Mapping of Spatiotemporal Auricular Electrophysiological Signals Reveals Human Biometric Clusters

Qingyun Huang; Cong Wu; Senlin Hou; Kuanming Yao; Hui Sun; Yufan Wang; Yikai Chen; Junhui Law; Mingxiao Yang; Ho-yin Chan; Vellaisamy A. L. Roy; Yuliang Zhao; Dong Wang; Enming Song; Xinge Yu; Lixing Lao; Yu Sun; Wen Jung Li

doi:10.1002/adhm.202201404

Mapping of Spatiotemporal Auricular Electrophysiological Signals Reveals Human Biometric Clusters

Qingyun Huang
, Cong Wu
, Senlin Hou
, Kuanming Yao
, Hui Sun
, Yufan Wang
, Yikai Chen
, Junhui Law
, Mingxiao Yang
, Ho-yin Chan^*
, Vellaisamy A. L. Roy
, Yuliang Zhao
, Dong Wang
, Enming Song
, Xinge Yu
, Lixing Lao
, Yu Sun
, Wen Jung Li^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

3 Citations (Scopus)

82 Downloads (CityUHK Scholars)

Abstract

Underneath the ear skin there are rich vascular network and sensory nerve branches. Hence, the 3D mapping of auricular electrophysiological signals can provide new biomedical perspectives. However, it is still extremely challenging for current sensing techniques to cover the entire ultra-curved auricle. Here, a 3D graphene-based ear-conformable sensing device with embedded and distributed 3D electrodes for full-auricle physiological monitoring is reported. As a proof-of-concept, spatiotemporal auricular electrical skin resistance (AESR) mapping is demonstrated for the first time, and human subject-specific AESR distributions are observed. From the data of more than 30 ears (both right and left ears), the auricular region-specific AESR changes after cycling exercise are observed in 98% of the tests and are clustered into four groups via machine learning-based data analyses. Correlations of AESR with heart rate and blood pressure are also studied. This 3D electronic platform and AESR-based biometrical findings show promising biomedical applications.

Original language	English
Article number	2201404
Journal	Advanced Healthcare Materials
Volume	11
Issue number	23
Online published	11 Oct 2022
DOIs	https://doi.org/10.1002/adhm.202201404
Publication status	Published - 7 Dec 2022

Funding

The authors thank Mr. M. Chen and Mr. Y. Lu for providing electrical circuit design advice, and Mr. L. Gao and Ms. X. Ren for their assistance with human experiments. This work was supported by the Hong Kong Research Grants Council's Joint Laboratory Funding Scheme (Grants No. JLFS/E-104/18), the Hong Kong Research Grants Council's General Research Fund (Grant No. 11204918), the University of Hong Kong Seed Fund for Translational and Applied Research (Grant No. 201711160034), the Hong Kong Centre for Cerebro-cardiovascular Health Engineering (COCHE), Lingang Laboratory (Grant No. LG-QS-202202-02), the Shanghai Municipal Science and Technology Major Project (Grant No. 2018SHZDZX01), ZJ Lab, and Shanghai Center for Brain Science and Brain-Inspired Technology.

Research Keywords

full-auricle electrophysiological monitoring
graphene-based 3D electrodes
human biometric clusters
machine learning
personalized healthcare sensors

Publisher's Copyright Statement

This full text is made available under CC-BY 4.0. https://creativecommons.org/licenses/by/4.0/

RGC Funding Information

RGC-funded

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10.1002/adhm.202201404

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Huang, Q., Wu, C., Hou, S., Yao, K., Sun, H., Wang, Y., Chen, Y., Law, J., Yang, M., Chan, H., Roy, V. A. L., Zhao, Y., Wang, D., Song, E., Yu, X., Lao, L., Sun, Y., & Li, W. J. (2022). Mapping of Spatiotemporal Auricular Electrophysiological Signals Reveals Human Biometric Clusters. Advanced Healthcare Materials, 11(23), Article 2201404. https://doi.org/10.1002/adhm.202201404

