Mussel-inspired polymer materials derived from nonphytogenic and phytogenic catechol derivatives and their applications,Polymer International

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Mussel-inspired polymer materials derived from nonphytogenic and phytogenic catechol derivatives and their applications
Polymer International ( IF 2.9 ) Pub Date : 2021-04-05 , DOI: 10.1002/pi.6230
Hanzhang Wang _{1,

2} , Liuliu Wang _{1,

2} , Shifeng Zhang _{1,

2} , Wei Zhang _{1,

2} , Jianzhang Li _{1,

2} , Yanming Han ₃

Affiliation

When it comes to underwater adhesion, mussel is the true expert that can firmly attach onto wet rocks under dynamic and turbulent environments. Catechol-like 3,4-dihydroxyphenylalanine and its biochemical interactions have been largely implicated in mussels' strong adhesion to various substrates. We successfully determined that a copolymerization polymer molecule could be designed according to the catechol structural features and that high-performance biomimetic mussel materials can be prepared from petrochemical materials or renewable materials, and because of their excellent performance in various application areas show a broad application prospect. The adhesion mechanism of the mussel protein and the recent advances in biomimetic mussel protein polymers based on nonphytogenic catechol derivatives and phytogenic catechol derivatives from different sources are comprehensively summarized. By comparing the application of nonphytogenic catechol derivatives and phytogenic catechol derivatives in industrial and biomedical fields, we found that the synthesis of phytogenic catechol derivatives is more facile and universal, and their application performance is as good as that of nonphytogenic catechol derivatives. In addition, the challenges and prospects for this field in the future are also discussed. © 2021 Society of Industrial Chemistry.

中文翻译：

源自非植物源性和植物源性儿茶酚衍生物的贻贝聚合物材料及其应用

在水下附着力方面，贻贝是真正的专家，可以在动态和湍流环境下牢固地附着在潮湿的岩石上。儿茶酚样 3,4-二羟基苯丙氨酸及其生化相互作用在很大程度上与贻贝对各种底物的强附着力有关。我们成功确定了可以根据邻苯二酚的结构特征设计共聚聚合物分子，并且可以从石油化工材料或可再生材料中制备高性能仿生贻贝材料，因其在各个应用领域的优异性能显示出广阔的应用前景。 . 综合总结了贻贝蛋白的粘附机制以及基于不同来源的非植物源儿茶酚衍生物和植物源儿茶酚衍生物的仿生贻贝蛋白聚合物的最新进展。通过比较非植物性儿茶酚衍生物和植物性儿茶酚衍生物在工业和生物医学领域的应用，我们发现植物性儿茶酚衍生物的合成更加简便和通用，其应用性能与非植物性儿茶酚衍生物一样好。此外，还讨论了该领域未来的挑战和前景。© 2021 工业化学学会。通过比较非植物性儿茶酚衍生物和植物性儿茶酚衍生物在工业和生物医学领域的应用，我们发现植物性儿茶酚衍生物的合成更加简便和通用，其应用性能与非植物性儿茶酚衍生物一样好。此外，还讨论了该领域未来的挑战和前景。© 2021 工业化学学会。通过比较非植物性儿茶酚衍生物和植物性儿茶酚衍生物在工业和生物医学领域的应用，我们发现植物性儿茶酚衍生物的合成更加简便和通用，其应用性能与非植物性儿茶酚衍生物一样好。此外，还讨论了该领域未来的挑战和前景。© 2021 工业化学学会。

更新日期：2021-04-05

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