Local hypoxia in cellular grafts remains a challenge during the repair of peripheral nerve injury. Oxygen carriers (perfluorotributylamine, PFTBA) have been shown to provide oxygen to Schwann cells (SCs) for a short period. However, the limited oxygen supply from oxygen-carrying materials hinders the ability of such systems to counteract hypoxia over an extended period and limits their therapeutic potential. In this study, PFTBA/VEGF core-shell fibers were fabricated through coaxial electrospinning to construct an oxygen supply system that can sequentially provide oxygen, first via the oxygen carrier and subsequently by promoting angiogenesis via VEGF. Then, the oxygen release and proangiogenic effects of the PFTBA/VEGF core-shell fibers were examined in vitro. Furthermore, sequential oxygen supply conduits prepared using the fibers and filled with SCs were used to bridge 15-mm-long sciatic nerve defects in rats. The PFTBA-VEGF system was confirmed to protect SCs from hypoxia and promote angiogenesis in vitro. Subsequent in vivo studies showed that after the oxygen carried by PFTBA was exhausted, the VEGF could induce neovascularization, and the nascent blood vessels acted as sequential oxygen suppliers for SCs during nerve regeneration. In addition, rats transplanted with the sequential oxygen supply system showed significant morphological and functional improvements in axonal regeneration, the sciatic function index, and the muscle wet weight ratio. The final functional outcomes were similar after treatment with the sequential oxygen supply conduits and autografts. Western blots revealed that the VEGF in the system could upregulate p-AMPK, contributing to axon regeneration after sciatic nerve injury. The sequential oxygen supply system offers essential insights into the oxygen regulation of biomaterials and highlights the potential of oxygen supply strategies as therapeutic approaches for repairing defects in peripheral nerves and other aerobic tissues.
Keywords: Angiogenesis; Coaxial electrospinning; Hypoxia; Nerve regeneration; Perfluorotributylamine; Peripheral nerve injury.
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