Electrochemiluminescent tactile visual synapse enabling in situ health monitoring

Woojoong Kim; Kyuho Lee; Sanghyeon Choi; Eunje Park; Gwanho Kim; Jebong Ha; Yeeun Kim; Jihye Jang; Ji Hye Oh; Ho Yeon Kim; Wei Jiang; Jioh Yoo; Taebin Kim; Yeonji Kim; Kwan Nyeong Kim; Juntaek Hong; Ali Javey; Dong Wook Rha; Tae Woo Lee; Keehoon Kang; Gunuk Wang; Cheolmin Park

doi:10.1038/s41563-025-02124-x

Electrochemiluminescent tactile visual synapse enabling in situ health monitoring

Woojoong Kim
, Kyuho Lee
, Sanghyeon Choi
, Eunje Park
, Gwanho Kim
, Jebong Ha
, Yeeun Kim
, Jihye Jang
, Ji Hye Oh
, Ho Yeon Kim
, Wei Jiang
, Jioh Yoo
, Taebin Kim
, Yeonji Kim
, Kwan Nyeong Kim
, Juntaek Hong
, Ali Javey
, Dong Wook Rha
, Tae Woo Lee
, Keehoon Kang

Gunuk Wang^*, Cheolmin Park^*

^*Corresponding author for this work

KU-KIST Graduate School of Converging Science and Technology

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

27 Citations (Scopus)

Abstract

Tactile visual synapses combine the functionality of tactile artificial synapses with the ability to visualize their activity in real time and provide a direct and intuitive visualization of the activity, offering an efficient route for in situ health monitoring. Herein we present a tactile visual synapse that enables in situ monitoring of finger rehabilitation and electrocardiogram analysis. Repetitive finger flexion and various arrhythmias are monitored and visually guided using the developed tactile visual synapse combined with an electrical and optical output feedback algorithm. The tactile visual synapse has the structure of an electrochemical transistor comprising an elastomeric top gate as a tactile receptor and an electrochemiluminescent ion gel as a light-emitting layer stacked on a polymeric semiconductor layer, forming an electrical synaptic channel between source and drain electrodes. The low-power (~34 μW) visualization of the tactile synaptic activity associated with the repetitive motions of fingers and heartbeats enables the development of a convenient and efficient personalized healthcare system.

Original language	English
Pages (from-to)	925-934
Number of pages	10
Journal	Nature Materials
Volume	24
Issue number	6
DOIs	https://doi.org/10.1038/s41563-025-02124-x
Publication status	Published - 2025 Jun

Bibliographical note

Publisher Copyright:
© The Author(s), under exclusive licence to Springer Nature Limited 2025.

ASJC Scopus subject areas

General Chemistry
General Materials Science
Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering

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Kim, W., Lee, K., Choi, S., Park, E., Kim, G., Ha, J., Kim, Y., Jang, J., Oh, J. H., Kim, H. Y., Jiang, W., Yoo, J., Kim, T., Kim, Y., Kim, K. N., Hong, J., Javey, A., Rha, D. W., Lee, T. W., ... Park, C. (2025). Electrochemiluminescent tactile visual synapse enabling in situ health monitoring. Nature Materials, 24(6), 925-934. https://doi.org/10.1038/s41563-025-02124-x

Kim, W, Lee, K, Choi, S, Park, E, Kim, G, Ha, J, Kim, Y, Jang, J, Oh, JH, Kim, HY, Jiang, W, Yoo, J, Kim, T, Kim, Y, Kim, KN, Hong, J, Javey, A, Rha, DW, Lee, TW, Kang, K, Wang, G & Park, C 2025, 'Electrochemiluminescent tactile visual synapse enabling in situ health monitoring', Nature Materials, vol. 24, no. 6, pp. 925-934. https://doi.org/10.1038/s41563-025-02124-x

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abstract = "Tactile visual synapses combine the functionality of tactile artificial synapses with the ability to visualize their activity in real time and provide a direct and intuitive visualization of the activity, offering an efficient route for in situ health monitoring. Herein we present a tactile visual synapse that enables in situ monitoring of finger rehabilitation and electrocardiogram analysis. Repetitive finger flexion and various arrhythmias are monitored and visually guided using the developed tactile visual synapse combined with an electrical and optical output feedback algorithm. The tactile visual synapse has the structure of an electrochemical transistor comprising an elastomeric top gate as a tactile receptor and an electrochemiluminescent ion gel as a light-emitting layer stacked on a polymeric semiconductor layer, forming an electrical synaptic channel between source and drain electrodes. The low-power (\textasciitilde{}34 μW) visualization of the tactile synaptic activity associated with the repetitive motions of fingers and heartbeats enables the development of a convenient and efficient personalized healthcare system.",

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Electrochemiluminescent tactile visual synapse enabling in situ health monitoring

Abstract

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ASJC Scopus subject areas

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