用于周围神经再生的纤维基导电复合支架的制备与性能

[Preparation and properties of fiber-based conductive composite scaffolds for peripheral nerve regeneration].

作者信息

Dai Wufei, Shi Jiaqi, Liu Sha, Xu Ziqi, Shi Yijin, Zhao Yahong, Yang Yumin

机构信息

Key Laboratory of Neuroregeneration of Jiangsu and Ministry of Education, Co-Innovation Center of Neuroregeneration, Nantong University, Nantong Jiangsu, 226001, P.R.China;Nantong University School of Medicine, Nantong Jiangsu, 226001, P.R.China.

Key Laboratory of Neuroregeneration of Jiangsu and Ministry of Education, Co-Innovation Center of Neuroregeneration, Nantong University, Nantong Jiangsu, 226001, P.R.China.

出版信息

Zhongguo Xiu Fu Chong Jian Wai Ke Za Zhi. 2019 Mar 15;33(3):356-362. doi: 10.7507/1002-1892.201808004.

DOI:10.7507/1002-1892.201808004

PMID:30874396

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8337933/

Abstract

OBJECTIVE

To explore the preparation method, physical and chemical properties, and biocompatibility of a conductive composite scaffold based on polypyrrole/silk fibroin (PPy/SF) fiber with "shell-core" structure, and to provide a preliminary research basis for the application in the field of tissue engineered neuroscience.

METHODS

The conductive fibers with "shell-core" structure were prepared by three-dimensional printing combined with polymerization. PPy/SF fiber-based conductive composite scaffolds were formed by electrospinning. In addition, core-free PPy conductive fibers and SF electrospinning fibers were prepared. The stability, biomechanics, electrical conductivity, degradation performance, and biological activity of each material were tested to analyze the comprehensive properties of fiber-based conductive composite scaffolds.

RESULTS

Compared with pure core-free PPy conductive fibers and SF electrospinning fibers, the PPy/SF fiber-based conductive composite scaffolds with "shell-core" structure could better maintain the stability performance, enhance the mechanical stretchability of the composite scaffolds, maintain long-term electrical activity, and improve the anti-degradation performance. At the same time, PPy/SF conductive composite scaffolds were suitable for NIH3T3 cells attachment, conducive to cell proliferation, and had good biological activity.

CONCLUSION

PPy/SF fiber-based conductive composite scaffolds meet the needs of conductivity, stability, and biological activity of artificial nerve grafts, and provide a new idea for the development of a new generation of high-performance and multi-functional composite materials.

摘要

目的

探究具有“核壳”结构的聚吡咯/丝素蛋白（PPy/SF）纤维基导电复合支架的制备方法、理化性质及生物相容性，为其在组织工程神经科学领域的应用提供初步研究依据。

方法

通过三维打印结合聚合反应制备具有“核壳”结构的导电纤维，采用静电纺丝法制备基于PPy/SF纤维的导电复合支架。此外，制备无核PPy导电纤维和SF静电纺丝纤维。测试各材料的稳定性、生物力学性能、导电性、降解性能及生物活性，以分析基于纤维的导电复合支架的综合性能。

结果

与纯无核PPy导电纤维和SF静电纺丝纤维相比，具有“核壳”结构的PPy/SF纤维基导电复合支架能更好地维持稳定性，增强复合支架的机械拉伸性，保持长期电活性，并提高抗降解性能。同时，PPy/SF导电复合支架适合NIH3T3细胞附着，有利于细胞增殖，具有良好的生物活性。

结论

PPy/SF纤维基导电复合支架满足人工神经移植物的导电性、稳定性及生物活性需求，为新一代高性能多功能复合材料的研发提供了新思路。

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