Design of an Injectable, Self-adhesive, and Highly Stable Hydrogel Electrode for Sleep Recording

Overview

Journal Device

Date 2024 Sep 6

PMID 39239460

Authors

Ju-Chun Hsieh

Weilong He

Dhivya Venkatraghavan

Victoria B Koptelova

Zoya J Ahmad

Ilya Pyatnitskiy

Wenliang Wang

Jinmo Jeong

Kevin Kai Wing Tang

Cody Harmeier

Conrad Li

Manini Rana

Sruti Iyer

Eesha Nayak

Hong Ding

Pradeep Modur

Vincent Mysliwiec

David M Schnyer

Benjamin Baird

Huiliang Wang

Affiliations

Soon will be listed here.

Abstract

High-quality and continuous electroencephalogram (EEG) monitoring is desirable for sleep research, sleep monitoring, and the evaluation and treatment of sleep disorders. Existing continuous EEG monitoring technologies suffer from fragile connections, long-term stability, and complex preparation for electrodes under real-life conditions. Here, we report an injectable and spontaneously cross-linked hydrogel electrode for long-term EEG applications. Specifically, our electrodes have a long-term low impedance on hairy scalp regions of 17.53 kΩ for more than 8 h of recording, high adhesiveness on the skin of 0.92 N cm with repeated attachment capability, and long-term wearability during daily activities and overnight sleep. In addition, our electrodes demonstrate a superior signal-to-noise-ratio of 23.97 decibels (dB) in comparison with commercial wet electrodes of 17.98 dB and share a high agreement of sleep stage classification with commercial wet electrodes during multichannel recording. These results exhibit the potential of our on-site-formed electrodes for high-quality, prolonged EEG monitoring in various scenarios.

Citing Articles

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