Neural stem cell transplantation in a double-layer collagen membrane with unequal pore sizes for spinal cord injury repair

doi:10.4103/1673-5374.133160

Abstract

Abstract:

A novel double-layer collagen membrane with unequal pore sizes in each layer was designed and tested in this study. The inner, loose layer has about 100-μm-diameter pores, while the outer, compact layer has about 10-μm-diameter pores. In a rat model of incomplete spinal cord injury, a large number of neural stem cells were seeded into the loose layer, which was then adhered to the injured side, and the compact layer was placed against the lateral side. The results showed that the transplantation of neural stem cells in a double-layer collagen membrane with unequal pore sizes promoted the differentiation of neural stem cells, attenuated the pathological lesion, and significantly improved the motor function of the rats with incomplete spinal cord injuries. These experimental findings suggest that the transplantation of neural stem cells in a double-layer collagen membrane with unequal pore sizes is an effective therapeutic strategy to repair an injured spinal cord.

Key words: nerve regeneration, spinal cord injury, collagen, scaffolds, neural stem cells, cell transplantation, nerve repair, neural regeneration

Ning Yuan, Wei Tian, Lei Sun, Runying Yuan, Jianfeng Tao, Dafu Chen. Neural stem cell transplantation in a double-layer collagen membrane with unequal pore sizes for spinal cord injury repair[J]. Neural Regeneration Research, 2014, 9(10): 1014-1019.

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Neural stem cell transplantation in a double-layer collagen membrane with unequal pore sizes for spinal cord injury repair

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