Yiliu Wang , Yu Zhang , Qi Zhang , Xia Li , Qinglong Yan , Ying Zhu
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引用次数: 0
Abstract
DNA hydrogels are three-dimensional polymer networks constructed using DNA as the structural building block. Due to the tight binding between hydrophilic groups on DNA chains and water molecules, they exhibit outstanding plasticity and fluid thermodynamic properties, making them one of the best choices for mimicking natural biological tissues. By controlling the backbone building blocks, gelation conditions, and cross-linking methods of DNA hydrogels, hydrogels with different mechanical strengths can be obtained, thus expanding their applications in the field of biology. This review first introduces the relationship between the mechanical properties of DNA hydrogels and their structure, elucidates the approaches and strategies for mechanical property modulation, and focuses on the scheme of controllable design to modulate the mechanical properties of DNA hydrogels for applications in biosensing, cellular function regulation, and bone tissue engineering. Furthermore, this review outlines the future development directions and challenges faced in the mechanical property modulation of DNA hydrogels, providing useful information for the precise design of DNA hydrogels for biological research.
DNA 水凝胶是以 DNA 为结构单元构建的三维聚合物网络。由于 DNA 链上的亲水基团与水分子紧密结合,它们具有出色的可塑性和流体热力学特性,是模拟天然生物组织的最佳选择之一。通过控制 DNA 水凝胶的骨架构建模块、凝胶化条件和交联方法,可以获得不同机械强度的水凝胶,从而拓展其在生物学领域的应用。本综述首先介绍了 DNA 水凝胶的力学性能与其结构之间的关系,阐明了调控力学性能的方法和策略,并重点介绍了调控 DNA 水凝胶力学性能的可控设计方案,以应用于生物传感、细胞功能调控和骨组织工程等领域。此外,本综述还概述了 DNA 水凝胶机械性能调控的未来发展方向和面临的挑战,为生物研究中 DNA 水凝胶的精确设计提供了有用信息。
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