生物启发聚合物自组装综述:单组分和相互作用聚合物系统。

IF 3.4 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY
Xiangxi Meng
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引用次数: 2

摘要

生物学展示了精细的方法来控制生物材料自组装成有序和无序的结构来进行必要的生物过程。使合成聚合物能够像生物材料一样自组装是高分子物理研究的一个标志。与蛋白质工程不同,聚合物科学通过有意地将特定的功能基团嵌入到聚合物的骨架中,同时分离其他功能基团,从而揭开自组装的神秘面纱。聚合物领域现在已经进入了一个通过在很大程度上模仿自然来推进材料设计的时代。例如,我们可以制造序列特异性聚合物来研究类似于研究蛋白质的高度有序的介观结构,并使用带电聚合物来研究无膜细胞器中的液-液相分离。本文综述了近年来利用仿生策略在单组分和多组分系统上研究自组装的进展。序列定义技术用于制造按需杂化材料,以分离手性和化学在合成嵌段共聚物自组装中的影响。与此同时,序列模式导致更多的层次组装仅由疏水和亲水单体组成。本文的后半部分讨论了由于带相反电荷的聚电解质的结合电荷相互作用而形成的复杂凝聚。可调的相行为和粘弹性是研究液相分离的独特之处,因为聚合物的缓慢弛豫主要来自电荷相互作用。生物启发聚合物自组装的研究显著影响我们如何在分子水平上优化用户自定义材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A mini-review on bio-inspired polymer self-assembly: single-component and interactive polymer systems.

Biology demonstrates meticulous ways to control biomaterials self-assemble into ordered and disordered structures to carry out necessary bioprocesses. Empowering the synthetic polymers to self-assemble like biomaterials is a hallmark of polymer physics studies. Unlike protein engineering, polymer science demystifies self-assembly by purposely embedding particular functional groups into the backbone of the polymer while isolating others. The polymer field has now entered an era of advancing materials design by mimicking nature to a very large extend. For example, we can make sequence-specific polymers to study highly ordered mesostructures similar to studying proteins, and use charged polymers to study liquid-liquid phase separation as in membraneless organelles. This mini-review summarizes recent advances in studying self-assembly using bio-inspired strategies on single-component and multi-component systems. Sequence-defined techniques are used to make on-demand hybrid materials to isolate the effects of chirality and chemistry in synthetic block copolymer self-assembly. In the meantime, sequence patterning leads to more hierarchical assemblies comprised of only hydrophobic and hydrophilic comonomers. The second half of the review discusses complex coacervates formed as a result of the associative charge interactions of oppositely charged polyelectrolytes. The tunable phase behavior and viscoelasticity are unique in studying liquid macrophase separation because the slow polymer relaxation comes primarily from charge interactions. Studies of bio-inspired polymer self-assembly significantly impact how we optimize user-defined materials on a molecular level.

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来源期刊
CiteScore
7.70
自引率
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发文量
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