Deep Learning‐based Classification of Resting‐state fMRI Independent‐component Analysis

Victor Nozais, Philippe Boutinaud, Violaine Verrecchia, Marie-Fateye Gueye, Pierre-Yves Hervé, Christophe Tzourio, Bernard Mazoyer, Marc Joliot
Neuroinform. 2021-02-05; :
DOI: 10.1007/s12021-021-09514-x

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Nozais V(1)(2)(3)(4), Boutinaud P(1)(5), Verrecchia V(1)(2)(3)(4), Gueye MF(1)(2)(3)(4), Hervé PY(1)(5), Tzourio C(6)(7), Mazoyer B(1)(2)(3)(4)(7), Joliot M(8)(9)(10)(11).

Author information:
(1)Ginesislab, Bordeaux, France.
(2)GIN, UMR5293, Bordeaux University, Bordeaux, France.
(3)GIN, UMR5293, CNRS, Bordeaux, France.
(4)GIN, UMR5293, CEA, Bordeaux, France.
(5)Fealinx, Lyon, France.
(6)Bordeaux Population Health Research Center, UMR1219, Bordeaux University, Inserm, Bordeaux, France.
(7)Centre Hospitalier Universitaire de Bordeaux, Bordeaux, France.
(8)Ginesislab, Bordeaux, France. .
(9)GIN, UMR5293, Bordeaux University, Bordeaux, France. .
(10)GIN, UMR5293, CNRS, Bordeaux, France. .
(11)GIN, UMR5293, CEA, Bordeaux, France. .

Functional connectivity analyses of fMRI data have shown that the activity of the brain at rest is spatially organized into resting-state networks (RSNs). RSNs appear as groups of anatomically distant but functionally tightly connected brain regions. Inter-RSN intrinsic connectivity analyses may provide an optimal spatial level of integration to analyze the variability of the functional connectome. Here we propose a deep learning approach to enable the automated classification
of individual independent-component (IC) decompositions into a set of predefined RSNs. Two databases were used in this work, BIL&GIN and MRi-Share, with 427 and 1811 participants, respectively. We trained a multilayer perceptron (MLP) to classify each IC as one of 45 RSNs, using the IC classification of 282 participants in BIL&GIN for training and a 5-dimensional parameter grid search
for hyperparameter optimization. It reached an accuracy of 92 %. Predictions for the remaining individuals in BIL&GIN were tested against the original classification and demonstrated good spatial overlap between the cortical RSNs. As a first application, we created an RSN atlas based on MRi-Share. This atlas defined a brain parcellation in 29 RSNs covering 96 % of the gray matter. Second,
we proposed an individual-based analysis of the subdivision of the default-mode network into 4 networks. Minimal overlap between RSNs was found except in the angular gyrus and potentially in the precuneus. We thus provide the community with an individual IC classifier that can be used to analyze one dataset or to statistically compare different datasets for RSN spatial definitions.

 

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