A Model for Cell Proliferation in a Developing Organism

In mathematical biology, there is a great deal of interest in producing continuum models by scaling discrete agent-based models governed by local stochastic rules. We discuss a particular example of this approach: a model for the proliferation of neural crest cells that can help us understand the de...

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Bibliographic Details
Published in:Journal of mathematical biology 2022-06, Vol.84 (7), p.63-63, Article 63
Main Authors: Pollett, Philip K., Tafakori, Laleh, Taylor, Peter G.
Format: Article
Language:English
Subjects:
Applications of Mathematics
Cell proliferation
Colon
Continuum modeling
Enteric nervous system
Intestine
Markov analysis
Markov chains
Mathematical and Computational Biology
Mathematical models
Mathematics
Mathematics and Statistics
Nervous system
Neural crest
Partial differential equations
Stochastic processes
Stochasticity
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Summary:In mathematical biology, there is a great deal of interest in producing continuum models by scaling discrete agent-based models governed by local stochastic rules. We discuss a particular example of this approach: a model for the proliferation of neural crest cells that can help us understand the development of Hirschprung’s disease, a potentially-fatal condition in which the enteric nervous system of a new-born child does not extend all the way through the intestine and colon. Our starting point is a discrete-state, continuous-time Markov chain model proposed by Hywood et al. ( 2013a ) for the location of the neural crest cells that make up the enteric nervous system. Hywood et al. ( 2013a ) scaled their model to derive an approximate second order partial differential equation describing how the limiting expected number of neural crest cells evolve in space and time. In contrast, we exploit the relationship between the above-mentioned Markov chain model and the well-known Yule-Furry process to derive the exact form of the scaled version of the process. Furthermore, we provide expressions for other features of the domain agent occupancy process, such as the variance of the marginal occupancy at a particular site, the distribution of the number of agents that are yet to reach a given site and a stochastic description of the process itself.
ISSN:0303-6812
1432-1416
DOI:10.1007/s00285-022-01769-5