1. Simulation and inference algorithms for stochastic biochemical reaction networks: from basic concepts to state-of-the-art
- Author
-
Ruth E. Baker, Matthew J. Simpson, and David J. Warne
- Subjects
0301 basic medicine ,060114 Systems Biology ,Computer science ,Stochastic modelling ,Molecular Networks (q-bio.MN) ,010406 Stochastic Analysis and Modelling ,Biomedical Engineering ,Biophysics ,Inference ,Bioengineering ,Models, Biological ,01 natural sciences ,Biochemistry ,010401 Applied Statistics ,Biomaterials ,approximate Bayesian computation ,010104 statistics & probability ,03 medical and health sciences ,Quantitative Biology - Molecular Networks ,0101 mathematics ,Monte Carlo ,Review Articles ,Network model ,Stochastic Processes ,Interpretation (logic) ,Systems Biology ,Probabilistic logic ,010202 Biological Mathematics ,stochastic simulation ,Complex dynamics ,030104 developmental biology ,FOS: Biological sciences ,Key (cryptography) ,Bayesian Inference ,biochemical reaction networks ,Likelihood function ,Algorithm ,Algorithms ,010402 Biostatistics ,Signal Transduction ,Biotechnology - Abstract
Stochasticity is a key characteristic of intracellular processes such as gene regulation and chemical signalling. Therefore, characterizing stochastic effects in biochemical systems is essential to understand the complex dynamics of living things. Mathematical idealizations of biochemically reacting systems must be able to capture stochastic phenomena. While robust theory exists to describe such stochastic models, the computational challenges in exploring these models can be a significant burden in practice since realistic models are analytically intractable. Determining the expected behaviour and variability of a stochastic biochemical reaction network requires many probabilistic simulations of its evolution. Using a biochemical reaction network model to assist in the interpretation of time-course data from a biological experiment is an even greater challenge due to the intractability of the likelihood function for determining observation probabilities. These computational challenges have been subjects of active research for over four decades. In this review, we present an accessible discussion of the major historical developments and state-of-the-art computational techniques relevant to simulation and inference problems for stochastic biochemical reaction network models. Detailed algorithms for particularly important methods are described and complemented with Matlab®implementations. As a result, this review provides a practical and accessible introduction to computational methods for stochastic models within the life sciences community.
- Published
- 2019