Summary Statement. ASTM therapy is commonly used to treat Achilles tendinopaty. However, there was no report to evaluate the biomechanical effects, especially the dynamic viscoelasticity. We have shown that ASTM treatment was biomechanically useful for chronic Achilles tendinopathy in an animal model. Introduction. Achilles tendinopathy is a common chronic overuse injury. Because Achilles tendon overuse injury takes place in sports and there has been a general increase in the popularity of sports activities, the number and incidence of Achilles tendon overuse injury has increased. Augmented Soft Tissue Mobilization (ASTM) therapy is a modification of traditional soft tissue mobilization and has been used to treat a variety of musculoskeletal disorders. ASTM therapy is thought to promote collagen fiber realignment and hasten tendon repair. It might also change the biomechanical behavior of the injured tendon, especially the dynamic viscoelasticity. The purpose of this study is to evaluate the effect of ASTM therapy in a rabbit model of Achilles tendinopathy by quantifying dynamic biomechanical properties and histologic features. Patients & Methods. The hind limbs of 12 rabbits were used, and 24 Achilles tendons were injected with collagenase to produce tendon injury. One hind limb of each animal was then randomly allocated to receive ASTM therapy, while the other received no treatment and served as a control. ASTM was performed on the Achilles tendon for 3 minutes on postoperative days 21, 24, 28, 31, 35, and 38. The Achilles tendons were harvested 10 days after the last treatment. Specimens were examined with dynamic viscoelasticity and light microscopy. Results. The mean±SD cross-sectional area for the treated and untreated tendons was 12.30±5.47 mm. 2. and 9.57±8.36 mm. 2. , respectively. The difference between the treated and untreated tendons was statistically significant (P<.01). At all dynamic loading frequencies, the storage modulus in the untreated tendons tended to be higher than that in the treated tendons. At 0.1 Hz and 10 Hz, in the untreated tendons was significantly higher than that in the treated tendons (P=.05). The loss modulus was significantly lower in the treated tendons than in the untreated tendons (P<.05). There was no significant difference in tan δ between the treated and untreated tendons. HE stain showed that the untreated tendon fiber was wavy and kinking and displayed a disordered collagen arrangement. In contrast, the tendon fiber was well aligned in the treated tendons. In the immunohistochemically stained specimens, the type III collagen showed higher color intensity in the untreated tendons than in the treated tendons. Discussion/Conclusion. We have shown that ASTM was a biomechanically useful treatment for chronic Achilles tendinopathy. Biomechanical and histologic data showed the treated Achilles tendons had better biomechanical function and histologic outcomes than the untreated tendons

The fibrocartilaginous enthesis displays a complex interface between two mechanically dissimilar tissues, namely tendon and bone. This graded transition zone consists of parallel collagen type I fibres arising from the tendon and inserting into bone across zones of fibrocartilage with aligned collagen type I and collagen type II fibres and mineralised fibrocartilage. Due the high stress concentrations arising at the interface, entheses are prone to traumatic and chronic overuse injuries such as rotator cuff and anterior cruciate ligament (ACL) tears. Treatment strategies range from surgical reattachment for complete tears and conservative treatments (physiotherapy, anti-inflammatory drugs) in chronic inflammatory conditions. Generally, the native tissue architecture is not re-established and mechanically inferior scar tissue is formed. Current interfacial tissue engineering approaches pose scaffold-associated drawbacks and limitations, such as foreign body response. Using a thermo-responsive electrospun scaffold that provides architectural signals similar to native tissues and can be removed prior to implantation, we aim to develop an ECM-rich, cell-based implant for tendon-enthesis regeneration. Alcian blue staining revealed highest sGAG deposition in cell (human adipose derived stem cells) sheets grown on random electrospun fibres and lowest sGAG deposition in collagen type I sponges. Cells did not show an equal distribution throughout the collagen type II scaffolds but tended to form localised aggregates. Thermo-responsive electrospun fibres with random and aligned fibre orientation provided an adequate three-dimensional environment for chondrogenic differentiation of multilayer hADSC-sheets shown by high ECM-production, especially high sGAG deposition. Chondrogenic cell sheets showed increased expression of SOX9, COL2A1, COL1A1, COMP and ACAN after 7 days of chondrogenic induction when compared to pellet culture. Anisotropic fibres enabled the generation of aligned chondrogenic cell sheets, shown by cell and collagen fibre alignment. Thermoresponsive electrospun fibres showed high chondro-inductivity due to their three-dimensionality and therefore pose a promising tool for the generation of scaffold-free multilayer constructs for tendon-enthesis repair within short culture periods. Aligned chondrogenic cell sheets mimic the zonal orientation of the native enthesis as the fibrocartilaginous zone exhibits high collagen alignment

Most cases of tendinopathy are believed to be overuse injuries rather than the result of a chronic event. The investigation of the fatigue properties of tendon is therefore of critical importance. This work considered the cyclic stress-relaxation and creep behaviour of two contrasting bovine tendon types – the largely postional digital extensor and the more energy storing deep digital flexor tendon. Fascicles were cyclically loaded (1Hz), to 1800 cycles of stress relaxation or to failure in creep, stopping some tests at 300, 900 or 1200 cycles to perform quasi-static failure tests or confocal imaging using a highly concentrated Acridine Orange solution. Creep tests were cycled to 60% of the ultimate tensile strength (UTS), while for stress relaxation, cyclic deformation to the strain associated with 60% UTS was used. Flexor tendon fascicles were found to exhibit reduced stress relaxation at all time points compared to the extensor fascicles and also showed an increase in the mean cycles to failure during creep testing. Evidence of fatigue damage was clear in the confocal images with breakdown of the collagen fibre alignment evident from 300 cycles; however it appears that some damage could occur without effect on the UTS of the fascicle. Despite what appears to be superior fatigue resistance in the flexor tendon fascicles, the matrix damage, certainly at early time points, appeared visually to be as severe as that observed with the extensor tendon fascicles