Deterministic and stochastic models of enzymatic networks-applications to pharmaceutical research
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Publication:929149
DOI10.1016/j.camwa.2006.12.092zbMath1137.92014OpenAlexW2145323026MaRDI QIDQ929149
Loretta Mastroeni, Alberto Maria Bersani, Enrico Bersani
Publication date: 12 June 2008
Published in: Computers \& Mathematics with Applications (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1016/j.camwa.2006.12.092
Dynamical systems in biology (37N25) Signal detection and filtering (aspects of stochastic processes) (60G35) Kinetics in biochemical problems (pharmacokinetics, enzyme kinetics, etc.) (92C45) Medical applications (general) (92C50)
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Cites Work
- Michaelis-Menten kinetics at high enzyme concentrations
- Quasi steady-state approximations in complex intracellular signal transduction networks - a word of caution
- Time-dependent closed form solutions for fully competitive enzyme reactions
- Stochastic simulation of chemical reactions in spatially complex media
- The total quasi-steady-state approximation for complex enzyme reactions
- On the validity of the steady state assumption of enzyme kinetics
- Extending the quasi-steady state approximation by changing variables
- The total quasi-steady-state approximation is valid for reversible enzyme kinetics
- The total quasi-steady-state approximation for fully competitive enzyme reactions
- Stochastic approaches for modelling in vivo reactions
- Multistationarity, the basis of cell differentiation and memory. I. Structural conditions of multistationarity and other nontrivial behavior
- The Quasi-Steady-State Assumption: A Case Study in Perturbation
- Stochastic approach to chemical kinetics
- Brownian motion in a field of force and the diffusion model of chemical reactions
