Multiscale model of fatigue of collagen gels

Fatigue as a mode of failure becomes increasingly relevant with age in tissues that experience repeated fluctuations in loading. While there has been a growing focus on the mechanics of networks of collagen fibers, which are recognized as the predominant mechanical components of soft tissues, the ne...

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Bibliographic Details
Published in:Biomechanics and modeling in mechanobiology 2019-02, Vol.18 (1), p.175-187
Main Authors: Dhume, Rohit Y., Shih, Elizabeth D., Barocas, Victor H.
Format: Article
Language:English
Subjects:
Animals
Biological and Medical Physics
Biomedical Engineering and Bioengineering
Biophysics
Collagen
Collagen - chemistry
Computer simulation
Crack propagation
Cyclic loads
Engineering
Fatigue
Fatigue failure
Fibers
Gels
Gels - chemistry
Mechanical components
Mechanical loading
Metal matrix composites
Models, Biological
Networks
Original Paper
Probability
Rats
Soft tissues
Stress concentration
Stress, Mechanical
Theoretical and Applied Mechanics
Trusses
Variation
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Summary:Fatigue as a mode of failure becomes increasingly relevant with age in tissues that experience repeated fluctuations in loading. While there has been a growing focus on the mechanics of networks of collagen fibers, which are recognized as the predominant mechanical components of soft tissues, the network’s fatigue behavior has received less attention. Specifically, it must be asked (1) how the fatigue of networks differs from that of its component fibers, and (2) whether this difference in fatigue behaviors is affected by changes in the network’s architecture. In the present study, we simulated cyclic uniaxial loading of Voronoi networks to model fatigue experiments performed on reconstituted collagen gels. Collagen gels were cast into dog-bone shape molds and were tested on a uniaxial machine under a tension-tension cyclic loading protocol. Simulations were performed on networks modeled as trusses of, on average, 600 nonlinear elastic fibers connected at freely rotating pin-joints. We also simulated fatigue failure of Delaunay, and Erdős–Rényi networks, in addition to Voronoi networks, to compare fatigue behavior among different architectures. The uneven distribution of stresses within the fibers of the unstructured networks resulted in all three network geometries being more endurant than a single fiber or a regular lattice under cyclic loading. Among the different network geometries, for low to moderate external loads, the Delaunay networks showed the best fatigue behavior, while at higher loads, the Voronoi networks performed better.
ISSN:1617-7959
1617-7940
1617-7940
DOI:10.1007/s10237-018-1075-y