Investigating Brain Connectivity with Graph Neural Networks and
GNNExplainer
- URL: http://arxiv.org/abs/2206.01930v1
- Date: Sat, 4 Jun 2022 07:47:13 GMT
- Title: Investigating Brain Connectivity with Graph Neural Networks and
GNNExplainer
- Authors: Maksim Zhdanov, Saskia Steinmann and Nico Hoffmann
- Abstract summary: We have made a step toward an in-depth examination of functional connectivity during a dichotic listening task via deep learning.
We propose a graph neural network-based framework within which we represent EEG data as signals in the graph domain.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Functional connectivity plays an essential role in modern neuroscience. The
modality sheds light on the brain's functional and structural aspects,
including mechanisms behind multiple pathologies. One such pathology is
schizophrenia which is often followed by auditory verbal hallucinations. The
latter is commonly studied by observing functional connectivity during speech
processing. In this work, we have made a step toward an in-depth examination of
functional connectivity during a dichotic listening task via deep learning for
three groups of people: schizophrenia patients with and without auditory verbal
hallucinations and healthy controls. We propose a graph neural network-based
framework within which we represent EEG data as signals in the graph domain.
The framework allows one to 1) predict a brain mental disorder based on EEG
recording, 2) differentiate the listening state from the resting state for each
group and 3) recognize characteristic task-depending connectivity. Experimental
results show that the proposed model can differentiate between the above groups
with state-of-the-art performance. Besides, it provides a researcher with
meaningful information regarding each group's functional connectivity, which we
validated on the current domain knowledge.
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