Assessment of the retinal pigment epithelial functions‐ modelling approach

Purpose Our purpose is to construct mathematical models of functions of retinal pigment epithelium (RPE). Here we show the development and results of two models: 1) a compartmental model of Ca2+ dynamics 2) finite element model of epithelial transport and trans‐epithelial resistance. Methods A model...

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Veröffentlicht in:	Acta ophthalmologica (Oxford, England) England), 2012-09, Vol.90 (s249), p.0-0
Hauptverfasser:	HYTTINEN, J, VAINIO, I, KHAMIDAKH, A, JUUTI‐UUSITALO, K, LUUKKANEN, H, SKOTTMAN, H, NYMARK, S
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Schlagworte:	Cellular biology Mathematical models Ophthalmology
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creator	HYTTINEN, J VAINIO, I KHAMIDAKH, A JUUTI‐UUSITALO, K LUUKKANEN, H SKOTTMAN, H NYMARK, S
description	Purpose Our purpose is to construct mathematical models of functions of retinal pigment epithelium (RPE). Here we show the development and results of two models: 1) a compartmental model of Ca2+ dynamics 2) finite element model of epithelial transport and trans‐epithelial resistance. Methods A model of Ca2+ dynamics of APRE‐19 cells based on an experimental data and literature was constructed. Ca+2 dynamics of APRE‐19 cells were recorded using fluorescent microscope after mechanical stimulation. Various Ca+2 functional conditions were tested. The computational model constructed (Matlab SimBiology ) comprises over 40 cell function parameters and twelve variables ranging from stretch‐sensitive ion channels to ryanodine receptor dynamics and sarco/endoplasmic reticulum ATPases. Further, a model of RPE epithelia barrier was developed based on finite element modelling (FEM) of the epithelia and trans‐epithelial resistance simulating the spatial distribution of epithelial properties originating of the tight junction distribution on epithelia. Results The Ca+2 kinetics model of RPE was able to reproduce the Ca+2 dynamics of APRE cells with high accuracy with above 0.97 cross‐correlation. Further, including stretch‐sensitive ion channels explained the Ca+2 dynamics of the cells close to the mechanically stimulated cell. The epithelial model showed that epithelial inhomogeneity may play a crucial role in epithelial tightness and even very small cellular changes produce large variation on the measures of the epithelial properties. Conclusion The models constructed provide new insight of the functions of the RPE with applications from drug transport studies to assessment of the functionality of stem cell derived RPE.
doi_str_mv	10.1111/j.1755-3768.2012.4485.x
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Here we show the development and results of two models: 1) a compartmental model of Ca2+ dynamics 2) finite element model of epithelial transport and trans‐epithelial resistance. Methods A model of Ca2+ dynamics of APRE‐19 cells based on an experimental data and literature was constructed. Ca+2 dynamics of APRE‐19 cells were recorded using fluorescent microscope after mechanical stimulation. Various Ca+2 functional conditions were tested. The computational model constructed (Matlab SimBiology ) comprises over 40 cell function parameters and twelve variables ranging from stretch‐sensitive ion channels to ryanodine receptor dynamics and sarco/endoplasmic reticulum ATPases. Further, a model of RPE epithelia barrier was developed based on finite element modelling (FEM) of the epithelia and trans‐epithelial resistance simulating the spatial distribution of epithelial properties originating of the tight junction distribution on epithelia. Results The Ca+2 kinetics model of RPE was able to reproduce the Ca+2 dynamics of APRE cells with high accuracy with above 0.97 cross‐correlation. Further, including stretch‐sensitive ion channels explained the Ca+2 dynamics of the cells close to the mechanically stimulated cell. The epithelial model showed that epithelial inhomogeneity may play a crucial role in epithelial tightness and even very small cellular changes produce large variation on the measures of the epithelial properties. 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Here we show the development and results of two models: 1) a compartmental model of Ca2+ dynamics 2) finite element model of epithelial transport and trans‐epithelial resistance. Methods A model of Ca2+ dynamics of APRE‐19 cells based on an experimental data and literature was constructed. Ca+2 dynamics of APRE‐19 cells were recorded using fluorescent microscope after mechanical stimulation. Various Ca+2 functional conditions were tested. The computational model constructed (Matlab SimBiology ) comprises over 40 cell function parameters and twelve variables ranging from stretch‐sensitive ion channels to ryanodine receptor dynamics and sarco/endoplasmic reticulum ATPases. Further, a model of RPE epithelia barrier was developed based on finite element modelling (FEM) of the epithelia and trans‐epithelial resistance simulating the spatial distribution of epithelial properties originating of the tight junction distribution on epithelia. Results The Ca+2 kinetics model of RPE was able to reproduce the Ca+2 dynamics of APRE cells with high accuracy with above 0.97 cross‐correlation. Further, including stretch‐sensitive ion channels explained the Ca+2 dynamics of the cells close to the mechanically stimulated cell. The epithelial model showed that epithelial inhomogeneity may play a crucial role in epithelial tightness and even very small cellular changes produce large variation on the measures of the epithelial properties. 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Here we show the development and results of two models: 1) a compartmental model of Ca2+ dynamics 2) finite element model of epithelial transport and trans‐epithelial resistance. Methods A model of Ca2+ dynamics of APRE‐19 cells based on an experimental data and literature was constructed. Ca+2 dynamics of APRE‐19 cells were recorded using fluorescent microscope after mechanical stimulation. Various Ca+2 functional conditions were tested. The computational model constructed (Matlab SimBiology ) comprises over 40 cell function parameters and twelve variables ranging from stretch‐sensitive ion channels to ryanodine receptor dynamics and sarco/endoplasmic reticulum ATPases. Further, a model of RPE epithelia barrier was developed based on finite element modelling (FEM) of the epithelia and trans‐epithelial resistance simulating the spatial distribution of epithelial properties originating of the tight junction distribution on epithelia. Results The Ca+2 kinetics model of RPE was able to reproduce the Ca+2 dynamics of APRE cells with high accuracy with above 0.97 cross‐correlation. Further, including stretch‐sensitive ion channels explained the Ca+2 dynamics of the cells close to the mechanically stimulated cell. The epithelial model showed that epithelial inhomogeneity may play a crucial role in epithelial tightness and even very small cellular changes produce large variation on the measures of the epithelial properties. Conclusion The models constructed provide new insight of the functions of the RPE with applications from drug transport studies to assessment of the functionality of stem cell derived RPE.</abstract><cop>Oxford, UK</cop><pub>Blackwell Publishing Ltd</pub><doi>10.1111/j.1755-3768.2012.4485.x</doi><tpages>1</tpages></addata></record>
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title	Assessment of the retinal pigment epithelial functions‐ modelling approach
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