Homogenized constrained mixture models for anisotropic volumetric growth and remodeling

Constrained mixture models for soft tissue growth and remodeling have attracted increasing attention over the last decade. They can capture the effects of the simultaneous presence of multiple constituents that are continuously deposited and degraded at in general different rates, which is important...

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Bibliographic Details
Published in:Biomechanics and modeling in mechanobiology 2017-06, Vol.16 (3), p.889-906
Main Authors: Braeu, F. A., Seitz, A., Aydin, R. C., Cyron, C. J.
Format: Article
Language:English
Subjects:
Anisotropy
Biological and Medical Physics
Biomechanical Phenomena
Biomedical Engineering and Bioengineering
Biophysics
Computer applications
Computer Simulation
Engineering
Error propagation
Growth models
Humans
Mathematical models
Measurement errors
Models, Biological
Original Paper
Soft tissues
Space life sciences
Theoretical and Applied Mechanics
Three dimensional models
Vascular Remodeling - physiology
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Summary:Constrained mixture models for soft tissue growth and remodeling have attracted increasing attention over the last decade. They can capture the effects of the simultaneous presence of multiple constituents that are continuously deposited and degraded at in general different rates, which is important to understand essential features of living soft tissues that cannot be captured by simple kinematic growth models. Recently the novel concept of homogenized constrained mixture models was introduced. It was shown that these models produce results which are very similar (and in certain limit cases even identical) to the ones of constrained mixture models based on multi-network theory. At the same time, the computational cost and complexity of homogenized constrained mixture models are much lower. This paper discusses the theory and implementation of homogenized constrained mixture models for anisotropic volumetric growth and remodeling in three dimensions. Previous constrained mixture models of volumetric growth in three dimensions were limited to the special case of isotropic growth. By numerical examples, comparison with experimental data and a theoretical discussion, we demonstrate that there is some evidence raising doubts whether isotropic growth models are appropriate to represent growth and remodeling of soft tissue in the vasculature. Anisotropic constrained mixture models, as introduced in this paper for the first time, may be required to avoid unphysiological results in simulations of vascular growth and remodeling.
ISSN:1617-7959
1617-7940
DOI:10.1007/s10237-016-0859-1