Adaptive Single-Channel EEG Artifact Removal With Applications to Clinical Monitoring

Electroencephalography (EEG) has become very common in clinical practice due to its relatively low cost, ease of installation, non-invasiveness, and good temporal resolution. Portable EEG devices are increasingly popular in clinical monitoring applications such as sleep scoring or anesthesia monitor...

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Bibliographic Details
Published in:IEEE transactions on neural systems and rehabilitation engineering 2022, Vol.30, p.286-295
Main Authors: Dora, Matteo, Holcman, David
Format: Article
Language:English
Subjects:
Algorithms
Anesthesia
artifact removal
Computer applications
Computing costs
Contamination
Discrete wavelet transforms
EEG
Electrodes
Electroencephalography
Electroencephalography (EEG)
Electroencephalography - methods
Humans
Inspection
Licenses
Monitoring
Noise levels
Portable equipment
quantile normalization
Reactive power
Real time
Signal Processing, Computer-Assisted
Temporal resolution
Visual signals
Wavelet Analysis
wavelet transform
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Summary:Electroencephalography (EEG) has become very common in clinical practice due to its relatively low cost, ease of installation, non-invasiveness, and good temporal resolution. Portable EEG devices are increasingly popular in clinical monitoring applications such as sleep scoring or anesthesia monitoring. In these situations, for reasons of speed and simplicity only few electrodes are used and contamination of the EEG signal by artifacts is inevitable. Visual inspection and manual removal of artifacts is often not possible, especially in real-time applications. Our goal is to develop a flexible technique to remove EEG artifacts in these contexts with minimal supervision. We propose here a new wavelet-based method which allows to remove artifacts from single-channel EEGs. The method is based on a data-driven renormalization of the wavelet components and is capable of adaptively attenuate artifacts of different nature. We benchmark our method against alternative artifact removal techniques. We assessed the performance of the proposed method on publicly available datasets comprising ocular, muscular, and movement artifacts. The proposed method shows superior performances on different kinds of artifacts and signal-to-noise levels. Finally, we present an application of our method to the monitoring of general anesthesia. We show that our method can successfully attenuate various types of artifacts in single-channel EEG. Thanks to its data-driven approach and low computational cost, the proposed method provides a valuable tool to remove artifacts in real-time EEG applications with few electrodes, such as monitoring in special care units.
ISSN:1534-4320
1558-0210
DOI:10.1109/TNSRE.2022.3147072