Optimizing Motor Intention Detection with Deep Learning: Towards Management of Intraoperative Awareness

Oleksii Avilov; Sébastien Rimbert; Anton Popov; Laurent Bougrain

doi:10.1109/TBME.2021.3064794

Journal articles

Optimizing Motor Intention Detection with Deep Learning: Towards Management of Intraoperative Awareness

Oleksii Avilov ^{1, 2} Sébastien Rimbert ² Anton Popov ¹ Laurent Bougrain ²

1 National Technical University of Ukraine "Kyiv Polytechnic Institute" [Kiev]

2 NEUROSYS - Analysis and modeling of neural systems by a system neuroscience approach

Inria Nancy - Grand Est, LORIA - AIS - Department of Complex Systems, Artificial Intelligence & Robotics

Abstract : Objective: This article shows the interest in deep learning techniques to detect motor imagery (MI) from raw electroencephalographic (EEG) signals when a functional electrical stimulation is added or not. Impacts of electrode montages and bandwidth are also reported. The perspective of this work is to improve the detection of intraoperative awareness during general anesthesia. Methods: Various architectures of EEGNet were investigated to optimize MI detection. They have been compared to the state-of-the-art classifiers in Brain-Computer Interfaces (based on Riemannian geometry, linear discriminant analysis), and other deep learning architectures (deep convolution network, shallow convolutional network). EEG data were measured from 22 participants performing motor imagery with and without median nerve stimulation. Results: The proposed architecture of EEGNet reaches the best classification accuracy (83.2%) and false-positive rate (FPR 19.0%) for a setup with only six electrodes over the motor cortex and frontal lobe and for an extended 4-38 Hz EEG frequency range while the subject is being stimulated via a median nerve. Configurations with a larger number of electrodes result in higher accuracy (94.5%) and FPR (6.1%) for 128 electrodes (and respectively 88.0% and 12.9% for 13 electrodes). Conclusion: The present work demonstrates that using an extended EEG frequency band and a modified EEGNet deep neural network increases the accuracy of MI detection when used with as few as 6 electrodes which include frontal channels. Significance: The proposed method contributes to the development of Brain-Computer Interface systems based on MI detection from EEG.

Keywords : Brain-computer interface (BCI) deep learning electroencephalogram (EEG) intraoperative awareness during general anesthesia machine learning median nerve stimulation motor imagery AAGA: accidental awareness during general anesthesia

Document type :

Journal articles

Domain :

Computer Science [cs] / Neural and Evolutionary Computing [cs.NE]

Computer Science [cs] / Machine Learning [cs.LG]

Engineering Sciences [physics] / Signal and Image processing

Computer Science [cs] / Medical Imaging

Cognitive science / Neuroscience

Complete list of metadata

https://hal.inria.fr/hal-03166495
Contributor : Laurent Bougrain Connect in order to contact the contributor
Submitted on : Thursday, March 11, 2021 - 12:11:20 PM
Last modification on : Friday, April 1, 2022 - 3:43:14 AM
Long-term archiving on: : Saturday, June 12, 2021 - 6:36:33 PM

Optimizing Motor Intention Detection with Deep Learning: Towards Management of Intraoperative Awareness

File

Identifiers

Collections

Citation

Export

Metrics

123

458

Contact Legal Notice Personal Data

Optimizing Motor Intention Detection with Deep Learning: Towards Management of Intraoperative Awareness

File

Identifiers

Collections

Citation

Export

Share

Metrics

123

458

Contact Legal Notice Personal Data