Elastin governs the mechanical response of medial collateral ligament under shear and transverse tensile loading

Elastin governs the mechanical response of medial collateral ligament under shear and transverse tensile loading

[Display omitted] Elastin is a highly extensible structural protein network that provides near-elastic resistance to deformation in biological tissues. In ligament, elastin is localized between and along the collagen fibers and fascicles. When ligament is stretched along the primary collagen axis, e...

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Bibliographic Details
Published in:Acta biomaterialia Vol. 25; pp. 304 - 312
Main Authors: Henninger, Heath B., Valdez, William R., Scott, Sara A., Weiss, Jeffrey A.
Format: Journal Article
Language:English
Published: England Elsevier Ltd 01-10-2015
Subjects:
Animals
Biomechanical Phenomena - drug effects
Collagen - metabolism
Collagens
Degradation
Elastase
Elastin
Elastin - chemistry
Elastin - metabolism
Elongation
Glycosaminoglycans - metabolism
Ligament
Ligaments
Mechanical analysis
Medial Collateral Ligament, Knee - drug effects
Medial Collateral Ligament, Knee - physiology
Pancreatic Elastase - pharmacology
Reduction
Shear
Sus scrofa
Tensile Strength - drug effects
Transverse tensile
Weight-Bearing - physiology
Ligament
Elastase
Shear
Elastin
Transverse tensile
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Summary:[Display omitted] Elastin is a highly extensible structural protein network that provides near-elastic resistance to deformation in biological tissues. In ligament, elastin is localized between and along the collagen fibers and fascicles. When ligament is stretched along the primary collagen axis, elastin supports a relatively high percentage of load. We hypothesized that elastin may also provide significant load support under elongation transverse to the primary collagen axis and shear along the collagen axis. Quasi-static transverse tensile and shear material tests were performed to quantify the mechanical contributions of elastin during deformation of porcine medial collateral ligament. Dose response studies were conducted to determine the level of elastase enzymatic degradation required to produce a maximal change in the mechanical response. Maximal changes in peak stress occurred after 3h of treatment with 2U/ml porcine pancreatic elastase. Elastin degradation resulted in a 60–70% reduction in peak stress and a 2–3× reduction in modulus for both test protocols. These results demonstrate that elastin provides significant resistance to elongation transverse to the collagen axis and shear along the collagen axis while only constituting 4% of the tissue dry weight. The magnitudes of the elastin contribution to peak transverse and shear stress were approximately 0.03MPa, as compared to 2MPa for axial tensile tests, suggesting that elastin provides a highly anisotropic contribution to the mechanical response of ligament and is the dominant structural protein resisting transverse and shear deformation of the tissue.
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ISSN:1742-7061
1878-7568
DOI:10.1016/j.actbio.2015.07.011