Basic Science Research Center, Department of Physics, and Department of Energy Systems Research, Ajou University, Suwon, 16499, Republic of Korea.
Panoptics Corporation, Seongnam, 13516, Republic of Korea.
Adv Mater. 2021 Jun;33(24):e2008308. doi: 10.1002/adma.202008308. Epub 2021 May 6.
Epidermal electronic systems for detecting electrophysiological signals, sensing, therapy, and drug delivery are at the frontier in man-machine interfacing for healthcare. However, it is still a challenge to develop multifunctional bioapplications with minimal invasiveness, biocompatibility, and stable electrical performance under various mechanical deformations of biological tissues. In this study, a natural silk protein with carbon nanotubes (CNTs) is utilized to realize an epidermal electronic tattoo (E-tattoo) system for multifunctional applications that address these challenging issues through dispersing highly conductive CNTs onto the biocompatible silk nanofibrous networks with porous nature to construct skin-adhesive ultrathin electronic patches. Individual components that incorporate electrically and optically active heaters, a temperature sensor (temperature coefficient of resistance of 5.2 × 10 °C ), a stimulator for drug delivery (>500 µm penetration depth in skin), and real-time electrophysiological signal detectors are described. This strategy of E-tattoos integrated onto human skin can open a new route to a next-generation electronic platform for wearable and epidermal bioapplications.
用于检测电生理信号、传感、治疗和药物输送的表皮电子系统是人机界面在医疗保健领域的前沿。然而,开发具有最小侵入性、生物相容性和在生物组织的各种机械变形下稳定的电性能的多功能生物应用仍然是一个挑战。在这项研究中,利用天然丝蛋白和碳纳米管 (CNT) 来实现表皮电子纹身 (E-tattoo) 系统,该系统具有多功能应用,通过将高导电性 CNT 分散到具有多孔性质的生物相容性丝纳米纤维网络上来构建皮肤贴合式超薄电子贴片,解决了这些具有挑战性的问题。描述了整合到人体皮肤上的 E-tattoo 的各个组件,包括电和光活性加热器、温度传感器(电阻温度系数为 5.2×10-°C)、用于药物输送的刺激器(>500 µm 渗透深度的皮肤)和实时电生理信号检测器。这种集成到人体皮肤上的 E-tattoo 策略为可穿戴和表皮生物应用的下一代电子平台开辟了新途径。
