Wireless, skin-interfaced sensors for compression therapy

Yoonseok Park; Kyeongha Kwon; Sung Soo Kwak; Da Som Yang; Jean Won Kwak; Haiwen Luan; Ted S. Chung; Keum San Chun; Jong Uk Kim; Hokyung Jang; Hanjun Ryu; Hyoyong Jeong; Sang Min Won; Youn J. Kang; Michael Zhang; David Pontes; Brianna R. Kampmeier; Seon Hee Seo; Jeffrey Zhao; Inhwa Jung; Yonggang Huang; Shuai Xu; John A. Rogers

doi:10.1126/sciadv.abe1655

Wireless, skin-interfaced sensors for compression therapy

Yoonseok Park
, Kyeongha Kwon
, Sung Soo Kwak
, Da Som Yang
, Jean Won Kwak
, Haiwen Luan
, Ted S. Chung
, Keum San Chun
, Jong Uk Kim
, Hokyung Jang
, Hanjun Ryu
, Hyoyong Jeong
, Sang Min Won
, Youn J. Kang
, Michael Zhang
, David Pontes
, Brianna R. Kampmeier
, Seon Hee Seo
, Jeffrey Zhao
, Inhwa Jung

Yonggang Huang, Shuai Xu, John A. Rogers

Department of Electronic and Electrical Engineering

Northwestern University
Korea Advanced Institute of Science and Technology
Sungkyunkwan University
University of Texas at Austin
University of Wisconsin–Madison
Korea Electrotechnology Research Institute
Kyung Hee University

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

72 Scopus citations

Abstract

Therapeutic compression garments (TCGs) are key tools for the management of a wide range of vascular lower extremity conditions. Proper use of TCGs involves application of a minimum and consistent pressure across the lower extremities for extended periods of time. Slight changes in the characteristics of the fabric and the mechanical properties of the tissues lead to requirements for frequent measurements and corresponding adjustments of the applied pressure. Existing sensors are not sufficiently small, thin, or flexible for practical use in this context, and they also demand cumbersome, hard-wired interfaces for data acquisition. Here, we introduce a flexible, wireless monitoring system for tracking both temperature and pressure at the interface between the skin and the TCGs. Detailed studies of the materials and engineering aspects of these devices, together with clinical pilot trials on a range of patients with different pathologies, establish the technical foundations and measurement capabilities.

Original language	English
Article number	eabe1655
Journal	Science Advances
Volume	6
Issue number	49
DOIs	https://doi.org/10.1126/sciadv.abe1655
State	Published - 4 Dec 2020

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Park, Y., Kwon, K., Kwak, S. S., Yang, D. S., Kwak, J. W., Luan, H., Chung, T. S., Chun, K. S., Kim, J. U., Jang, H., Ryu, H., Jeong, H., Won, S. M., Kang, Y. J., Zhang, M., Pontes, D., Kampmeier, B. R., Seo, S. H., Zhao, J., ... Rogers, J. A. (2020). Wireless, skin-interfaced sensors for compression therapy. Science Advances, 6(49), Article eabe1655. https://doi.org/10.1126/sciadv.abe1655

@article{a550fbb238a14db8be2e7b6feb154e41,

title = "Wireless, skin-interfaced sensors for compression therapy",

abstract = "Therapeutic compression garments (TCGs) are key tools for the management of a wide range of vascular lower extremity conditions. Proper use of TCGs involves application of a minimum and consistent pressure across the lower extremities for extended periods of time. Slight changes in the characteristics of the fabric and the mechanical properties of the tissues lead to requirements for frequent measurements and corresponding adjustments of the applied pressure. Existing sensors are not sufficiently small, thin, or flexible for practical use in this context, and they also demand cumbersome, hard-wired interfaces for data acquisition. Here, we introduce a flexible, wireless monitoring system for tracking both temperature and pressure at the interface between the skin and the TCGs. Detailed studies of the materials and engineering aspects of these devices, together with clinical pilot trials on a range of patients with different pathologies, establish the technical foundations and measurement capabilities.",

