[HTML][HTML] The dispersion of viscoelastic properties of fascicle bundles within the tendon results from the presence of interfascicular matrix and flow of body fluids

A Mlyniec, S Dabrowska, M Heljak, WP Weglarz… - Materials Science and …, 2021 - Elsevier
Materials Science and Engineering: C, 2021Elsevier
In this work, we investigate differences in the mechanical and structural properties of tendon
fascicle bundles dissected from different areas of bovine tendons. The properties of tendon
fascicle bundles were investigated by means of uniaxial tests with relaxation periods and
hysteresis, dynamic mechanical analysis (DMA), as well as magnetic resonance imaging
(MRI). Uniaxial tests with relaxation periods revealed greater elastic modulus, hysteresis, as
well as stress drop during the relaxation of samples dissected from the posterior side of the …
Abstract
In this work, we investigate differences in the mechanical and structural properties of tendon fascicle bundles dissected from different areas of bovine tendons. The properties of tendon fascicle bundles were investigated by means of uniaxial tests with relaxation periods and hysteresis, dynamic mechanical analysis (DMA), as well as magnetic resonance imaging (MRI). Uniaxial tests with relaxation periods revealed greater elastic modulus, hysteresis, as well as stress drop during the relaxation of samples dissected from the posterior side of the tendon. However, the normalized stress relaxation curves did not show a statistically significant difference in the stress drop between specimens cut from different zones or between different strain levels.
Using dynamic mechanical analysis, we found that fascicle bundles dissected from the anterior side of the tendon had lower storage and loss moduli, which could result from altered fluid flow within the interfascicular matrix (IFM). The lower water content, diffusivity, and higher fractional anisotropy of the posterior part of the tendon, as observed using MRI, indicates a different structure of the IFM, which controls the flow of fluids within the tendon.
Our results show that the viscoelastic response to dynamic loading is correlated with fluid flow within the IFM, which was confirmed during analysis of the MRI results. In contrast to this, the long-term relaxation of tendon fascicle bundles is controlled by viscoplasticity of the IFM and depends on the spatial distribution of the matrix within the tendon. Comparison of results from tensile tests, DMA, and MRI gives new insight into tendon mechanics and the role of the IFM. These findings may be useful in improving the diagnosis of tendon injury and effectiveness of medical treatments for tendinopathies.
Elsevier
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