Functional recovery after peripheral nerve injuries is disappointing despite surgical advances in nerve repair. This review summarizes the relatively short window of opportunity for successful nerve regeneration due to the decline in the expression of growth-associated genes and in turn, the decline in regenerative capacity of the injured neurons and the support provided by the denervated Schwann cells, and the atrophy of denervated muscles. Brief, low-frequency electrical stimulation and post-injury exercise regimes ameliorate these deficits in animal models and patients, but the misdirection of regenerating nerve fibers compromises functional recovery and remains an important area of future research.

The therapeutic effect of rehabilitation after cell therapy for brain injury remains unclear. Here, we report the neural stem/progenitor cells transplantation into a brain injury mouse model followed by treadmill exercise training. Among all experimental groups, mice that underwent transplantation and treadmill exercise demonstrated significant functional motor and electrophysiological improvement. Transplanted cells at the brain injury site were observed and differentiated into neurons and astrocytes. Transplanted cells significantly differentiated into neurons in the mice that underwent transplantation and treadmill exercise compared with those treated with only transplantation. Furthermore, the expression of brain-derived neurotrophic factor and growth-associated protein 43 mRNAs were significantly up-regulated in the mice that underwent transplantation and treadmill exercise than in those in other experimental groups during the early recovery stage. These results suggest that rehabilitation after neural stem/progenitor cell transplantation enhances neurogenesis and promotes the recovery of motor function in brain injury model mice.