Highly stretchable, self-healing, antibacterial, conductive, and amylopectin-enhanced hydrogels with gallium droplets loading as strain sensors

In this study, we address the challenge of developing highly conductive hydrogels with enhanced stretchability for use in wearable sensors, which are critical for the precise detection of human motion and subtle physiological strains. Our novel approach utilizes amylopectin, a biopolymer, for the un...

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Bibliographic Details
Published in:Carbohydrate polymers 2024-10, Vol.342, p.122357, Article 122357
Main Authors: Hu, Feihong, Dong, Baoting, Yu, Dehai, Zhao, Rui, Chen, Wei, Song, Zhaoping, Lu, Peng, Zhang, Fengshan, Wang, Zhaojiang, Liu, Xiaona, Wang, Huili, Liu, Wenxia, Li, Huihui
Format: Article
Language:English
Subjects:
Amylopectin - chemistry
Amylopectin-enhanced hydrogels
Anti-Bacterial Agents - chemistry
Anti-Bacterial Agents - pharmacology
Bio-compatible conductive hydrogels
Elasticity
Electric Conductivity
Escherichia coli - drug effects
Flexible strain sensors
Gallium - chemistry
Human-computer interaction
Humans
Hydrogels - chemistry
Hydrogels - pharmacology
Liquid metal
Microbial Sensitivity Tests
Staphylococcus aureus - drug effects
Wearable Electronic Devices
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Summary:In this study, we address the challenge of developing highly conductive hydrogels with enhanced stretchability for use in wearable sensors, which are critical for the precise detection of human motion and subtle physiological strains. Our novel approach utilizes amylopectin, a biopolymer, for the uniform integration of liquid metal gallium into the hydrogel matrix. This integration results in a conductive hydrogel characterized by remarkable elasticity (up to 7100 % extensibility) and superior electrical conductance (Gauge Factor = 31.4), coupled with a minimal detection limit of less than 0.1 % and exceptional durability over 5000 cycles. The hydrogel demonstrates significant antibacterial activity, inhibiting microbial growth in moist environments, thus enhancing its applicability in medical settings. Employing a synthesis process that involves ambient condition polymerization of acrylic acid, facilitated by a hydrophobic associative framework, this hydrogel stands out for its rapid gelation and robust mechanical properties. The potential applications of this hydrogel extend beyond wearable sensors, promising advancements in human-computer interaction through technologies like wireless actuation of robotic systems. This study not only introduces a viable material for current wearable technologies but also sets a foundation for future innovations in bio-compatible sensors and interactive devices. [Display omitted]
ISSN:0144-8617
1879-1344
1879-1344
DOI:10.1016/j.carbpol.2024.122357