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通过微孔发泡和聚合物浸出制备原纤化且相互连通的多孔聚(ε-己内酯)血管组织工程支架

Fabrication of fibrillated and interconnected porous poly(ε-caprolactone) vascular tissue engineering scaffolds by microcellular foaming and polymer leaching.

作者信息

Hou Jianhua, Jiang Jing, Guo Haiyang, Guo Xin, Wang Xiaofeng, Shen Yaqiang, Li Qian

机构信息

School of Mechanics & Engineering Science, Zhengzhou University, National Center for International Joint Research of Micro-Nano Molding Technology Zhengzhou 450001 PR China

School of Mechanical Engineering, Zhengzhou University Zhengzhou 450001 PR China

出版信息

RSC Adv. 2020 Mar 10;10(17):10055-10066. doi: 10.1039/d0ra00956c. eCollection 2020 Mar 6.

DOI:10.1039/d0ra00956c
PMID:35498611
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9050225/
Abstract

This paper provides a method combining eco-friendly supercritical CO microcellular foaming and polymer leaching to fabricate small-diameter vascular tissue engineering scaffolds. The relationship between pore morphology and mechanical properties, and the cytocompatibility, are investigated with respect to the effects of poly(ε-caprolactone)/poly(ethylene oxide) (PCL/PEO) phase morphologies and PEO leaching. When PEO content increases, the pore size decreases and the pore density increases. After the leaching process, highly interconnected and fibrillated porous structures are detected in the foamed PCL70 blend with droplet-matrix morphologies. Moreover, the leaching process had a greater contribution to improve the open-cell content in the PCL50 blend, which has a co-continuous morphology and easily obtained open-cell content of more than 80%. Small-diameter tubular PCL70 and PCL50 porous scaffolds with an average pore size of 48 ± 1.4 μm and 30 ± 1.0 μm respectively, are fabricated successfully. Prominent orientated pores are found in the PCL70 scaffold, and a mixed microstructure combining interconnected channels and open cells occurs in PCL50 scaffold. The PCL70 scaffold has a greater longitudinal tensile strength, longer toe region, and larger cyclical recoverability. HUVECs tend to align along the direction of the pore orientation in the PCL70 scaffold, whereas HUVECs have a higher density and spreading area in the PCL50 scaffold. The results gathered in this paper may provide a theoretical basis and data support for fabricating small-diameter porous tissue engineering vascular scaffolds.

摘要

本文提供了一种结合环保型超临界CO2微孔发泡和聚合物浸出的方法来制备小直径血管组织工程支架。针对聚(ε-己内酯)/聚(环氧乙烷)(PCL/PEO)相形态和PEO浸出的影响,研究了孔形态与力学性能之间的关系以及细胞相容性。当PEO含量增加时,孔径减小,孔密度增加。浸出过程后,在具有液滴-基体形态的发泡PCL70共混物中检测到高度互连且呈纤维状的多孔结构。此外,浸出过程对提高PCL50共混物中的开孔含量有更大贡献,PCL50共混物具有双连续形态,且易于获得超过80%的开孔含量。成功制备了平均孔径分别为48±1.4μm和30±1.0μm的小直径管状PCL70和PCL50多孔支架。在PCL70支架中发现了明显的定向孔,而在PCL50支架中出现了由互连通道和开孔组成的混合微观结构。PCL70支架具有更大的纵向拉伸强度、更长的趾部区域和更大的循环恢复能力。人脐静脉内皮细胞(HUVECs)倾向于在PCL70支架中沿孔的方向排列,而在PCL50支架中HUVECs具有更高的密度和铺展面积。本文收集的结果可为制备小直径多孔组织工程血管支架提供理论依据和数据支持。

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