3D-engineering of Cellularized Conduits for Peripheral Nerve Regeneration

电气导管 神经导管 再生(生物学) 组织工程 周围神经 坐骨神经 脚手架 生物医学工程 神经营养因子 体内 干细胞 明胶 细胞生物学 材料科学 解剖 生物 计算机科学 医学 内科学 受体 生物技术 电信 生物化学
作者
Yu Hu,Yao Wu,Zhiyuan Gou,Jie Tao,Jiumeng Zhang,Qianqi Liu,Tianyi Kang,Shu Jiang,Siqing Huang,Jiankang He,Shaochen Chen,Yanan Du,Maling Gou
出处
期刊:Scientific Reports [Nature Portfolio]
卷期号:6 (1) 被引量:138
标识
DOI:10.1038/srep32184
摘要

Tissue engineered conduits have great promise for bridging peripheral nerve defects by providing physical guiding and biological cues. A flexible method for integrating support cells into a conduit with desired architectures is wanted. Here, a 3D-printing technology is adopted to prepare a bio-conduit with designer structures for peripheral nerve regeneration. This bio-conduit is consisted of a cryopolymerized gelatin methacryloyl (cryoGelMA) gel cellularized with adipose-derived stem cells (ASCs). By modeling using 3D-printed "lock and key" moulds, the cryoGelMA gel is structured into conduits with different geometries, such as the designed multichannel or bifurcating and the personalized structures. The cryoGelMA conduit is degradable and could be completely degraded in 2-4 months in vivo. The cryoGelMA scaffold supports the attachment, proliferation and survival of the seeded ASCs, and up-regulates the expression of their neurotrophic factors mRNA in vitro. After implanted in a rat model, the bio-conduit is capable of supporting the re-innervation across a 10 mm sciatic nerve gap, with results close to that of the autografts in terms of functional and histological assessments. The study describes an indirect 3D-printing technology for fabricating cellularized designer conduits for peripheral nerve regeneration, and could lead to the development of future nerve bio-conduits for clinical use.

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