Finite element modeling of diffusion and partitioning in biological systems: the infinite composite medium problem

Finite element modeling of diffusion and partitioning in biological systems: the infinite composite medium problem

Four methods are proposed for modeling diffusion in heterogeneous media where diffusion and partition coefficients take on differing values in each subregion. The exercise was conducted to validate finite element modeling (FEM) procedures in anticipation of modeling drug diffusion with regional part...

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Bibliographic Details
Published in:Annals of biomedical engineering Vol. 28; no. 11; pp. 1307 - 1317
Main Author: Missel, P J
Format: Journal Article
Language:English
Published: United States Springer Nature B.V 01-11-2000
Subjects:
Biological Transport, Active
Biomedical Engineering
Boundary conditions
Chemical potential
Diffusion
Finite element method
Humans
Injections
Mathematical models
Models, Biological
Molecular weight
Pharmacokinetics
Retina - metabolism
Software
Studies
Tissue
Vitreous Body - metabolism
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Summary:Four methods are proposed for modeling diffusion in heterogeneous media where diffusion and partition coefficients take on differing values in each subregion. The exercise was conducted to validate finite element modeling (FEM) procedures in anticipation of modeling drug diffusion with regional partitioning into ocular tissue, though the approach can be useful for other organs, or for modeling diffusion in laminate devices. Partitioning creates a discontinuous value in the dependent variable (concentration) at an intertissue boundary that is not easily handled by available general-purpose FEM codes, which allow for only one value at each node. The discontinuity is handled using a transformation on the dependent variable based upon the region-specific partition coefficient. Methods were evaluated by their ability to reproduce a known exact result, for the problem of the infinite composite medium (Crank, J. The Mathematics of Diffusion, 2nd ed. New York: Oxford University Press, 1975, pp. 38-39.). The most physically intuitive method is based upon the concept of chemical potential, which is continuous across an interphase boundary (method III). This method makes the equation of the dependent variable highly nonlinear. This can be linearized easily by a change of variables (method IV). Results are also given for a one-dimensional problem simulating bolus injection into the vitreous, predicting time disposition of drug in vitreous and retina.
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ISSN:0090-6964
1573-9686
DOI:10.1114/1.1329886