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title = "Mapping of Spatiotemporal Auricular Electrophysiological Signals Reveals Human Biometric Clusters",

abstract = "Underneath the ear skin there are rich vascular network and sensory nerve branches. Hence, the 3D mapping of auricular electrophysiological signals can provide new biomedical perspectives. However, it is still extremely challenging for current sensing techniques to cover the entire ultra-curved auricle. Here, a 3D graphene-based ear-conformable sensing device with embedded and distributed 3D electrodes for full-auricle physiological monitoring is reported. As a proof-of-concept, spatiotemporal auricular electrical skin resistance (AESR) mapping is demonstrated for the first time, and human subject-specific AESR distributions are observed. From the data of more than 30 ears (both right and left ears), the auricular region-specific AESR changes after cycling exercise are observed in 98\% of the tests and are clustered into four groups via machine learning-based data analyses. Correlations of AESR with heart rate and blood pressure are also studied. This 3D electronic platform and AESR-based biometrical findings show promising biomedical applications.",

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author = "Qingyun Huang and Cong Wu and Senlin Hou and Kuanming Yao and Hui Sun and Yufan Wang and Yikai Chen and Junhui Law and Mingxiao Yang and Ho-yin Chan and Roy, \{Vellaisamy A. L.\} and Yuliang Zhao and Dong Wang and Enming Song and Xinge Yu and Lixing Lao and Yu Sun and Li, \{Wen Jung\}",

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AU - Huang, Qingyun

AU - Wu, Cong

AU - Hou, Senlin

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AU - Sun, Hui

AU - Wang, Yufan

AU - Chen, Yikai

AU - Law, Junhui

AU - Yang, Mingxiao

AU - Chan, Ho-yin

AU - Roy, Vellaisamy A. L.

AU - Zhao, Yuliang

AU - Wang, Dong

AU - Song, Enming

AU - Yu, Xinge

AU - Lao, Lixing

AU - Sun, Yu

AU - Li, Wen Jung

PY - 2022/12/7

Y1 - 2022/12/7

N2 - Underneath the ear skin there are rich vascular network and sensory nerve branches. Hence, the 3D mapping of auricular electrophysiological signals can provide new biomedical perspectives. However, it is still extremely challenging for current sensing techniques to cover the entire ultra-curved auricle. Here, a 3D graphene-based ear-conformable sensing device with embedded and distributed 3D electrodes for full-auricle physiological monitoring is reported. As a proof-of-concept, spatiotemporal auricular electrical skin resistance (AESR) mapping is demonstrated for the first time, and human subject-specific AESR distributions are observed. From the data of more than 30 ears (both right and left ears), the auricular region-specific AESR changes after cycling exercise are observed in 98% of the tests and are clustered into four groups via machine learning-based data analyses. Correlations of AESR with heart rate and blood pressure are also studied. This 3D electronic platform and AESR-based biometrical findings show promising biomedical applications.

AB - Underneath the ear skin there are rich vascular network and sensory nerve branches. Hence, the 3D mapping of auricular electrophysiological signals can provide new biomedical perspectives. However, it is still extremely challenging for current sensing techniques to cover the entire ultra-curved auricle. Here, a 3D graphene-based ear-conformable sensing device with embedded and distributed 3D electrodes for full-auricle physiological monitoring is reported. As a proof-of-concept, spatiotemporal auricular electrical skin resistance (AESR) mapping is demonstrated for the first time, and human subject-specific AESR distributions are observed. From the data of more than 30 ears (both right and left ears), the auricular region-specific AESR changes after cycling exercise are observed in 98% of the tests and are clustered into four groups via machine learning-based data analyses. Correlations of AESR with heart rate and blood pressure are also studied. This 3D electronic platform and AESR-based biometrical findings show promising biomedical applications.

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Mapping of Spatiotemporal Auricular Electrophysiological Signals Reveals Human Biometric Clusters

Abstract

Funding

Research Keywords

Publisher's Copyright Statement

RGC Funding Information

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JLFS: Development of 3D Integrated Robotics and Sensing Structures using Multi-layered Nano-ink Circuit Deposition

GRF: Atomization of Viscous Fluids for Digital Scent Technology Using An Integrated Micro-droplet Generation Platform

Cite this

Mapping of Spatiotemporal Auricular Electrophysiological Signals Reveals Human Biometric Clusters

Abstract

Funding

Research Keywords

Publisher's Copyright Statement

RGC Funding Information

Access Output

Other Access Options

Permanent Link

Other Files and Links

Fingerprint

Projects

JLFS: Development of 3D Integrated Robotics and Sensing Structures using Multi-layered Nano-ink Circuit Deposition

GRF: Atomization of Viscous Fluids for Digital Scent Technology Using An Integrated Micro-droplet Generation Platform

Cite this