组织工程中用于小直径血管的仿生双层蚕丝材料支架。

Ana M Gaviria Castrillon, Sandra Wray, Aníbal Rodríguez, Sahara Díaz Fajardo, Victoria A Machain, Julieta Parisi, Gabriela N Bosio, David L Kaplan, Adriana Restrepo-Osorio, Valeria E Bosio
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引用次数: 0

摘要

提高小直径血管支架的生物相容性和机械稳定性仍然是一项重大挑战。为了应对这一挑战,我们利用丝绸纺织业废弃材料中的蚕丝纤维素(SF)电纺出小直径管状结构,生成了模拟原生血管的双层支架,这种支架来源于可持续的天然材料资源。内层是通过将蚕丝纤维素直接溶解在甲酸中得到的,而中间层(蚕丝纤维素-M)则是通过水浓缩蛋白质得到的。对各层以及双分子层的结构和生物特性进行了评估。内层显示出纳米级的纤维直径和 57.9% 的结晶度,降解率与 SF-M 层相当。中间层的纤维直径为微米级,最终延伸率约为 274%。两层材料的接触角都适合细胞生长和细胞相容性,而双层材料则显示出中等的机械响应,与每一层材料相比,酶降解率更低。双层材料模拟了本地小口径血管的许多特性,从而为进一步研究体内血管提供了机会。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Biomimetic bilayer scaffold from Bombyx mori silk materials for small diameter vascular applications in tissue engineering.

Enhancing the biocompatibility and mechanical stability of small diameter vascular scaffolds remain significant challenges. To address this challenge, small-diameter tubular structures were electrospun from silk fibroin (SF) from silk textile industry discarded materials to generate bilayer scaffolds that mimic native blood vessels, but derived from a sustainable natural material resource. The inner layer was obtained by directly dissolving SF in formic acid, while the middle layer (SF-M) was achieved through aqueous concentration of the protein. Structural and biological properties of each layer as well as the bilayer were evaluated. The inner layer exhibited nano-scale fiber diameters and 57.9% crystallinity, and degradation rates comparable with the SF-M layer. The middle layer displayed micrometer-scale fibers diameters with an ultimate extension of about 274%. Both layers presented contact angles suitable for cell growth and cytocompatibility, while the bilayer material displayed an intermediate mechanical response and a reduced enzymatic degradation rate when compared to each individual layer. The bilayer material emulates many of the characteristics of native small-diameter vessels, thereby suggesting further studies towards in vivo opportunities.

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