Adhesive Wearable Sensors for Electroencephalography from Hairy Scalp

Author:

Zhang Anan1,Shyam Abhijith Balamuraleekrishna1,Cunningham Alexandra McCalla2,Williams Christopher2,Brissenden Amanda2,Bartley Alex1,Amsden Brian2,Docoslis Aristides2,Kontopoulou Marianna2,Ameri Shideh Kabiri13ORCID

Affiliation:

1. Department of Electrical and Computer Engineering Queen's University Kingston Ontario K7L 3N6 Canada

2. Department of Chemical Engineering Queen's University Kingston Ontario K7L 3N6 Canada

3. Centre for Neuroscience Studies (CNS) Queen's University Kingston Ontario K7L 3N6 Canada

Abstract

AbstractElectroencephalography has garnered interest for applications in mobile healthcare, human–machine interfaces, and Internet of Things. Conventional electroencephalography relies on wet and dry electrodes. Despite favorable interface impedance of wet electrodes and skin, the application of a large amount of gel at their interface with skin limits the electroencephalography spatial resolution, increases the risk of shorting between electrodes, and makes them unsuited for long‐term mobile recording. In contrast, dry electrodes are better suited for long‐term recordings but susceptible to motion artifacts. In addition, both wet and dry electrodes are non‐adhesive to the hairy scalp and mechanical support, or chemical adhesives are used to hold them in place. Herein, a conical microstructure array (CMSA) based sensor made of carbon nanotube‐polydimethylsiloxane composite is reported. The CMSA sensor is fabricated using the innovative, cost‐effective, and scalable method of viscosity‐controlled dip‐pull process. The sensor adheres to the hairy scalp by generating negative pressure in its conical microstructures when it is pressed against scalp. Aided by the application of a trace amount of gel, CMSA sensor establishes good electrical contact with the skin, enabling its applications in mobile electroencephalography over extended periods. Notably, the signal quality of CMSA sensors is comparable to that of medical‐grade wet gel electrodes.

Publisher

Wiley

Subject

Pharmaceutical Science,Biomedical Engineering,Biomaterials

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