Fabrication of Nerve Guide Conduit Based on 3D Graphene/ Polymer for Nerve Tissue Engineering

Journal of Advanced Materials in Engineering Pub Date : 2020-04-01 DOI:10.47176/jame.39.1.20571

N. B. Tolou, H. S. Jazi, M. Kharaziha, N. Lisi, G. Faggio, A. Tamburrano

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Abstract

In recent years, graphene has been considered in various tissue engineering applications such as nerve guide conduits because of its unique properties such as high electrical and mechanical properties, porous structure for exchange of nutritious and waste materials, biocompatible, capability of drug and growth factor delivery. In the current study, nerve guide conduits based on a 3D graphene were synthesized by induction heating chemical vapor deposition (ICVD). Graphene was synthesized on Ni foam template at 1080 Cͦ. Fabricated samples were characterized by Raman analysis and Scanning Electron Microscopy. Raman analysis showed that the synthesized graphene is in the form of a turbostratic multilayered graphene with little defects. Cyclododecane (CD) as a temporary protective layer was used to remove nickel. After removing nickel, the free-standing 3Dgraphene structure was coated with a polymer (PCL) by drop and dip coating methods to obtain the composite conduit. A comparison of the electromechanical results of the 3D-graphene/PCL conduit and PCL conduit indicated that firstly, grapheme increased the electrical conductivity of the composite conduit which will help promote nerve regeneration and axon growth. Secondly, tensile strength and flexibility of the 3D-graphene/PCL conduit was improved compared to the PCL conduit. .

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基于三维石墨烯/聚合物的神经组织工程神经导管的制备

近年来，石墨烯由于其独特的性能，如高电学和机械性能，多孔结构，营养物质和废物的交换，生物相容性，药物和生长因子的输送能力，已被考虑在各种组织工程应用，如神经导管。本研究采用感应加热化学气相沉积(ICVD)法制备了基于三维石墨烯的神经导管。石墨烯是在1080℃下在Ni泡沫模板上合成的。用拉曼分析和扫描电镜对制备的样品进行了表征。拉曼分析表明，合成的石墨烯以涡层状多层石墨烯的形式存在缺陷。采用环十二烷(CD)作为临时保护层去除镍。去除镍后，采用滴涂和浸涂的方法在独立的3d石墨烯结构上涂覆聚合物(PCL)，得到复合导管。对比3d -石墨烯/PCL导管与PCL导管的机电性能结果表明，石墨烯提高了复合导管的电导率，有助于促进神经再生和轴突生长。其次，与PCL导管相比，3d -石墨烯/PCL导管的拉伸强度和柔韧性得到了提高。

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来源期刊

Journal of Advanced Materials in Engineering

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审稿时长

50 weeks