Multi-Center Evaluation of Gel-Based and Dry Multipin EEG Caps

Author:

Ng Chuen RueORCID,Fiedler PatriqueORCID,Kuhlmann Levin,Liley David,Vasconcelos BeatrizORCID,Fonseca CarlosORCID,Tamburro GabriellaORCID,Comani SilviaORCID,Lui Troby Ka-Yan,Tse Chun-YuORCID,Warsito Indhika FauzhanORCID,Supriyanto Eko,Haueisen JensORCID

Abstract

Dry electrodes for electroencephalography (EEG) allow new fields of application, including telemedicine, mobile EEG, emergency EEG, and long-term repetitive measurements for research, neurofeedback, or brain–computer interfaces. Different dry electrode technologies have been proposed and validated in comparison to conventional gel-based electrodes. Most previous studies have been performed at a single center and by single operators. We conducted a multi-center and multi-operator study validating multipin dry electrodes to study the reproducibility and generalizability of their performance in different environments and for different operators. Moreover, we aimed to study the interrelation of operator experience, preparation time, and wearing comfort on the EEG signal quality. EEG acquisitions using dry and gel-based EEG caps were carried out in 6 different countries with 115 volunteers, recording electrode-skin impedances, resting state EEG and evoked activity. The dry cap showed average channel reliability of 81% but higher average impedances than the gel-based cap. However, the dry EEG caps required 62% less preparation time. No statistical differences were observed between the gel-based and dry EEG signal characteristics in all signal metrics. We conclude that the performance of the dry multipin electrodes is highly reproducible, whereas the primary influences on channel reliability and signal quality are operator skill and experience.

Funder

German Academic Exchange Service

European Union

Free State of Thuringia

Publisher

MDPI AG

Subject

Electrical and Electronic Engineering,Biochemistry,Instrumentation,Atomic and Molecular Physics, and Optics,Analytical Chemistry

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