Guo Zhongwei, Xu Xing, Qiu Jingjiang, Yu Wenlong, Zhang Shiqiang, Li Junfu, Zhu Yihong, Lu Junxia, Gao Qiulei, Nie Bangbang, Zhang Yudong, Qi Guochen, Wang Wen, Zhang Xiang, Jiang Liying, Wei Ronghan
School of Mechanics and Safety Engineering, Zhengzhou University, Zhengzhou 450001, China; Henan Province Engineering Technology Research Center of MEMS Manufacturing and Applications, Zhengzhou University, Zhengzhou 450001, China.
School of Mechanics and Safety Engineering, Zhengzhou University, Zhengzhou 450001, China.
Int J Biol Macromol. 2024 Dec;282(Pt 6):137576. doi: 10.1016/j.ijbiomac.2024.137576. Epub 2024 Nov 13.
Soft electronic products are being extensively investigated in diverse applications including sensors and devices, due to their superior softness, responsiveness, and biocompatibility. One-dimensional (1-D) fiber electronic devices are recognized for their lightweight, wearable, and stretchable qualities, thus emerging as critical constituents for seamless integration with the human body and attire, exhibiting great potential in wearable applications. However, wearable conductive hydrogel fibers usually face challenges in combining stretchability and excellent stability, notably in high-temperature environment. Herein, a novel stretchable conductive hydrogel fiber, namely PVA-CS-CNT (Polyvinyl Alcohol-Chitosan-Carbon Nanotube) hydrogel fiber, was successfully prepared through a straightforward low-temperature process. This hydrogel fiber not only maintains stable signal transmission at high temperatures but also exhibits significant mechanical and sensing capabilities, ensuring signal stability during repetitive cyclic stretching. Inspired by fishing net, textile sensors were fabricated by weaving PVA-CS-CNT hydrogel fibers, which offered breathability, high stability (withstanding over 500 stretch cycles), high sensitivity (detecting strains as low as 1 %), and exceptional mechanical strength (exceeding 17 MPa). The wearable sensor could not only accurately monitor human movements like stretching and bending, but also adeptly captured delicate signals such as pulses and sounds. These characteristics demonstrated the potential applications of the hydrogel fibers encompassing human motion tracking, intelligent textiles, and soft robotics.
由于其卓越的柔软性、响应性和生物相容性,柔性电子产品正在包括传感器和设备在内的各种应用中得到广泛研究。一维(1-D)纤维电子器件因其轻质、可穿戴和可拉伸的特性而受到认可,因此成为与人体和服装无缝集成的关键组成部分,在可穿戴应用中展现出巨大潜力。然而,可穿戴导电水凝胶纤维通常在结合拉伸性和优异稳定性方面面临挑战,尤其是在高温环境下。在此,通过一种简单的低温工艺成功制备了一种新型可拉伸导电水凝胶纤维,即PVA-CS-CNT(聚乙烯醇-壳聚糖-碳纳米管)水凝胶纤维。这种水凝胶纤维不仅在高温下保持稳定的信号传输,还表现出显著的机械和传感能力,确保在重复循环拉伸过程中的信号稳定性。受渔网启发,通过编织PVA-CS-CNT水凝胶纤维制造了纺织传感器,该传感器具有透气性、高稳定性(可承受超过500次拉伸循环)、高灵敏度(可检测低至1%的应变)和出色的机械强度(超过17MPa)。这种可穿戴传感器不仅可以准确监测人体的拉伸和弯曲等运动,还能巧妙地捕捉脉搏和声音等细微信号。这些特性证明了水凝胶纤维在人体运动跟踪、智能纺织品和软机器人等方面的潜在应用。
