Graphene E-tattoos for Unobstructive Ambulatory Electrodermal Activity Sensing on the Palm Enabled by Heterogeneous Serpentine Ribbons

Overview

Journal Nat Commun

Specialty Biology

Date 2022 Nov 4

PMID 36329038

Authors

Hongwoo Jang

Kaan Sel

Eunbin Kim

Sangjun Kim

Xiangxing Yang

Seungmin Kang

Kyoung-Ho Ha

Rebecca Wang

Yifan Rao

Roozbeh Jafari

Nanshu Lu

Affiliations

Soon will be listed here.

Abstract

Electrodermal activity (EDA) is a popular index of mental stress. State-of-the-art EDA sensors suffer from obstructiveness on the palm or low signal fidelity off the palm. Our previous invention of sub-micron-thin imperceptible graphene e-tattoos (GET) is ideal for unobstructive EDA sensing on the palm. However, robust electrical connection between ultrathin devices and rigid circuit boards is a long missing component for ambulatory use. To minimize the well-known strain concentration at their interfaces, we propose heterogeneous serpentine ribbons (HSPR), which refer to a GET serpentine partially overlapping with a gold serpentine without added adhesive. A fifty-fold strain reduction in HSPR vs. heterogeneous straight ribbons (HSTR) has been discovered and understood. The combination of HSPR and a soft interlayer between the GET and an EDA wristband enabled ambulatory EDA monitoring on the palm in free-living conditions. A newly developed EDA event selection policy leveraging unbiased selection of phasic events validated our GET EDA sensor against gold standards.

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