Rapidly self-healing electronic skin for machine learning–assisted physiological and movement evaluation

Yongju Lee; Xinyu Tian; Jaewon Park; Dong Hyun Nam; Zhuohong Wu; Hyojeong Choi; Juhwan Kim; Dong Wook Park; Keren Zhou; Sang Won Lee; Tanveer A. Tabish; Xuanbing Cheng; Sam Emaminejad; Tae Woo Lee; Hyeok Kim; Ali Khademhosseini; Yangzhi Zhu

doi:10.1126/sciadv.ads1301

Rapidly self-healing electronic skin for machine learning–assisted physiological and movement evaluation

Yongju Lee
, Xinyu Tian
, Jaewon Park
, Dong Hyun Nam
, Zhuohong Wu
, Hyojeong Choi
, Juhwan Kim
, Dong Wook Park
, Keren Zhou
, Sang Won Lee
, Tanveer A. Tabish
, Xuanbing Cheng
, Sam Emaminejad
, Tae Woo Lee
, Hyeok Kim
, Ali Khademhosseini
, Yangzhi Zhu

School of Electrical and Computer Engineering

Research output: Contribution to journal › Article › peer-review

23 Scopus citations

Abstract

Emerging electronic skins (E-Skins) offer continuous, real-time electrophysiological monitoring. However, daily mechanical scratches compromise their functionality, underscoring urgent need for self-healing E-Skins resistant to mechanical damage. Current materials have slow recovery times, impeding reliable signal measurement. The inability to heal within 1 minute is a major barrier to commercialization. A composition achieving 80% recovery within 1 minute has not yet been reported. Here, we present a rapidly self-healing E-Skin tailored for real-time monitoring of physical and physiological bioinformation. The E-Skin recovers more than 80% of its functionality within 10 seconds after physical damage, without the need of external stimuli. It consistently maintains reliable biometric assessment, even in extreme environments such as underwater or at various temperatures. Demonstrating its potential for efficient health assessment, the E-Skin achieves an accuracy exceeding 95%, excelling in wearable muscle strength analytics and on-site AI-driven fatigue identification. This study accelerates the advancement of E-Skin through rapid self-healing capabilities.

Original language	English
Article number	eads1301
Journal	Science advances
Volume	11
Issue number	7
DOIs	https://doi.org/10.1126/sciadv.ads1301
State	Published - 14 Feb 2025

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Lee, Y., Tian, X., Park, J., Nam, D. H., Wu, Z., Choi, H., Kim, J., Park, D. W., Zhou, K., Lee, S. W., Tabish, T. A., Cheng, X., Emaminejad, S., Lee, T. W., Kim, H., Khademhosseini, A., & Zhu, Y. (2025). Rapidly self-healing electronic skin for machine learning–assisted physiological and movement evaluation. Science advances, 11(7), Article eads1301. https://doi.org/10.1126/sciadv.ads1301

@article{dc9ecd337d524d689378b7e6d691da84,

title = "Rapidly self-healing electronic skin for machine learning–assisted physiological and movement evaluation",

abstract = "Emerging electronic skins (E-Skins) offer continuous, real-time electrophysiological monitoring. However, daily mechanical scratches compromise their functionality, underscoring urgent need for self-healing E-Skins resistant to mechanical damage. Current materials have slow recovery times, impeding reliable signal measurement. The inability to heal within 1 minute is a major barrier to commercialization. A composition achieving 80\% recovery within 1 minute has not yet been reported. Here, we present a rapidly self-healing E-Skin tailored for real-time monitoring of physical and physiological bioinformation. The E-Skin recovers more than 80\% of its functionality within 10 seconds after physical damage, without the need of external stimuli. It consistently maintains reliable biometric assessment, even in extreme environments such as underwater or at various temperatures. Demonstrating its potential for efficient health assessment, the E-Skin achieves an accuracy exceeding 95\%, excelling in wearable muscle strength analytics and on-site AI-driven fatigue identification. This study accelerates the advancement of E-Skin through rapid self-healing capabilities.",

author = "Yongju Lee and Xinyu Tian and Jaewon Park and Nam, \{Dong Hyun\} and Zhuohong Wu and Hyojeong Choi and Juhwan Kim and Park, \{Dong Wook\} and Keren Zhou and Lee, \{Sang Won\} and Tabish, \{Tanveer A.\} and Xuanbing Cheng and Sam Emaminejad and Lee, \{Tae Woo\} and Hyeok Kim and Ali Khademhosseini and Yangzhi Zhu",

note = "Publisher Copyright: Copyright {\textcopyright} 2025 The Authors, some rights reserved.",

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doi = "10.1126/sciadv.ads1301",

language = "English",

volume = "11",

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AU - Lee, Yongju

AU - Tian, Xinyu

AU - Park, Jaewon

AU - Nam, Dong Hyun

AU - Wu, Zhuohong

AU - Choi, Hyojeong

AU - Kim, Juhwan

AU - Park, Dong Wook

AU - Zhou, Keren

AU - Lee, Sang Won

AU - Tabish, Tanveer A.

AU - Cheng, Xuanbing

AU - Emaminejad, Sam

AU - Lee, Tae Woo

AU - Kim, Hyeok

AU - Khademhosseini, Ali

AU - Zhu, Yangzhi

PY - 2025/2/14

Y1 - 2025/2/14

N2 - Emerging electronic skins (E-Skins) offer continuous, real-time electrophysiological monitoring. However, daily mechanical scratches compromise their functionality, underscoring urgent need for self-healing E-Skins resistant to mechanical damage. Current materials have slow recovery times, impeding reliable signal measurement. The inability to heal within 1 minute is a major barrier to commercialization. A composition achieving 80% recovery within 1 minute has not yet been reported. Here, we present a rapidly self-healing E-Skin tailored for real-time monitoring of physical and physiological bioinformation. The E-Skin recovers more than 80% of its functionality within 10 seconds after physical damage, without the need of external stimuli. It consistently maintains reliable biometric assessment, even in extreme environments such as underwater or at various temperatures. Demonstrating its potential for efficient health assessment, the E-Skin achieves an accuracy exceeding 95%, excelling in wearable muscle strength analytics and on-site AI-driven fatigue identification. This study accelerates the advancement of E-Skin through rapid self-healing capabilities.

AB - Emerging electronic skins (E-Skins) offer continuous, real-time electrophysiological monitoring. However, daily mechanical scratches compromise their functionality, underscoring urgent need for self-healing E-Skins resistant to mechanical damage. Current materials have slow recovery times, impeding reliable signal measurement. The inability to heal within 1 minute is a major barrier to commercialization. A composition achieving 80% recovery within 1 minute has not yet been reported. Here, we present a rapidly self-healing E-Skin tailored for real-time monitoring of physical and physiological bioinformation. The E-Skin recovers more than 80% of its functionality within 10 seconds after physical damage, without the need of external stimuli. It consistently maintains reliable biometric assessment, even in extreme environments such as underwater or at various temperatures. Demonstrating its potential for efficient health assessment, the E-Skin achieves an accuracy exceeding 95%, excelling in wearable muscle strength analytics and on-site AI-driven fatigue identification. This study accelerates the advancement of E-Skin through rapid self-healing capabilities.

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JO - Science advances

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Rapidly self-healing electronic skin for machine learning–assisted physiological and movement evaluation

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