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Multimodal Autoencoder Predicts fNIRS Resting State From EEG Signals

Parikshat Sirpal, Rafat Damseh, Ke Peng, Dang Khoa Nguyen, Frédéric Lesage

2021Neuroinformatics34 citationsDOIOpen Access PDF

Abstract

In this work, we introduce a deep learning architecture for evaluation on multimodal electroencephalographic (EEG) and functional near-infrared spectroscopy (fNIRS) recordings from 40 epileptic patients. Long short-term memory units and convolutional neural networks are integrated within a multimodal sequence-to-sequence autoencoder. The trained neural network predicts fNIRS signals from EEG, sans a priori, by hierarchically extracting deep features from EEG full spectra and specific EEG frequency bands. Results show that higher frequency EEG ranges are predictive of fNIRS signals with the gamma band inputs dominating fNIRS prediction as compared to other frequency envelopes. Seed based functional connectivity validates similar patterns between experimental fNIRS and our model's fNIRS reconstructions. This is the first study that shows it is possible to predict brain hemodynamics (fNIRS) from encoded neural data (EEG) in the resting human epileptic brain based on power spectrum amplitude modulation of frequency oscillations in the context of specific hypotheses about how EEG frequency bands decode fNIRS signals.

Topics & Concepts

ElectroencephalographyAutoencoderArtificial intelligenceComputer sciencePattern recognition (psychology)Functional near-infrared spectroscopyContext (archaeology)Speech recognitionEEG-fMRIBrain activity and meditationArtificial neural networkNeurosciencePsychologyPrefrontal cortexCognitionPaleontologyBiologyEEG and Brain-Computer InterfacesFunctional Brain Connectivity StudiesOptical Imaging and Spectroscopy Techniques
Multimodal Autoencoder Predicts fNIRS Resting State From EEG Signals | Litcius