applications of such models in biotechnology and synthetic biology. In particular, genome-scale models of cellular metabolism beyond the steady state are required in order to represent transient and dynamic regulatory properties of the system. Development of such whole-cell models requires new modelling approaches. Here, we propose the energy-based bond graph methodology, which integrates stoichiometric models with thermodynamic principles and kinetic modelling. We demonstrate how the bond graph approach intrinsically enforces thermodynamic constraints, provides a modular approach to modelling, and gives a basis for estimation of model parameters leading to dynamic models of biomolecular systems. The approach is illustrated using a well-established stoichiometric model of Escherichia coli and published experimental data.

Topics & Concepts

Bond graphModular designUnificationSystems biologyBiological systemComputer scienceSynthetic biologyComputationBiochemical engineeringStatistical physicsComputational biologyPhysicsBiologyMathematicsAlgorithmEngineeringProgramming languageCombinatoricsOperating systemMicrobial Metabolic Engineering and BioproductionGene Regulatory Network AnalysisATP Synthase and ATPases Research