TY - JOUR
T1 - Protein fibers with self-recoverable mechanical properties via dynamic imine chemistry
AU - Sun, Jing
AU - He, Haonan
AU - Zhao, Kelu
AU - Cheng, Wenhao
AU - Li, Yuanxin
AU - Zhang, Peng
AU - Wan, Sikang
AU - Liu, Yawei
AU - Wang, Mengyao
AU - Li, Ming
AU - Wei, Zheng
AU - Li, Bo
AU - Zhang, Yi
AU - Li, Cong
AU - Sun, Yao
AU - Shen, Jianlei
AU - Li, Jingjing
AU - Wang, Fan
AU - Ma, Chao
AU - Tian, Yang
AU - Su, Juanjuan
AU - Chen, Dong
AU - Fan, Chunhai
AU - Zhang, Hongjie
AU - Liu, Kai
N1 - Publisher Copyright:
© 2023, Springer Nature Limited.
PY - 2023/12
Y1 - 2023/12
N2 - The manipulation of internal interactions at the molecular level within biological fibers is of particular importance but challenging, severely limiting their tunability in macroscopic performances and applications. It thus becomes imperative to explore new approaches to enhance biological fibers’ stability and environmental tolerance and to impart them with diverse functionalities, such as mechanical recoverability and stimulus-triggered responses. Herein, we develop a dynamic imine fiber chemistry (DIFC) approach to engineer molecular interactions to fabricate strong and tough protein fibers with recoverability and actuating behaviors. The resulting DIF fibers exhibit extraordinary mechanical performances, outperforming many recombinant silks and synthetic polymer fibers. Remarkably, impaired DIF fibers caused by fatigue or strong acid treatment are quickly recovered in water directed by the DIFC strategy. Reproducible mechanical performance is thus observed. The DIF fibers also exhibit exotic mechanical stability at extreme temperatures (e.g., −196 °C and 150 °C). When triggered by humidity, the DIFC endows the protein fibers with diverse actuation behaviors, such as self-folding, self-stretching, and self-contracting. Therefore, the established DIFC represents an alternative strategy to strengthen biological fibers and may pave the way for their high-tech applications.
AB - The manipulation of internal interactions at the molecular level within biological fibers is of particular importance but challenging, severely limiting their tunability in macroscopic performances and applications. It thus becomes imperative to explore new approaches to enhance biological fibers’ stability and environmental tolerance and to impart them with diverse functionalities, such as mechanical recoverability and stimulus-triggered responses. Herein, we develop a dynamic imine fiber chemistry (DIFC) approach to engineer molecular interactions to fabricate strong and tough protein fibers with recoverability and actuating behaviors. The resulting DIF fibers exhibit extraordinary mechanical performances, outperforming many recombinant silks and synthetic polymer fibers. Remarkably, impaired DIF fibers caused by fatigue or strong acid treatment are quickly recovered in water directed by the DIFC strategy. Reproducible mechanical performance is thus observed. The DIF fibers also exhibit exotic mechanical stability at extreme temperatures (e.g., −196 °C and 150 °C). When triggered by humidity, the DIFC endows the protein fibers with diverse actuation behaviors, such as self-folding, self-stretching, and self-contracting. Therefore, the established DIFC represents an alternative strategy to strengthen biological fibers and may pave the way for their high-tech applications.
UR - https://www.scopus.com/pages/publications/85169666170
U2 - 10.1038/s41467-023-41084-1
DO - 10.1038/s41467-023-41084-1
M3 - 文章
C2 - 37660126
AN - SCOPUS:85169666170
SN - 2041-1723
VL - 14
JO - Nature Communications
JF - Nature Communications
IS - 1
M1 - 5348
ER -