Data-Driven Network Neuroscience: On Data Collection and Benchmark
- URL: http://arxiv.org/abs/2211.12421v6
- Date: Sun, 29 Oct 2023 10:35:05 GMT
- Title: Data-Driven Network Neuroscience: On Data Collection and Benchmark
- Authors: Jiaxing Xu, Yunhan Yang, David Tse Jung Huang, Sophi Shilpa
Gururajapathy, Yiping Ke, Miao Qiao, Alan Wang, Haribalan Kumar, Josh
McGeown, Eryn Kwon
- Abstract summary: This paper presents a collection of functional human brain network data for potential research in the intersection of neuroscience, machine learning, and graph analytics.
The datasets originate from 6 different sources, cover 4 brain conditions, and consist of a total of 2,702 subjects.
- Score: 6.796086914275059
- License: http://creativecommons.org/licenses/by-nc-sa/4.0/
- Abstract: This paper presents a comprehensive and quality collection of functional
human brain network data for potential research in the intersection of
neuroscience, machine learning, and graph analytics. Anatomical and functional
MRI images have been used to understand the functional connectivity of the
human brain and are particularly important in identifying underlying
neurodegenerative conditions such as Alzheimer's, Parkinson's, and Autism.
Recently, the study of the brain in the form of brain networks using machine
learning and graph analytics has become increasingly popular, especially to
predict the early onset of these conditions. A brain network, represented as a
graph, retains rich structural and positional information that traditional
examination methods are unable to capture. However, the lack of publicly
accessible brain network data prevents researchers from data-driven
explorations. One of the main difficulties lies in the complicated
domain-specific preprocessing steps and the exhaustive computation required to
convert the data from MRI images into brain networks. We bridge this gap by
collecting a large amount of MRI images from public databases and a private
source, working with domain experts to make sensible design choices, and
preprocessing the MRI images to produce a collection of brain network datasets.
The datasets originate from 6 different sources, cover 4 brain conditions, and
consist of a total of 2,702 subjects. We test our graph datasets on 12 machine
learning models to provide baselines and validate the data quality on a recent
graph analysis model. To lower the barrier to entry and promote the research in
this interdisciplinary field, we release our brain network data and complete
preprocessing details including codes at
https://doi.org/10.17608/k6.auckland.21397377 and
https://github.com/brainnetuoa/data_driven_network_neuroscience.
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