GM-VGG-Net: A Gray Matter-Based Deep Learning Network for Autism Classification
Ebenezer Daniel, Anjalie Gulati, Shraya Saxena, Deniz Akay Urgun, Biraj Bista

TL;DR
This paper introduces a deep learning model that uses gray matter brain scans to classify autism with high accuracy.
Contribution
The study is the first to use gray matter tissue alone with a VGG-Net model for autism classification.
Findings
The model achieved 97% training accuracy and 96% validation accuracy without overfitting.
ASD and control groups were comparable in age and size (p = 0.23).
Abstract
Background: Around 1 in 59 individuals is diagnosed with Autism Spectrum Disorder (ASD), according to CDS statistics. Conventionally, ASD has been diagnosed using functional brain regions, regions of interest, or multi-tissue-based training in artificial intelligence models. The objective of the exhibit study is to develop an efficient deep learning network for identifying ASD using structural magnetic resonance imaging (MRI)-based brain scans. Methods: In this work, we developed a VGG-based deep learning network capable of diagnosing autism using whole brain gray matter (GM) tissues. We trained our deep network with 132 MRI T1 images from normal controls and 140 MRI T1 images from ASD patients sourced from the Autism Brain Imaging Data Exchange (ABIDE) dataset. Results: The number of participants in both ASD and normal control (CN) subject groups was not statistically different (p =…
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Taxonomy
TopicsAutism Spectrum Disorder Research · Genetics and Neurodevelopmental Disorders · Functional Brain Connectivity Studies
