用于生物医学的生物灵感粘合剂水凝胶-原理和设计策略

Smart medicine Pub Date : 2022-12-25 eCollection Date: 2022-12-01 DOI:10.1002/SMMD.20220024
Wenzhao Li, Xinyuan Yang, Puxiang Lai, Luoran Shang
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引用次数: 0

摘要

在各种生物医学应用中,如医用贴片、组织密封剂和柔性电子设备等,都迫切需要水凝胶的粘合性。然而,生物组织通常潮湿、柔软、可移动且易受损。这些特点给医用粘性水凝胶的制造带来了困难。在自然界中,生物坚持独特的策略,如章鱼的可逆吸盘粘附和贻贝的无毒且牢固的儿茶酚化学性质,这为医用水凝胶克服上述挑战提供了许多启示。在这篇综述中,我们将生物粘附策略系统地分为结构相关策略和分子相关策略,几乎涵盖了所有已知的生物粘附范例。我们概述了这些策略的原理,并总结了受其启发的医用粘合剂水凝胶的相应设计。最后,我们还提供了有关该领域发展的结论和展望。对于蓬勃发展的生物启发粘合水凝胶,本综述旨在总结和分析现有的各种理论,并从创新的角度为未来研究提供系统指导。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Bio-inspired adhesive hydrogel for biomedicine-principles and design strategies.

The adhesiveness of hydrogels is urgently required in various biomedical applications such as medical patches, tissue sealants, and flexible electronic devices. However, biological tissues are often wet, soft, movable, and easily damaged. These features pose difficulties for the construction of adhesive hydrogels for medical use. In nature, organisms adhere to unique strategies, such as reversible sucker adhesion in octopuses and nontoxic and firm catechol chemistry in mussels, which provide many inspirations for medical hydrogels to overcome the above challenges. In this review, we systematically classify bioadhesion strategies into structure-related and molecular-related ones, which cover almost all known bioadhesion paradigms. We outline the principles of these strategies and summarize the corresponding designs of medical adhesive hydrogels inspired by them. Finally, conclusions and perspectives concerning the development of this field are provided. For the booming bio-inspired adhesive hydrogels, this review aims to summarize and analyze the various existing theories and provide systematic guidance for future research from an innovative perspective.

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