Advances in Electrospun Nanofibers: Versatile Materials and Diverse Biomedical Applications

IF 14 Q1 CHEMISTRY, MULTIDISCIPLINARY
Chenlong Wang, Yajuan Su and Jingwei Xie*, 
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引用次数: 0

Abstract

Electrospining has emerged as a versatile and transformative technique for the fabrication of nanofiber materials, which have been shown to be promising in applications across various biomedical domains. Cutting-edge research in electrospinning technology is centered on enhancing versatility, efficiency, and functionality of electrospun nanofibers through several key facets. These include the development of advanced materials, with ongoing exploration into novel polymer systems spanning synthetic polymers, natural polymers, and polymer blends to broaden the spectrum of achievable properties and functions. Additionally, there is significant emphasis on controlling fiber size, morphology, and alignment. Surface functionalization with bioactive molecules, drugs, or targeting ligands enhances specific functionalities like antimicrobial properties, cell adhesion, or targeted drug delivery. Furthermore, researchers are delving into the creation of multifunctional hybrid structures by integrating electrospinning with other fabrication techniques such as 3D printing, microfluidics, or layer-by-layer assembly, enabling customized properties and functionalities. Lastly, there is a strong fucus on biomedical applications, leveraging electrospun nanofibers for tissue engineering, wound healing, drug delivery, and biosensing, aiming to develop biocompatible and bioresorbable scaffolds with controlled structural and bioactive cues to promote tissue regeneration and repair.

However, several significant questions remain unanswered. For instance, can electrospun nanofibers sustainably deliver immunomodulating compounds topically to enhance human innate immunity? Is it possible to develop a robust approach for fabricating 3D nanofiber scaffolds with precise shapes and controlled characteristics such as fiber alignment, porosity, and pore size? Can these scaffolds be implanted into the body using minimal invasive surgery considering their current requirement for invasive surgical implantation? Additionally, can electrospun nanofibers be processed into microspheres or microcarriers for injectable therapy, and how effectively can they integrate with other technologies?

Over the past decade, our laboratory has focused on addressing these questions. In this Account, we present an overview of recent developments of electrospun nanofiber materials, emphasizing their modifications, unique structures, integration with other technologies, and diverse biomedical applications. We begin by outlining and comparing three methods for modifying electrospun nanofibers, laying the groundwork for selecting the most appropriate technique. Subsequently, we summarize methods for engineering novel forms of electrospun nanofiber materials. Further, we explore the integration of electrospun nanofibers with other technologies, such as microfluidic chips, microneedles, and electrostatic flocking. Following this, we highlight several notable biomedical applications, including infection control, hemostasis, tissue regeneration, and biological sample collection. Finally, we assess the future possibilities of electrospun nanofiber materials. The remarkable versatility demonstrated by electrospun nanofibers, as evidenced in this Account, opens up a myriad of possibilities in materials science, biomedicine, and beyond. By leveraging their potential for modification, 3D structuring, integration with other technologies, and various applications, electrospun nanofibers continue to advance our capabilities in tackling critical biomedical challenges and fostering innovative solutions.

Abstract Image

电纺纳米纤维的研究进展:多功能材料和多样化生物医学应用
电纺丝已成为制造纳米纤维材料的一种多用途变革性技术,在各种生物医学领域的应用中都大有可为。电纺技术的前沿研究主要集中在通过几个关键方面提高电纺纳米纤维的多功能性、效率和功能。其中包括开发先进材料,不断探索新型聚合物系统,包括合成聚合物、天然聚合物和聚合物混合物,以拓宽可实现的性能和功能范围。此外,对纤维尺寸、形态和排列的控制也是重点。用生物活性分子、药物或靶向配体进行表面功能化可增强特定功能,如抗菌性、细胞粘附性或靶向给药性。此外,研究人员还通过将电纺丝与三维打印、微流体或逐层组装等其他制造技术相结合,深入研究多功能混合结构的创造,从而实现定制的特性和功能。最后,电纺纳米纤维在组织工程、伤口愈合、药物输送和生物传感方面的生物医学应用也十分突出,其目的是开发具有可控结构和生物活性线索的生物相容性和生物可吸收性支架,以促进组织再生和修复。例如,电纺纳米纤维能否可持续地局部递送免疫调节化合物以增强人体先天免疫力?是否有可能开发出一种稳健的方法,用于制造具有精确形状和可控特性(如纤维排列、孔隙率和孔径)的三维纳米纤维支架?考虑到目前侵入性手术植入的要求,这些支架能否通过微创手术植入人体?此外,电纺纳米纤维能否加工成用于注射治疗的微球或微载体,以及它们与其他技术的有效结合程度如何?在本报告中,我们将概述电纺纳米纤维材料的最新发展,重点介绍它们的改性、独特结构、与其他技术的整合以及各种生物医学应用。首先,我们概述并比较了改性电纺纳米纤维的三种方法,为选择最合适的技术奠定了基础。随后,我们总结了设计新型电纺纳米纤维材料的方法。此外,我们还探讨了电纺纳米纤维与微流控芯片、微针和静电植绒等其他技术的整合。随后,我们重点介绍了几种著名的生物医学应用,包括感染控制、止血、组织再生和生物样本采集。最后,我们评估了电纺纳米纤维材料的未来可能性。正如本开户绑定手机领体验金所证明的那样,电纺纳米纤维所表现出的卓越多功能性为材料科学、生物医学及其他领域带来了无数可能性。通过利用电纺纳米纤维在改性、三维结构、与其他技术整合以及各种应用方面的潜力,电纺纳米纤维将继续推动我们应对重大生物医学挑战和开发创新解决方案的能力。
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
17.70
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