膨胀水凝胶纳米技术:水凝胶基本溶胀特性的高级应用

Rong Wang , Chongling Cheng , Huiyun Wang , Dayang Wang
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引用次数: 0

摘要

水凝胶是由交联亲水性聚合物组成的三维网络,由于其优异的吸水性和溶胀性,已成为各种先进应用的关键。本综述基于水凝胶独特的溶胀特性,探讨了水凝胶在传统给药应用之外的其他应用,重点关注大气集水、水凝胶致动器、膨胀显微镜(ExM)以及通过受控消肿实现的三维纳米制造。我们首先讨论了影响水凝胶膨胀的因素,如网络尺寸和聚合物特性。接着,我们探讨了水凝胶膨胀的内在机制,强调了各种作用力之间的相互作用。水凝胶的溶胀使 ExM 能够对生物组织进行超分辨率成像,而水凝胶的受控脱水则有助于以纳米级精度创建复杂的三维结构--这是增材制造技术的一大突破。尽管有这些优势,挑战依然存在。在本综述的最后,我们强调了跨学科研究的必要性,以解决这些局限性并释放水凝胶技术的全部潜力。水凝胶研究的未来有望为环境科学、机器人技术和生物医学成像做出革命性的贡献。
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Swollen hydrogel nanotechnology: Advanced applications of the rudimentary swelling properties of hydrogels
Hydrogels, which are three-dimensional networks of crosslinked hydrophilic polymers, have become crucial for various advanced applications owing to their exceptional water absorption and swelling properties. This review explores the applications of hydrogels based on their unique swelling properties, beyond their application in traditional drug delivery, focusing on atmospheric water harvesting, hydrogel actuator, expansion microscopy (ExM), and 3D nanofabrication through controlled deswelling. We first discuss the factors influencing hydrogel swelling, such as network size and polymer properties. Next, we explore the mechanisms underlying hydrogel swelling, emphasizing the interplay between various forces. Hydrogel swelling enables ExM for super-resolution imaging of biological tissues, while controlled deswelling of hydrogels facilitates the creation of intricate 3D structures with nanoscale precision—a breakthrough for additive manufacturing techniques. Despite these advantages, challenges still remain. We conclude this review by emphasizing the need for interdisciplinary research to address these limitations and unlock the full potential of the hydrogel technology. The future of hydrogel research holds promise for revolutionary contributions to environmental science, robotics, and biomedical imaging.
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