Comprehensive Mathematical Model of Microcirculatory Dynamics(Ⅰ)——Basic Theory

Guo Zhongsan; Xiao Fan; Guo Siwen; Wu Yueqing; Gu Leye

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Article Navigation > Applied Mathematics and Mechanics > 1999 > 20(9): 947-954

Guo Zhongsan, Xiao Fan, Guo Siwen, Wu Yueqing, Gu Leye. Comprehensive Mathematical Model of Microcirculatory Dynamics(Ⅰ)——Basic Theory[J]. Applied Mathematics and Mechanics, 1999, 20(9): 947-954.

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Comprehensive Mathematical Model of Microcirculatory Dynamics(Ⅰ)——Basic Theory

Chengdu Institute of Computer Application, Academia Sinica, Chengdu 610041, P R China

Received Date: 1998-07-19
Rev Recd Date: 1999-04-20
Publish Date: 1999-09-15

Abstract

Abstract

Under the basis of physiological data,a nonlinear and unsteady comprehensive mathematical model of microcirculatory dynamics with distributed parameters is developed.Hemodynamics,interstitium dynamics,lymph dynamics,dynamics of protein transport,oxygen dynamics,dynamics of heat transfer,and myogenic and metabolic regulation procedures are included.The interactions between these factors were comprehensively exhibited.The influences of arteriolar vasomotion and nonlinear viscoelasticity of blood in arteriole are considered.A simplified vessel network consisting of arteriole,open and reserved capillaries,venule,initial lymphatics and arteriole-venule anastomose is adopted as the geometrical model.This kind of comprehensive mathematical model is helpful in analyzing clinical data and developing a "numerical experiment method" in microcirculation research.
- microcirculatory system,
- comprehensive mathematical model,
- interaction,
- numerical experiment

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References(13)

References

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