A framework for deriving analytic steady states of biochemical reaction networks

Hernandez, Bryan S.; Lubenia, Patrick Vincent N.; Johnston, Matthew D.; Kim, Jae Kyoung

doi:10.1371/journal.pcbi.1011039

PLoS Comput Biol

2023

DOI: 10.1371/journal.pcbi.1011039

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A framework for deriving analytic steady states of biochemical reaction networks

Bryan S. Hernandez

Patrick Vincent N. Lubenia²,

Matthew D. Johnston

et al.

Abstract: The long-term behaviors of biochemical systems are often described by their steady states. Deriving these states directly for complex networks arising from real-world applications, however, is often challenging. Recent work has consequently focused on network-based approaches. Specifically, biochemical reaction networks are transformed into weakly reversible and deficiency zero generalized networks, which allows the derivation of their analytic steady states. Identifying this transformation, however, can be ch… Show more

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Cited by 5 publications

References 42 publications

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Towards a Classification of Steady-State Bifurcations for Networks with Asymmetric Inputs

Aguiar,

Dias,

Soares

2024

J Nonlinear Sci

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We consider homogeneous coupled cell networks with asymmetric inputs. We obtain general results concerning codimension-one steady-state bifurcations for networks with any number of cells and any number of asymmetric inputs. These results rely solely on the network adjacency matrices eigenvalue structure and the existence, or not, of network synchrony subspaces. For networks with three cells, we describe the possible lattices of synchrony subspaces annotated with the eigenvalues on each synchrony subspace. Applying the previous results, we classify the synchrony-breaking steady-state bifurcations that can occur for three-cell minimal networks with one, two or six asymmetric inputs.

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Towards a Classification of Steady-State Bifurcations for Networks with Asymmetric Inputs

Aguiar,

Dias,

Soares

2024

J Nonlinear Sci

View full text Add to dashboard Cite

show abstract

A network-based parametrization of positive steady states of power-law kinetic systems

Hernandez,

Buendicho

2023

J Math Chem

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Positive steady states of a class of power law systems with independent decompositions

Alamin,

Hernandez

2024

J Math Chem

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A framework for deriving analytic steady states of biochemical reaction networks

Cited by 5 publications

References 42 publications

Towards a Classification of Steady-State Bifurcations for Networks with Asymmetric Inputs

Towards a Classification of Steady-State Bifurcations for Networks with Asymmetric Inputs

A network-based parametrization of positive steady states of power-law kinetic systems

Positive steady states of a class of power law systems with independent decompositions

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