| Literature DB >> 30044554 |
Xun Sun1,2, Yu Wang1,3, Zhiyuan Guo1, Bo Xiao1, Zhen Sun1, Heyong Yin4, Haoye Meng1, Xiang Sui1, Qing Zhao1,3, Quanyi Guo1, Aiyuan Wang1, Wenjing Xu1, Shuyun Liu1, Yaojun Li5, Shibi Lu1, Jiang Peng1,3.
Abstract
Autologous nerve grafting (ANG), the gold standard treatment for peripheral nerve defects, still has many restrictions. In this study, the acellular cauda equina allograft (ACEA), which consists of biodegradable chitin conduit and acellular cauda equina, is developed. The cauda equina is able to complete decellularization more quickly and efficiently than sciatic nerves under the same conditions, and it is able to reserve more basal lamina tube. In vitro, ACEA shows superior guidance capacity for the regeneration of axons and migration of Schwann cells compared to acellular sciatic nerve allograft (ASNA) in dorsal root ganglion culture. In vivo, ACEA is used to bridge 15 mm long-distance defects in rat sciatic nerves. On day 21 after transplantation, the regenerative distance of neurofilaments in the grafting segment is not significantly different between the ACEA and ANG groups. At week 12, ACEA group shows better sciatic nerve repair than chitin conduit only and ASNA groups, and the effect is similar to that in the ANG group as determined by gait analysis, neural electrophysiological, and histological analyses. The above results suggest that the ACEA has the potential to become a new biological material as a replacement for autografting in the treatment of long-distance nerve defects.Entities:
Keywords: autologous nerve grafts; cauda equina; extracellular matrix; peripheral nerve defects; peripheral nerve regeneration
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Year: 2018 PMID: 30044554 DOI: 10.1002/adhm.201800276
Source DB: PubMed Journal: Adv Healthc Mater ISSN: 2192-2640 Impact factor: 9.933