Mechanical strain inhibits bacterial collagenase from cleaving collagen. Additionally, the toe region of a soft tissue’s force–elongation curve arises from sequentially engaging collagen fibrils as the tissue lengthens. Together, these phenomena suggest that mechanical strain may gradually inhibit collagenase activity through a soft tissue’s toe region. Therefore, this investigation sought to test this hypothesis.
92 rat tail tendon fascicles from 3 female sentinel animals underwent preliminary stiffness tests, and their force–elongation curves were fit to a collagen distribution model. This distribution-based model calculated the force magnitude corresponding to p% of collagen fibril engagement. Specimens were separated into one of five levels of p, and that level of force was maintained for two hours while being exposed to 0.054 U/mL of bacterial collagenase from C. histolyticum. The specimens were strained to failure following the creep test, and the relative reduction in stiffness was quantified to estimate the fraction of digested fibrils.
Every 10% additional collagen engagement corresponded to a 6.3% (97% highest density interval: 4.3 – 8.4%) retention of stiffness, which indicated collagenase inhibition.
The results of this investigation were consistent with a strain-inhibition hypothesis along with the established uncrimping mechanism in the toe region. These results support an interaction between mechanical strain and collagenolysis, which may be valuable for disease prevention or treatment.