Tendons are constantly subjected to mechanical loading in vivo. Recently, stem cells were identified in human, mouse, and rabbit tendons, but the mechanobiological responses of tendon stem cells (TSCs) are still undefined. Using an in vitro system capable of mimicking in vivo loading conditions, it was determined that mechanical stretching increased TSC proliferation in a stretching magnitudedependent manner. Moreover, low mechanical stretching at 4% (''clamp-to-clamp'' engineering strain) promoted differentiation of TSCs into tenocytes, whereas large stretching at 8% induced differentiation of some TSCs into adipogenic, chondrogenic, and osteogenic lineages, as indicated by upregulated expression of marker genes for adipocytes, chondrocytes, and osteocytes. Thus, low mechanical stretching may be beneficial to tendons by enabling differentiation of TSCs into tenocytes to maintain tendon homeostasis. However, large mechanical loading may be detrimental, as it directs differentiation of TSCs into non-tenocytes in tendons, thus resulting in lipid accumulation, mucoid formation, and tissue calcification, which are typical features of tendinopathy at later stages. Tendons transmit muscular forces to bone and are constantly subjected to mechanical loading in vivo. As such, tendons are susceptible to pathological changes, known as tendinopathy. Tendinopathy is especially prevalent in both occupational and athletic settings that involve repetitive motions, indicating that excessive mechanical loading placed on tendons is a major contributor to the development of tendinopathy. Nevertheless, the precise pathogenic mechanisms of tendinopathy remain unclear. However, the typical histopathological features of tendinopathy have been identified, including accumulation of lipid cells, mucoid degeneration, tissue calcification, or some combination thereof.1 These findings suggest that tendons contain cells with the potential to exhibit multi-phenotypes that differ from tenocytes, the resident cells in tendons, which express the fibroblast phenotype. Indeed, tendon stem/progenitor cells (TSCs) were recently identified from humans, mice, and rabbits, and TSCs were shown to have multi-differentiation potential. These stem cells can differentiate into non-tenocyte lineages such as adipocytes, chondrocytes, and osteocytes. 2,3 Stem cells are able to perpetuate themselves through self-replication and differentiation, a process which generates mature cells of a particular tissue. Currently, most studies in stem cell research focus on isolation, identification, and characterization of stem cells. Few studies have investigated the effects of mechanical loading on stem cells, which is nevertheless essential for gaining a better understanding of the physiology and pathology of load-bearing tissues such as tendons. 4 Existing studies, however, have indicated that mechanical loading regulates stem cell proliferation and differentiation. For example, mechanical stretching stimulates proliferation of human bone marrow mesenchymal ste...
