Immobilized Particles in Gel Matrix-Type Porous Media. Nonhomogeneous Cell Distribution

The conventional random pore model assumes a homogeneous cell distribution in the gel matrix used to immobilize cells. However, the validity of this model is restricted to values of the exponent α, between 1.8 and 2.25, of a model power function relating the diffusivity coefficient in the matrix wit...

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Bibliographic Details
Published in:Biotechnology progress 2002, Vol.18 (4), p.807-814
Main Authors: Mota, Manuel, Teixeira, José A., Yelshin, Alexander
Format: Article
Language:English
Subjects:
Anisotropy
Biological and medical sciences
Biotechnology
Cell Count
Cells, Immobilized - cytology
Culture Media - chemistry
Diffusion
Fermentation
Fundamental and applied biological sciences. Psychology
Gels - chemistry
Immobilization of organelles and whole cells
Immobilization techniques
Methods. Procedures. Technologies
Models, Chemical
Oxygen - metabolism
Porosity
Reproducibility of Results
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Summary:The conventional random pore model assumes a homogeneous cell distribution in the gel matrix used to immobilize cells. However, the validity of this model is restricted to values of the exponent α, between 1.8 and 2.25, of a model power function relating the diffusivity coefficient in the matrix with the overall cell volume fraction in the system. Based on the analysis of published data for diffusion in gels with immobilized cells and on the homogeneous approach for the random pore model developed in a previous work, a new, nonhomogeneous approach is proposed for αvalues outside the range 1.8–2.25. To explain these data, two main types of nonhomogeneous cell distribution were considered: (1) nonhomogeneous cell distribution in the gel for α > 2.25 (type 1) and (2) nonhomogeneity related with anisotropy of cell space orientation when α < 1.8 (type 2). In the case of nonhomogeneity of type 1, the cell volume fraction in the layers occupied by cells must be considered in place of the concept previously used for homogeneous distribution, viz., the average cell volume fraction. This model underlines that accumulation of cells in a thin layer close to the surface improves their nutrient intake. For nonhomogeneity of type 2, the tortuosity of such a system is smaller than should be expected if spherical cells were considered, thereby changing the effective diffusion. The model proposed in this work proved to fit into several real cases reported in the literature.
ISSN:8756-7938
1520-6033
DOI:10.1021/bp020046r