Silk Fibroin Hybrids for Biological Scaffolds with Adhesive Surface and Adaptability to the Target Tissue Change

IF 1.2 Q3 MULTIDISCIPLINARY SCIENCES
S. Ciabattini, V. Raggi, L. Valentini, A. Morabito
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引用次数: 1

Abstract

Abstract Background Regenerative Medicine (RM) is a branch of medicine that aims to regenerate tissues and organs to overcome the problems transplants entail (poor availability, risk of rejection and intense immunosuppression). To do this, RM makes use of tissue engineering (TE). This fundamental branch deals with creating biological scaffolds capable of performing the role that physiologically belongs to the extracellular matrix (ECM). In this review, we report how specific characteristics of the scaffolds (bio-compatibility, biodegradability and mechanical and conformal properties) can be obtained using 3D printing, which facilitates the emulation of physiological tissues and organs. Purpose and scope This review reports recent advances in the fabrication method of bioactive scaffolds that can be used clinically, providing support for cell seeding and proliferation. To this end, silk fibroin, tannin and graphene were used to improve the scaffold’s electro-bio-mechanical properties. These materials in different compositions are studied to demonstrate their potential use as bio-ink in bioadhesives and cellularized and implantable 3D-printed scaffolds. Summary of new synthesis and conclusions reached in the review Silk fibroin is a natural biopolymer; tannin, on the other hand, is a biological polyphenol, highly reactive with other molecules by nature and with promising antioxidant capabilities. Finally, graphene is nothing more than a monolayer of graphite that has been shown to implement the mechanics and electrical conductivity of the compounds in which it is inserted; it also has excellent biocompatibility and surface area, qualities that promote cell adhesion and growth. Conclusion Polyphenols and graphene have been shown to work in synergy in improving the electro-mechanical properties of silk fibroin scaffolds. We reported optimal and potentially market-competitive bioadhesives, but above all, the proliferation of neuronal precursor cells in vitro was successfully demonstrated.
具有粘附表面和对目标组织变化适应性的生物支架用丝素蛋白杂交种
再生医学(RM)是医学的一个分支,旨在再生组织和器官,以克服移植所带来的问题(可获得性差,排斥风险和强烈的免疫抑制)。为了做到这一点,RM利用组织工程(TE)。这一基本分支涉及创造能够发挥生理上属于细胞外基质(ECM)作用的生物支架。在这篇综述中,我们报告了如何使用3D打印获得支架的特定特性(生物相容性,生物降解性以及机械和保形性能),从而促进生理组织和器官的模拟。目的与范围本文综述了近年来临床应用的生物活性支架的制备方法,为细胞的播种和增殖提供支持。为此,使用丝素、单宁和石墨烯来改善支架的电-生物力学性能。研究人员对这些不同成分的材料进行了研究,以证明它们在生物粘合剂和细胞化和可植入的3d打印支架中作为生物墨水的潜在用途。丝素蛋白是一种天然的生物高聚物。另一方面,单宁是一种生物多酚,与其他分子具有高度活性,具有良好的抗氧化能力。最后,石墨烯只不过是一层石墨,已经被证明可以实现它所插入的化合物的力学和导电性;它还具有良好的生物相容性和表面积,促进细胞粘附和生长的品质。结论多酚和石墨烯在改善丝素蛋白支架的机电性能方面具有协同作用。我们报告了最佳的和具有潜在市场竞争力的生物粘合剂,但最重要的是,神经前体细胞的体外增殖被成功证明。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
The EuroBiotech Journal
The EuroBiotech Journal Agricultural and Biological Sciences-Food Science
CiteScore
3.60
自引率
0.00%
发文量
17
审稿时长
10 weeks
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