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Generation of multicellular spatiotemporal models of population dynamics from ordinary differential equations, with applications in viral infection
- Source :
- BMC Biology, Vol 19, Iss 1, Pp 1-24 (2021), BMC Biology
- Publication Year :
- 2021
- Publisher :
- BMC, 2021.
-
Abstract
- Background The biophysics of an organism span multiple scales from subcellular to organismal and include processes characterized by spatial properties, such as the diffusion of molecules, cell migration, and flow of intravenous fluids. Mathematical biology seeks to explain biophysical processes in mathematical terms at, and across, all relevant spatial and temporal scales, through the generation of representative models. While non-spatial, ordinary differential equation (ODE) models are often used and readily calibrated to experimental data, they do not explicitly represent the spatial and stochastic features of a biological system, limiting their insights and applications. However, spatial models describing biological systems with spatial information are mathematically complex and computationally expensive, which limits the ability to calibrate and deploy them and highlights the need for simpler methods able to model the spatial features of biological systems. Results In this work, we develop a formal method for deriving cell-based, spatial, multicellular models from ODE models of population dynamics in biological systems, and vice versa. We provide examples of generating spatiotemporal, multicellular models from ODE models of viral infection and immune response. In these models, the determinants of agreement of spatial and non-spatial models are the degree of spatial heterogeneity in viral production and rates of extracellular viral diffusion and decay. We show how ODE model parameters can implicitly represent spatial parameters, and cell-based spatial models can generate uncertain predictions through sensitivity to stochastic cellular events, which is not a feature of ODE models. Using our method, we can test ODE models in a multicellular, spatial context and translate information to and from non-spatial and spatial models, which help to employ spatiotemporal multicellular models using calibrated ODE model parameters. We additionally investigate objects and processes implicitly represented by ODE model terms and parameters and improve the reproducibility of spatial, stochastic models. Conclusion We developed and demonstrate a method for generating spatiotemporal, multicellular models from non-spatial population dynamics models of multicellular systems. We envision employing our method to generate new ODE model terms from spatiotemporal and multicellular models, recast popular ODE models on a cellular basis, and generate better models for critical applications where spatial and stochastic features affect outcomes.
- Subjects :
- Physiology
Stochastic modelling
QH301-705.5
Population
Population Dynamics
Plant Science
Biology
Models, Biological
General Biochemistry, Genetics and Molecular Biology
Structural Biology
Humans
Computer Simulation
Multiscale modeling
Biology (General)
education
Spatial analysis
Ecology, Evolution, Behavior and Systematics
Spatial contextual awareness
Mathematical and theoretical biology
education.field_of_study
Ode
Reproducibility of Results
Cell Biology
Virus Diseases
Agent-based modeling
Ordinary differential equation
Multicellular systems
General Agricultural and Biological Sciences
Biological system
Developmental Biology
Biotechnology
Research Article
Subjects
Details
- Language :
- English
- ISSN :
- 17417007
- Volume :
- 19
- Issue :
- 1
- Database :
- OpenAIRE
- Journal :
- BMC Biology
- Accession number :
- edsair.doi.dedup.....acf85d0565a3384d8102fdf555ed9b9b