材料科学
纳米技术
蜘蛛丝
韧性
粘附
水下
丝绸
自愈水凝胶
复合材料
高分子化学
海洋学
地质学
作者
Eugene Kim,Juya Jeon,Yaguang Zhu,Ethan D. Hoppe,Young‐Shin Jun,Guy M. Genin,Fuzhong Zhang
标识
DOI:10.1021/acsami.1c14182
摘要
Strong underwater adhesives are attractive materials for biomedical healing and underwater repair, but their success in applications has been limited, owing to challenges with underwater setting and with balancing surface adhesion and cohesion. Here, we applied synthetic biology approaches to overcome these challenges through design and synthesis of a novel hybrid protein consisting of the zipper-forming domains of an amyloid protein, flexible spider silk sequences, and a dihydroxyphenylalanine (DOPA)-containing mussel foot protein (Mfp). This partially structured, hybrid protein can self-assemble into a semi-crystalline hydrogel that exhibits high strength and toughness as well as strong underwater adhesion to a variety of surfaces, including difficult-to-adhere plastics, tendon, and skin. The hydrogel allows selective debonding by oxidation or iron-chelating treatments. Both the material design and the biosynthetic approach explored in this study will inspire future work for a wide range of hybrid protein-based materials with tunable properties and broad applications.
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