Rapid-response water-shrink films with high output work density based on polyethylene oxide and α-cyclodextrin for autonomous wound closure

Rapid-response water-shrink films with high output work density based on polyethylene oxide and α-cyclodextrin for autonomous wound closure

Conventional wound closure methods, including sutures and tissue adhesives, present significant challenges for self-care treatment, particularly in the context of bleeding wounds. Existing stimuli-responsive contractile materials designed for autonomous wound closure frequently lack sufficient outpu...

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Bibliographic Details
Main Authors: Yi, Junqi, Ren, Xueyang, Li, Yanzhen, Yuan, Yuehui, Tang, Wenjie, Wang, Xiaoshi, Yu, Jing, Yu, Shujin, Li, Wenlong, Wang, Jianwu, Loh, Xian Jun, Hu, Benhui, Chen, Xiaodong
Other Authors: School of Materials Science and Engineering
Format: Article
Language:English
Published: 2024
Subjects:
Engineering
Polymer actuator
Supercontraction
Online Access:https://hdl.handle.net/10356/179480
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Institution: Nanyang Technological University
Language: English
Description
Summary:Conventional wound closure methods, including sutures and tissue adhesives, present significant challenges for self-care treatment, particularly in the context of bleeding wounds. Existing stimuli-responsive contractile materials designed for autonomous wound closure frequently lack sufficient output work density to generate the force needed to bring the wound edges into proximity or necessitate stimuli that are not compatible with the human body. Here, semi-transparent, flexible, and water-responsive shrinkable films, composed of poly(ethylene oxide) and α-cyclodextrin, are reported. These films exhibit remarkable stability under ambient conditions and demonstrate significant contraction (≈50%) within 6 s upon exposure to water, generating substantial contractile stress (up to 6 MPa) and output work density (≈1028 kJ m-3), which is 100 times larger than that of conventional hydrogel and 25 times larger than that of skeletal muscles. Remarkably, upon hydration, these films are capable of lifting objects 10 000 times their own weight. Leveraging this technology, water-shrink tapes, which, upon contact with water, effectively constrict human skin and autonomously close bleeding wounds in animal models within 10 seconds, are developed further. This work offers a novel approach to skin wound management, showing significant potential for emergency and self-care scenarios.

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