author = "Yoonseok Park and Kyeongha Kwon and Kwak, \{Sung Soo\} and Yang, \{Da Som\} and Kwak, \{Jean Won\} and Haiwen Luan and Chung, \{Ted S.\} and Chun, \{Keum San\} and Kim, \{Jong Uk\} and Hokyung Jang and Hanjun Ryu and Hyoyong Jeong and Won, \{Sang Min\} and Kang, \{Youn J.\} and Michael Zhang and David Pontes and Kampmeier, \{Brianna R.\} and Seo, \{Seon Hee\} and Jeffrey Zhao and Inhwa Jung and Yonggang Huang and Shuai Xu and Rogers, \{John A.\}",

note = "Publisher Copyright: Copyright {\textcopyright} 2020 The Authors, some rights reserved;",

year = "2020",

month = dec,

day = "4",

doi = "10.1126/sciadv.abe1655",

language = "English",

volume = "6",

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Park, Y, Kwon, K, Kwak, SS, Yang, DS, Kwak, JW, Luan, H, Chung, TS, Chun, KS, Kim, JU, Jang, H, Ryu, H, Jeong, H, Won, SM, Kang, YJ, Zhang, M, Pontes, D, Kampmeier, BR, Seo, SH, Zhao, J, Jung, I, Huang, Y, Xu, S & Rogers, JA 2020, 'Wireless, skin-interfaced sensors for compression therapy', Science Advances, vol. 6, no. 49, eabe1655. https://doi.org/10.1126/sciadv.abe1655

TY - JOUR

T1 - Wireless, skin-interfaced sensors for compression therapy

AU - Park, Yoonseok

AU - Kwon, Kyeongha

AU - Kwak, Sung Soo

AU - Yang, Da Som

AU - Kwak, Jean Won

AU - Luan, Haiwen

AU - Chung, Ted S.

AU - Chun, Keum San

AU - Kim, Jong Uk

AU - Jang, Hokyung

AU - Ryu, Hanjun

AU - Jeong, Hyoyong

AU - Won, Sang Min

AU - Kang, Youn J.

AU - Zhang, Michael

AU - Pontes, David

AU - Kampmeier, Brianna R.

AU - Seo, Seon Hee

AU - Zhao, Jeffrey

AU - Jung, Inhwa

AU - Huang, Yonggang

AU - Xu, Shuai

AU - Rogers, John A.

PY - 2020/12/4

Y1 - 2020/12/4

N2 - Therapeutic compression garments (TCGs) are key tools for the management of a wide range of vascular lower extremity conditions. Proper use of TCGs involves application of a minimum and consistent pressure across the lower extremities for extended periods of time. Slight changes in the characteristics of the fabric and the mechanical properties of the tissues lead to requirements for frequent measurements and corresponding adjustments of the applied pressure. Existing sensors are not sufficiently small, thin, or flexible for practical use in this context, and they also demand cumbersome, hard-wired interfaces for data acquisition. Here, we introduce a flexible, wireless monitoring system for tracking both temperature and pressure at the interface between the skin and the TCGs. Detailed studies of the materials and engineering aspects of these devices, together with clinical pilot trials on a range of patients with different pathologies, establish the technical foundations and measurement capabilities.

AB - Therapeutic compression garments (TCGs) are key tools for the management of a wide range of vascular lower extremity conditions. Proper use of TCGs involves application of a minimum and consistent pressure across the lower extremities for extended periods of time. Slight changes in the characteristics of the fabric and the mechanical properties of the tissues lead to requirements for frequent measurements and corresponding adjustments of the applied pressure. Existing sensors are not sufficiently small, thin, or flexible for practical use in this context, and they also demand cumbersome, hard-wired interfaces for data acquisition. Here, we introduce a flexible, wireless monitoring system for tracking both temperature and pressure at the interface between the skin and the TCGs. Detailed studies of the materials and engineering aspects of these devices, together with clinical pilot trials on a range of patients with different pathologies, establish the technical foundations and measurement capabilities.

UR - https://www.scopus.com/pages/publications/85097310456

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SN - 2375-2548

VL - 6

JO - Science Advances

JF - Science Advances

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M1 - eabe1655

ER -

Wireless, skin-interfaced sensors for compression therapy

Abstract

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