Spectral Representation of EEG Data using Learned Graphs with Application to Motor Imagery Decoding

Miri, Maliheh; Abootalebi, Vahid; Saeedi-Sourck, Hamid; Behjat, Hamid

doi:10.1101/2022.08.13.503836

Cited by 3 publications

(8 citation statements)

References 113 publications

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“…That is, functional patterns are smooth relative to the underlying fiber architecture and tissue profile morphologies. This observation is, on the one hand, consistent with the energy profile of fMRI graph signals on voxel-wise gray matter graphs (Behjat et al, 2015, as well as region-wise brain graphs (Atasoy et al, 2017;Preti and Van De Ville, 2019;Glomb et al, 2020;Miri et al, 2022), which is reminiscent of a power-law behavior, and on the other hand, can be linked to the decreasing trend observed in the Procrustes validation errors (see Fig. 3(D)), where increasing K-values reduce the error close to that of a randomly generated graph.…”

Section: Discussionsupporting

confidence: 83%

“…GSP has found numerous applications across multiple domains—see e.g. (Ortega et al, 2018) for a recent review, and in particular within neuroimaging, examples include: brain state decoding (Petrantonakis and Kompatsiaris, 2018; Ghoroghchian et al, 2020; Georgiadis et al, 2021; Cattai et al, 2021; Miri et al, 2022), brain signal denoising (Einizade and Sardouie, 2022), brain activation mapping (Behjat et al, 2015; Abramian et al, 2021) and source localization (Hyde et al, 2019), diagnosing neuropathology (Itani and Thanou, 2021; Jafadideh and Asl, 2022), tracking fast spatiotemporal cortical dynamics (Glomb et al, 2020; Rué-Queralt et al, 2021), brain fingerprinting and task decoding (Griffa et al, 2022), identifying dynamically evolving populations of neurons (Charles et al, 2022), deciphering signatures of attention switching (Medaglia et al, 2018; Huang et al, 2018), manifesting white matter pathways that mediate cortical activity (Tarun et al, 2020), and elucidating perturbations of consciousness induced by brain injury or drugs (Atasoy et al, 2017; Luppi et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

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Voxel-Wise Brain Graphs from Diffusion MRI: Intrinsic Eigenspace Dimensionality and Application to Functional MRI

Behjat

Tarun

Abramian

et al. 2022

Preprint

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Structural brain graphs are conventionally limited to defining nodes as gray matter regions from an atlas, with edges reflecting the density of axonal projections between pairs of nodes. Here we explicitly model the entire set of voxels within a brain mask as nodes of high-resolution, subject-specific graphs. We define the strength of local voxel-to-voxel connections using diffusion tensors and orientation distribution functions derived from diffusion-weighted MRI data. We study the graphs' Laplacian spectral properties on data from the Human Connectome Project. We then assess the extent of inter-subject variability of the Laplacian eigenmodes via a procrustes validation scheme. Finally, we demonstrate the extent to which functional MRI data are shaped by the underlying anatomical structure via graph signal processing. The graph Laplacian eigenmodes manifest highly resolved spatial profiles, reflecting distributed patterns that correspond to major white matter pathways. We show that the intrinsic dimensionality of the eigenspace of such high-resolution graphs is only a mere fraction of the graph dimensions. By projecting task and resting-state data on low-frequency graph Laplacian eigenmodes, we show, firstly, that brain activity can be well approximated by a small subset of low-frequency components, and secondly, that spectral graph energy profiles differ under different functional loads. The proposed graphs open new avenues in studying the brain, be it, by exploring their organisational properties via graph or spectral graph theory, or by treating them as the scaffold on which brain function is observed at the individual level.

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Section: Discussionsupporting

confidence: 83%

Section: Introductionmentioning

confidence: 99%

Voxel-Wise Brain Graphs from Diffusion MRI: Intrinsic Eigenspace Dimensionality and Application to Functional MRI

Behjat

Tarun

Abramian

et al. 2022

Preprint

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“…replacing the ℓ 2 -norm with a logarithmic barrier, the optimization in (2) can be solved more efficiently via a more general-purpose formulation with respect to the graph’s adjacency matrix [11]: where Z is an N × N matrix with elements Z i,j = ∥ F i ,: − F j ,: ∥ 2 , i.e., Euclidean distance between signal values on electrodes i and j . The first term in (3) enforces the smoothness constraint in similar way as in the first term in (2), which is based on the equivalence trace( F T LF ) = 0.5 ∥ A ◦ Z ∥ 1 , where ◦ is the Hadamard product [19]. Intuitively, if smooth graph signals reside on well-connected vertices, it is expected that these vertices have smaller distances Z i,j .…”

Section: Methodsmentioning

confidence: 99%

“…where • is the Hadamard product [19]. Intuitively, if smooth graph signals reside on well-connected vertices, it is expected that these vertices have smaller distances Z i,j .…”

Section: A Graph Learning Via Enforcing Graph Signal Smoothnessmentioning

confidence: 99%

“…A closely related method has already shown promising results on fMRI data [8]. Here we focus on EEG data, leveraging our recently proposed method for inferring brain graphs from EEG data [19]. This method results in a graph that captures subtle spatial relations between EEG electrodes, in particular, their instantaneous spatial profiles, such that EEG maps can be seen as smooth functions on the resulting graphs.…”

Section: Introductionmentioning

confidence: 99%

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Brain fingerprinting using EEG graph inference

Miri

Abootalebi

Amico

et al. 2023

Preprint

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Taking advantage of the human brain functional connectome as an individual's fingerprint has attracted great research in recent years. Conventionally, Pearson correlation between regional time-courses is used as a pairwise measure for each edge weight of the connectome. Building upon recent advances in graph signal processing, we propose here to estimate the graph structure as a whole by considering all time-courses at once. Using data from two publicly available datasets, we show the superior performance of such learned brain graphs over correlation-based functional connectomes in characterizing an individual.

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Joint subject-identification and task-decoding from inferred functional brain graphs via a multi-task neural network

Balcioglu,

Döner,

Sareen

et al. 2023

Preprint

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Functional connectivity (FC) between brain regions as manifested via fMRI entails signatures that can be used to identify individuals and decode cognitive tasks. In this work, we use methods from graph structure inference to estimate FC, which is in contrast to the conventional approach of deriving FC via correlation. Furthermore, instead of working on raw (temporal) fMRI data, we infer FC graphs from seed-based co-activation patterns. We also propose a multi-task neural network architecture to jointly perform subject-identification and task-decoding from inferred functional brain graphs. We validate the the developed model on data from 100 subjects from the Human Connectome Project across eight fMRI tasks. Most importantly, our results show the superior task-decoding performance of FC graphs inferred from seed-based activity maps over graphs inferred from raw fMRI data. Furthermore, via gradient-based back-projection, we derive a significance score for inputs to the neural network, and present results showing the differential role of brain connections in subject-identification and task-decoding.

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Spectral Representation of EEG Data using Learned Graphs with Application to Motor Imagery Decoding

Cited by 3 publications

References 113 publications

Voxel-Wise Brain Graphs from Diffusion MRI: Intrinsic Eigenspace Dimensionality and Application to Functional MRI

Voxel-Wise Brain Graphs from Diffusion MRI: Intrinsic Eigenspace Dimensionality and Application to Functional MRI

Brain fingerprinting using EEG graph inference

Joint subject-identification and task-decoding from inferred functional brain graphs via a multi-task neural network

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