The proliferation and differentiation of skeletal muscle stem cells are enhanced in a bioreactor.

Skeletal muscle (SKM) is the largest organ in mammalian body and it can repair damages by using the residential myogenic stem cells (MuSC), but this repairing capacity reduces with age and in some genetic muscular dystrophy. Under these circumstances, artificial amplification of autologous MuSC in vitro might be necessary to repair the damaged SKM. The amplification of MuSC is highly dependent on myogenic signals, such as sonic hedgehog (Shh), Wnt3a, and fibroblast growth factors, so formulating an optimum myogenic kit composed of specific myogenic signals might increase the proliferation and differentiation of MuSC efficiently. In this study, various myogenic signals have been tested on C2C12 myoblasts and primary MuSC, and a myogenic kit consists of insulin, lithium chloride, T₃, and retinoic acid has been formulated, and we found it significantly increased the fusion index and MHC expression level of both C2C12 and MuSC myotubes. A novel bioreactor providing cyclic stretching (CS) and electrical stimulation (ES) has been fabricated to enhance the myogenic differentiation of both C2C12 and MuSC. We further found that coating the bioreactor substratum with collagen gave the best effect on proliferation and differentiation of MuSC. Furthermore, combining the collagen coating and physical stimuli (CS + ES) in the bioreactor can generate more proliferative primary MuSC cells. Our results have demonstrated that the combination of myogenic kit and bioreactor can provide environment for efficient MuSC proliferation and differentiation. These MuSC and mature myotubes amplified in the bioreactor might be useful for clinical grafting into damaged SKM in the future.