Electrospun Scaffolds for Tissue Engineering: A Review

Macromol Pub Date : 2023-08-03 DOI:10.3390/macromol3030031
G. G. Flores-Rojas, Bélen Gómez-Lazaro, F. López-Saucedo, R. Vera-Graziano, E. Bucio, E. Mendizábal
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引用次数: 3

Abstract

Tissue engineering and regenerative medicine have emerged as innovative approaches to enhance clinical outcomes by addressing tissue lesions and degenerations that can significantly impair organ function. Since human tissues have limited regenerative capacity, the field of regenerative medicine aims to restore damaged tissues and their functionalities. Recent decades have witnessed remarkable progress in materials science, tissue engineering, and medicine, leading to the development of regenerative engineering. This interdisciplinary field has revolutionized the production of artificial matrices, enabling the design of anatomically accurate structures with enhanced biocompatibility, bioabsorption, and cell adhesion. Among the techniques utilized for fabricating cellular scaffolds, the electrospinning of fibers stands out as an ideal approach due to its ability to mimic the characteristics of the extracellular matrix (ECM). Electrospun scaffolds exhibit distinct advantages, including a high surface area-to-volume ratio, exceptional porosity, uniformity, compositional diversity, structural flexibility, and the ease of functionalization with bioactive molecules for controlled release. These versatile properties allow for the creation of nanofiber scaffolds that closely resemble the architecture of the ECM. Consequently, they facilitate the transport of nutrients and oxygen to cells as well as the incorporation of growth factors to stimulate cell growth. These advancements open up a wide range of applications in the field of regenerative medicine.
电纺丝支架在组织工程中的应用综述
组织工程和再生医学已经成为一种创新的方法,通过解决可能严重损害器官功能的组织病变和变性来提高临床结果。由于人体组织的再生能力有限,再生医学领域旨在恢复受损组织及其功能。近几十年来,材料科学、组织工程和医学取得了显著进展,导致了再生工程的发展。这一跨学科领域已经彻底改变了人工基质的生产,使解剖学上精确的结构设计具有增强的生物相容性,生物吸收和细胞粘附性。在用于制造细胞支架的技术中,纤维的静电纺丝由于其模仿细胞外基质(ECM)特性的能力而成为一种理想的方法。电纺丝支架具有明显的优势,包括高表面积体积比、优异的孔隙率、均匀性、成分多样性、结构灵活性以及易于与生物活性分子功能化以控制释放。这些多用途的特性使得纳米纤维支架的创建与ECM的结构非常相似。因此,它们促进营养物质和氧气向细胞的运输,并结合生长因子来刺激细胞生长。这些进展为再生医学开辟了广阔的应用领域。
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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CiteScore
5.20
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