Scalp electrode impedance, infection risk, and EEG data quality
Objectives: Breaking the skin when applying scalp electroencephalographic (EEG)
electrodes creates the risk of infection from blood-born pathogens such as HIV, Hepatitis-C,
and Creutzfeldt–Jacob Disease. Modern engineering principles suggest that excellent EEG
signals can be collected with high scalp impedance (≈ 40 kΩ) without scalp abrasion. The
present study was designed to evaluate the effect of electrode-scalp impedance on EEG
data quality. Methods: The first section of the paper reviews electrophysiological recording …
electrodes creates the risk of infection from blood-born pathogens such as HIV, Hepatitis-C,
and Creutzfeldt–Jacob Disease. Modern engineering principles suggest that excellent EEG
signals can be collected with high scalp impedance (≈ 40 kΩ) without scalp abrasion. The
present study was designed to evaluate the effect of electrode-scalp impedance on EEG
data quality. Methods: The first section of the paper reviews electrophysiological recording …
Objectives
Breaking the skin when applying scalp electroencephalographic (EEG) electrodes creates the risk of infection from blood-born pathogens such as HIV, Hepatitis-C, and Creutzfeldt–Jacob Disease. Modern engineering principles suggest that excellent EEG signals can be collected with high scalp impedance (≈40 kΩ) without scalp abrasion. The present study was designed to evaluate the effect of electrode-scalp impedance on EEG data quality.
Methods
The first section of the paper reviews electrophysiological recording with modern high input-impedance differential amplifiers and subject isolation, and explains how scalp-electrode impedance influences EEG signal amplitude and power line noise. The second section of the paper presents an experimental study of EEG data quality as a function of scalp-electrode impedance for the standard frequency bands in EEG and event-related potential (ERP) recordings and for 60 Hz noise.
Results
There was no significant amplitude change in any EEG frequency bands as scalp-electrode impedance increased from less than 10 kΩ (abraded skin) to 40 kΩ (intact skin). 60 Hz was nearly independent of impedance mismatch, suggesting that capacitively coupled noise appearing differentially across mismatched electrode impedances did not contribute substantially to the observed 60 Hz noise levels.
Conclusions
With modern high input-impedance amplifiers and accurate digital filters for power line noise, high-quality EEG can be recorded without skin abrasion.
Elsevier
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