Recent advances in coacervation and underlying noncovalent molecular interaction mechanisms

IF 26 1区化学 Q1 POLYMER SCIENCE

Progress in Polymer Science Pub Date : 2024-05-08 DOI:10.1016/j.progpolymsci.2024.101827

Qiongyao Peng , Tao Wang , Diling Yang, Xuwen Peng, Hao Zhang, Hongbo Zeng

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Abstract

Coacervation is a liquid-liquid phase separation phenomenon. It involves the formation of a dense coacervate phase, rich in concentrated materials, and a co-existing immiscible dilute supernatant. This phenomenon can occur either from a homogeneous aqueous solution (simple coacervation) or when two different macromolecular aqueous solutions (proteins, polymers, and colloids) are brought into contact (complex coacervation). Coacervation has historical significance as it may have played a role in the origin of life, concentrating nutritious materials through liquid-liquid phase separation. It also reveals the underlying mechanisms of many biological phenomena such as intracellular biomolecular condensates, extracellular matrices, squid beak's gradient properties, sessile organism's wet adhesion, Alzheimer's diseases, and more. Coacervation provides insights and inspires promising solutions in areas like artificial cells/tissues, gradient materials, gene/drug delivery, underwater adhesives, and beyond. The driving forces of coacervation are noncovalent molecular interactions, often referred to as ‘chemistry beyond the molecule’, including hydrophobic interaction, electrostatic interaction, hydrogen-bonding interaction, cation-π interaction, π-π interaction, multivalency, etc. In this work, we have systematically reviewed the underlying noncovalent molecular interactions of simple coacervation and complex coacervation, respectively. We summarize commonly used materials and their corresponding molecular structures, discussing their applications. Some remaining challenge issues and perspectives for future studies are also presented. Understanding the underlying noncovalent molecular interactions of coacervation, alongside insights into molecular compositions and structures, can better guide the design of novel materials, elucidate various biological phenomena, and contribute to the development and optimization of relevant engineering technologies.

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共保持和基本非共价分子相互作用机制的最新进展

凝聚是一种液-液相分离现象。它包括形成富含浓缩物质的致密凝聚相和共存不相溶的稀释上清液。这种现象既可能发生在均相水溶液中（简单凝聚），也可能发生在两种不同的大分子水溶液（蛋白质、聚合物和胶体）接触时（复杂凝聚）。共凝具有重要的历史意义，因为它可能在生命起源过程中发挥了作用，通过液-液相分离浓缩了营养物质。它还揭示了许多生物现象的内在机理，如细胞内生物分子凝聚物、细胞外基质、乌贼喙的梯度特性、无柄生物的湿粘附、老年痴呆症等。共保温为人造细胞/组织、梯度材料、基因/药物输送、水下粘合剂等领域提供了深入的见解和有前景的解决方案。共保持的驱动力是非共价分子相互作用，通常被称为 "分子外化学"，包括疏水相互作用、静电相互作用、氢键相互作用、阳离子-π相互作用、π-π相互作用、多价相互作用等。在这项工作中，我们分别对简单共保持和复杂共保持的基本非共价分子相互作用进行了系统回顾。我们总结了常用材料及其相应的分子结构，并讨论了它们的应用。此外，还介绍了一些尚存的挑战问题和未来研究的前景。了解共保持的基本非共价分子相互作用以及对分子组成和结构的见解，可以更好地指导新型材料的设计，阐明各种生物现象，并有助于相关工程技术的开发和优化。

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来源期刊

Progress in Polymer Science 化学-高分子科学

CiteScore

48.70

自引率

1.10%

发文量

审稿时长

38 days

期刊介绍： Progress in Polymer Science is a journal that publishes state-of-the-art overview articles in the field of polymer science and engineering. These articles are written by internationally recognized authorities in the discipline, making it a valuable resource for staying up-to-date with the latest developments in this rapidly growing field. The journal serves as a link between original articles, innovations published in patents, and the most current knowledge of technology. It covers a wide range of topics within the traditional fields of polymer science, including chemistry, physics, and engineering involving polymers. Additionally, it explores interdisciplinary developing fields such as functional and specialty polymers, biomaterials, polymers in drug delivery, polymers in electronic applications, composites, conducting polymers, liquid crystalline materials, and the interphases between polymers and ceramics. The journal also highlights new fabrication techniques that are making significant contributions to the field. The subject areas covered by Progress in Polymer Science include biomaterials, materials chemistry, organic chemistry, polymers and plastics, surfaces, coatings and films, and nanotechnology. The journal is indexed and abstracted in various databases, including Materials Science Citation Index, Chemical Abstracts, Engineering Index, Current Contents, FIZ Karlsruhe, Scopus, and INSPEC.