A tissue's microstructure determines its failure properties at larger length scales, however, the specific relationship between microstructure and macroscopic failure in native and engineered soft tissues (such as capsular ligaments, aortic aneurysms, or vascular grafts) has proven elusive. In this study, variations in the microscale fiber alignment in collagen gel tissue analogs were modeled in order to understand their effects on macroscale damage and failure outcomes. The study employed a multiscale finite-element (FE) model for damage and failure in collagen-based materials. The model relied on microstructural representative volume elements (RVEs) that consisted of stochastically-generated networks of discrete type-I collagen fibers. Fiber alignment was varied within RVEs and between layers of RVEs in a macroscopic FE model of a notched dogbone geometry. The macroscale stretch and the microscale response of fibers for each of the differently aligned cases were compared as the dogbone was uniaxially extended to failure. Networks with greater fiber alignment parallel to the direction of extension failed at smaller strains (with a 6–22% reduction in the Green strain at failure), however, at greater grip forces (a 28–60% increase) than networks with fibers aligned perpendicular to the extension. Alternating layers of crisscrossed network alignments (aligned ±45 deg to the direction of extension) failed at smaller strains but at greater grip forces than those created using one fiber alignment type. In summary, variations in microscale structure via fiber alignment produced different macroscale failure trends. To conclude, these findings may be significant in the realm of tissue engineering and in soft tissue biomechanics.
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February 2013
Research-Article
Microscale Fiber Network Alignment Affects Macroscale Failure Behavior in Simulated Collagen Tissue Analogs
Mohammad F. Hadi,
Victor H. Barocas
Victor H. Barocas
1
e-mail: baroc001@umn.edu
Department of Biomedical Engineering,
7-105 Hasselmo Hall,
312 Church Street SE,
Minneapolis MN 55455
Department of Biomedical Engineering,
University of Minnesota
,7-105 Hasselmo Hall,
312 Church Street SE,
Minneapolis MN 55455
1Corresponding author.
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Mohammad F. Hadi
e-mail: hadix004@umn.edu
Victor H. Barocas
e-mail: baroc001@umn.edu
Department of Biomedical Engineering,
7-105 Hasselmo Hall,
312 Church Street SE,
Minneapolis MN 55455
Department of Biomedical Engineering,
University of Minnesota
,7-105 Hasselmo Hall,
312 Church Street SE,
Minneapolis MN 55455
1Corresponding author.
Contributed by the Bioengineering Division of ASME for publication in the JOURNAL OF BIOMECHANICAL ENGINEERING. Manuscript received October 22, 2012; final manuscript received January 7, 2013; accepted manuscript posted January 18, 2013; published online February 7, 2013. Editor: Beth Winkelstein.
J Biomech Eng. Feb 2013, 135(2): 021026 (8 pages)
Published Online: February 7, 2013
Article history
Received:
October 22, 2012
Revision Received:
January 7, 2013
Accepted:
January 18, 2013
Citation
Hadi, M. F., and Barocas, V. H. (February 7, 2013). "Microscale Fiber Network Alignment Affects Macroscale Failure Behavior in Simulated Collagen Tissue Analogs." ASME. J Biomech Eng. February 2013; 135(2): 021026. https://doi.org/10.1115/1.4023411
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