| Abstract: | Tendinopathy, degeneration of the tendon that leads to pain and dysfunction, is common in both sports and occupational settings, but multi‐scale mechanisms for tendinopathy are still unknown. We recently showed that micro‐scale sliding (shear) is responsible for both load transfer and damage mechanisms in the rat tail tendon; however, the rat tail tendon is a specialized non‐load‐bearing tendon, and thus the load transfer and damage mechanisms are still unknown for load‐bearing tendons. The objective of this study was to investigate the load transfer and damage mechanisms of load‐bearing tendons using the rat plantaris tendon. We demonstrated that micro‐scale sliding is a key component for both mechanisms in the plantaris tendon, similar to the tail tendon. Namely, the micro‐scale sliding was correlated with applied strain, demonstrating that load was transferred via micro‐scale sliding in the plantaris and tail tendons. In addition, while the micro‐scale strain fully recovered, the micro‐scale sliding was non‐recoverable and strain‐dependent, and correlated with tissue‐scale mechanical parameters. When the applied strain was normalized, the % magnitudes of non‐recoverable sliding was similar between the plantaris and tail tendons. Statement of clinical significance: Understanding the mechanisms responsible for the pathogenesis and progression of tendinopathy can improve prevention and rehabilitation strategies and guide therapies and the design of engineered constructs. © 2019 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 37:1827–1837, 2019 |
