Agent-based computational modeling of wounded epithelial cell monolayers

D C Walker; G Hill; S M Wood; R H Smallwood; J Southgate

doi:10.1109/TNB.2004.833680

Agent-based computational modeling of wounded epithelial cell monolayers

D C Walker, G Hill, S M Wood, R H Smallwood, J Southgate

Jack Birch Unit

Research output: Contribution to journal › Article › peer-review

Abstract

Computational modeling of biological systems, or in silico biology, is an emerging tool for understanding structure and order in biological tissues. Computational models of the behavior of epithelial cells in monolayer cell culture have been developed and used to predict the healing characteristics of scratch wounds made to urothelial cell cultures maintained in low- and physiological [Ca2+] environments. Both computational models and in vitro experiments demonstrated that in low exogenous [Ca2+], the closure of 500-mum scratch wounds was achieved primarily by cell migration into the denuded area. The wound healing rate in low (0.09 mM) [Ca2+] was approximately twice as rapid as in physiological (2 mM) [Ca2+]. Computational modeling predicted that in cell cultures that are actively proliferating, no increase in the fraction of cells in the S-phase would be expected, and this conclusion was supported experimentally in vitro by bromodeoxyuridine incorporation assay. We have demonstrated that a simple rule-based model of cell behavior, incorporating rules relating to contact inhibition of proliferation and migration, is sufficient to qualitatively predict the calcium-dependent pattern of wound closure observed in vitro. Differences between the in vitro and in silico models suggest a role for wound-induced signaling events in urothelial cell cultures.

Original language	English
Pages (from-to)	153-163
Number of pages	11
Journal	IEEE Transactions on NanoBioscience
Volume	3
Issue number	3
DOIs	https://doi.org/10.1109/TNB.2004.833680
Publication status	Published - Sept 2004

Keywords

calcium
computational modeling
emergent structure
urinary epithelium
wound healing
HUMAN UROTHELIAL CELLS
EPIDERMAL-CELLS
IN-VITRO
GROWTH
DIFFERENTIATION
PROLIFERATION
ADHESION
CULTURE
MECHANISMS
MOTILITY

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10.1109/TNB.2004.833680

Cite this

@article{ac1729de83da465f86ddebdc4ba1505f,

title = "Agent-based computational modeling of wounded epithelial cell monolayers",

abstract = "Computational modeling of biological systems, or in silico biology, is an emerging tool for understanding structure and order in biological tissues. Computational models of the behavior of epithelial cells in monolayer cell culture have been developed and used to predict the healing characteristics of scratch wounds made to urothelial cell cultures maintained in low- and physiological [Ca2+] environments. Both computational models and in vitro experiments demonstrated that in low exogenous [Ca2+], the closure of 500-mum scratch wounds was achieved primarily by cell migration into the denuded area. The wound healing rate in low (0.09 mM) [Ca2+] was approximately twice as rapid as in physiological (2 mM) [Ca2+]. Computational modeling predicted that in cell cultures that are actively proliferating, no increase in the fraction of cells in the S-phase would be expected, and this conclusion was supported experimentally in vitro by bromodeoxyuridine incorporation assay. We have demonstrated that a simple rule-based model of cell behavior, incorporating rules relating to contact inhibition of proliferation and migration, is sufficient to qualitatively predict the calcium-dependent pattern of wound closure observed in vitro. Differences between the in vitro and in silico models suggest a role for wound-induced signaling events in urothelial cell cultures.",

keywords = "calcium, computational modeling, emergent structure, urinary epithelium, wound healing, HUMAN UROTHELIAL CELLS, EPIDERMAL-CELLS, IN-VITRO, GROWTH, DIFFERENTIATION, PROLIFERATION, ADHESION, CULTURE, MECHANISMS, MOTILITY",

author = "Walker, {D C} and G Hill and Wood, {S M} and Smallwood, {R H} and J Southgate",

year = "2004",

month = sep,

doi = "10.1109/TNB.2004.833680",

language = "English",

volume = "3",

pages = "153--163",

journal = "IEEE Transactions on NanoBioscience",

issn = "1536-1241",

publisher = "IEEE",

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TY - JOUR

T1 - Agent-based computational modeling of wounded epithelial cell monolayers

AU - Walker, D C

AU - Hill, G

AU - Wood, S M

AU - Smallwood, R H

AU - Southgate, J

PY - 2004/9

Y1 - 2004/9

N2 - Computational modeling of biological systems, or in silico biology, is an emerging tool for understanding structure and order in biological tissues. Computational models of the behavior of epithelial cells in monolayer cell culture have been developed and used to predict the healing characteristics of scratch wounds made to urothelial cell cultures maintained in low- and physiological [Ca2+] environments. Both computational models and in vitro experiments demonstrated that in low exogenous [Ca2+], the closure of 500-mum scratch wounds was achieved primarily by cell migration into the denuded area. The wound healing rate in low (0.09 mM) [Ca2+] was approximately twice as rapid as in physiological (2 mM) [Ca2+]. Computational modeling predicted that in cell cultures that are actively proliferating, no increase in the fraction of cells in the S-phase would be expected, and this conclusion was supported experimentally in vitro by bromodeoxyuridine incorporation assay. We have demonstrated that a simple rule-based model of cell behavior, incorporating rules relating to contact inhibition of proliferation and migration, is sufficient to qualitatively predict the calcium-dependent pattern of wound closure observed in vitro. Differences between the in vitro and in silico models suggest a role for wound-induced signaling events in urothelial cell cultures.

AB - Computational modeling of biological systems, or in silico biology, is an emerging tool for understanding structure and order in biological tissues. Computational models of the behavior of epithelial cells in monolayer cell culture have been developed and used to predict the healing characteristics of scratch wounds made to urothelial cell cultures maintained in low- and physiological [Ca2+] environments. Both computational models and in vitro experiments demonstrated that in low exogenous [Ca2+], the closure of 500-mum scratch wounds was achieved primarily by cell migration into the denuded area. The wound healing rate in low (0.09 mM) [Ca2+] was approximately twice as rapid as in physiological (2 mM) [Ca2+]. Computational modeling predicted that in cell cultures that are actively proliferating, no increase in the fraction of cells in the S-phase would be expected, and this conclusion was supported experimentally in vitro by bromodeoxyuridine incorporation assay. We have demonstrated that a simple rule-based model of cell behavior, incorporating rules relating to contact inhibition of proliferation and migration, is sufficient to qualitatively predict the calcium-dependent pattern of wound closure observed in vitro. Differences between the in vitro and in silico models suggest a role for wound-induced signaling events in urothelial cell cultures.

KW - calcium

KW - computational modeling

KW - emergent structure

KW - urinary epithelium

KW - wound healing

KW - HUMAN UROTHELIAL CELLS

KW - EPIDERMAL-CELLS

KW - IN-VITRO

KW - GROWTH

KW - DIFFERENTIATION

KW - PROLIFERATION

KW - ADHESION

KW - CULTURE

KW - MECHANISMS

KW - MOTILITY

U2 - 10.1109/TNB.2004.833680

DO - 10.1109/TNB.2004.833680

M3 - Article

SN - 1536-1241

VL - 3

SP - 153

EP - 163

JO - IEEE Transactions on NanoBioscience

JF - IEEE Transactions on NanoBioscience

IS - 3

ER -