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AuthorMahmud, Sakib
AuthorChowdhury, Muhammad E.H.
AuthorKiranyaz, Serkan
AuthorAl Emadi, Nasser
AuthorTahir, Anas M.
AuthorHossain, Md Shafayet
AuthorKhandakar, Amith
AuthorAl-Maadeed, Somaya
Available date2024-08-12T08:26:57Z
Publication Date2024
Publication NameEngineering Applications of Artificial Intelligence
ResourceScopus
ISSN9521976
URIhttp://dx.doi.org/10.1016/j.engappai.2023.107514
URIhttp://hdl.handle.net/10576/57606
AbstractElectroencephalogram (EEG) signals suffer substantially from motion artifacts even in ambulatory settings. Signal processing techniques for removing motion artifacts from EEG signals have limitations, and the potential of classical or deep machine-learning algorithms for this task remains largely unexplored. We propose Attention-Guided Operational CycleGAN (AGO-CycleGAN), a novel CycleGAN-based framework to remove motion artifacts and enhance the quality of corrupted EEG signals. It incorporates self-generative operational neurons and an attention-guided Feature Pyramid Network with modified bottlenecks as generators and PatchGAN-based discriminators. AGO-CycleGAN was trained and tested on a single-channel EEG dataset from 23 subjects, using a subject-independent Jackknife cross-validation approach. It outperformed other methods and was evaluated through qualitative and quantitative analysis, employing robust metrics in both temporal and frequency domains. The results indicate its effectiveness in restoring EEG signals affected by severe motion artifacts. AGO-CycleGAN achieves state-of-the-art EEG restoration performance in the temporal domain, gaining improvements in signal-to-noise ratio (ΔSNR) and temporal correlation (ηtemp) by 26.497 dB and 87.2%, respectively. It also showed excellent performance in preserving the spectral EEG components (delta, theta, alpha, beta, and gamma), evaluated through band power ratio before and after restoration. Spectral correlation (ηspec) improved by 93.5% after cleaning the motion artifacts. Qualitative evaluations showed excellently reconstructed clean EEG waveforms upon restoration. Spectral restoration visualized through Power Spectral Density (PSD) plots and per-band topographic maps showed a uniform removal of high-power motion artifact components throughout the spectrum. AGO-CycleGAN significantly outperformed existing techniques in EEG artifact removal and can be extended to multi-channel EEG systems.
SponsorThis work was made possible by NPRP12S-0227-190164 from the Qatar National Research Fund, a member of Qatar Foundation , a member of Qatar Foundation, Doha, Qatar , and International Research Collaboration Co-Fund (IRCC) grant: IRCC-2021-001 . The statements made herein are solely the responsibility of the authors.
Languageen
PublisherElsevier
Subject1D signal restoration
Attention guided operational CycleGAN (AGO-CycleGAN)
Cycle generative adversarial networks (CycleGANs)
Electroencephalography (EEG)
Motion artifact correction
TitleRestoration of motion-corrupted EEG signals using attention-guided operational CycleGAN
TypeArticle
Volume Number128
dc.accessType Full Text


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