Bioactive Materials (Sep 2022)

Acellular nerve grafts supplemented with induced pluripotent stem cell-derived exosomes promote peripheral nerve reconstruction and motor function recovery

  • Jianfeng Pan,
  • Meng Zhao,
  • Xiangjiao Yi,
  • Jianguo Tao,
  • Shaobo Li,
  • Zengxin Jiang,
  • Biao Cheng,
  • Hengfeng Yuan,
  • Feng Zhang

Journal volume & issue
Vol. 15
pp. 272 – 287

Abstract

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Peripheral nerve injury is a great challenge in clinical work due to the restricted repair gap and weak regrowth ability. Herein, we selected induced pluripotent stem cells (iPSCs) derived exosomes to supplement acellular nerve grafts (ANGs) with the aim of restoring long-distance peripheral nerve defects. Human fibroblasts were reprogrammed into iPSCs through non-integrating transduction of Oct3/4, Sox2, Klf4, and c-Myc. The obtained iPSCs had highly active alkaline phosphatase expression and expressed Oct4, SSEA4, Nanog, Sox2, which also differentiated into all three germ layers in vivo and differentiated into mature peripheral neurons and Schwann cells (SCs) in vitro. After isolation and biological characteristics of iPSCs-derived exosomes, we found that numerous PKH26-labeled exosomes were internalized inside SCs through endocytotic pathway and exhibited a proliferative effect on SCs that were involved in the process of axonal regeneration and remyelination. After that, we prepared ANGs via optimized chemical extracted process to bridge 15 mm long-distance peripheral nerve gaps in rats. Owing to the promotion of iPSCs-derived exosomes, satisfactory regenerative outcomes were achieved including gait behavior analysis, electrophysiological assessment, and morphological analysis of regenerated nerves. Especially, motor function was restored with comparable to those achieved with nerve autografts and there were no significant differences in the fiber diameter and area of reinnervated muscle fibers. Taken together, our combined use of iPSCs-derived exosomes with ANGs demonstrates good promise to restore long-distance peripheral nerve defects, and thus represents a cell-free strategy for future clinical applications.

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