Derivation of the Macroscopic Intracellular Conductivity of Deformed Myocardium on the Basis of Microstructure Analysis

A model of changes in the intracellular conductivity of the myocardium due to its deformation was developed. Macroconductivities were derived using the microstructure-based model proposed by Hand et al. (2009), where the heart tissue was considered as a periodic grid, the cells were rectangular pris...

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Bibliographic Details
Published in:Biophysics (Oxford) 2018-05, Vol.63 (3), p.455-462
Main Authors: Vasserman, I. N., Matveenko, V. P., Shardakov, I. N., Shestakov, A. P.
Format: Article
Language:English
Subjects:
Anisotropy
Biological and Medical Physics
Biophysics
Cell size
Complex Systems Biophysics
Compression
Conductivity
Cytoplasm
Electrical properties
Gap junctions
Intracellular
Myocardium
Periodicity
Physics
Physics and Astronomy
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Summary:A model of changes in the intracellular conductivity of the myocardium due to its deformation was developed. Macroconductivities were derived using the microstructure-based model proposed by Hand et al. (2009), where the heart tissue was considered as a periodic grid, the cells were rectangular prisms filled with conducting fluid, and the conductivity of gap-junctions was represented through boundary conditions on the sides of these prisms. In deriving the dependence of conductivities on deformation, some generalizations associated with the layered fiber structure for the tissue and nature of deformation were used. Furthermore, it was assumed that the cytoplasm is an isotropic electrolyte with deformation-independent conductivity, conductivities of gap junctions are constant, and cell deformation is the same as the tissue macrodeformation. Using the homogenization method, conductivity values were expressed analytically through the cell size, parameters of the grid periodicity, and electrical properties of the myoplasm and gap junctions. On the basis of these data, the dependence of the conductivity on tissue deformation was shown. First, we considered a simple model where the deformation is a tension–compression along the axes of the material. A model for a general case of deformation was then developed. Finally, this model was generalized in order to take the microstructural anisotropy of the myoplasm into account. Our model was compared with the model proposed by F.V. Sachse. It was shown that both models can be well aligned for elongations in the range from 0.8 to 1.2.
ISSN:0006-3509
1555-6654
DOI:10.1134/S0006350918030247