Detecting ASD in individuals based on their brain functional connectivity patterns
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BRAC University
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Abstract
The main focus of this research is on accurate pediatric neurodevelopmental disorder
diagnostics as well as early detection of Autism Spectrum Disorder (ASD)
children and adolescents. Given the heightened neuroplasticity of the brain during
these formative years, the ability to detect ASD (Autism Spectrum Disorder)
early in development has profound implications for intervention and outcomes.This
inherent variability poses a challenge when attempting to classify ASD (Autism
Spectrum Disorder) using the intricate 4D fMRI data from ABIDE I that captures
both spatial and temporal aspects of brain activity. Majority of research dealing
with the neuroimaging methods has typically reduced this high-dimensional 4D
data to a 2D correlation matrix, leading to a potential loss of crucial information
related to both the dynamic brain activity and the connectivity patterns. In response
to this limitation, we introduce an innovative preprocessing framework, NeuroSeg3D
(Neuroimaging Segmentation for 3D framework), a cutting-edge pipeline
designed to preserve the full 4D integrity of the fMRI(Voxel intensity) data. Also
by retaining the inherent temporal and spatial complexities of the 4D fMRI scans,
NeuroSeg3D empowers the model to extract a more nuanced understanding of the
brain’s architecture, which is paramount for accurate ASD classification. Building
on this advanced preprocessing methodology, we developed CASD-Net (Children
ASD Neural Network), a specialized convolutional neural network (CNN) meticulously
engineered to handle the complexities of 4D neuroimaging data. CASD-Net
(Children ASD Neural Network) utilizes state-of-the-art deep learning techniques
to extract high-level features from raw fMRI volumes, capturing both spatial and
temporal dependencies crucial for distinguishing ASD from non-ASD individuals.
By employing multiple convolutional layers, attention mechanisms, and optimization
strategies, CASD-Net(Children ASD Neural Network) is able to identify and
learn intricate patterns within the 4D brain scans that are often imperceptible to
conventional analysis methods. Beside this the model’s performance was rigorously
evaluated through both test set validation and 5-fold cross-validation, ensuring its
robustness and generalizability across different subsets of data. Most importantly
CASD-Net(Children ASD Neural Network) has achieved a remarkable test accuracy
of 93.97%, underscoring its high performance in distinguishing ASD from control
subjects. Beyond that, the cross-validation results of the model depicted a solid
generalization capabilities, with an average accuracy of 83.57%, an average loss
of 0.3147, and a standard deviation of 16.27%, and thus highlighting the model’s
adaptability despite variability in the dataset. The model we developed has demonstrated
a robust performance through the classification metrics like precision, recall,
and F1-score. Ensuring that both ASD(Autism Spectrum Disorder) and control
classifications were accurate, reliable, and balanced. This result has underscored an enormous potentiality that our developed model possessed while revolutionizing
neuroimaging diagnostics, especially with the complex and high-dimensional data
ABIDE I.
Description
Cataloged from PDF version of thesis.
Includes bibliographical references (pages 61-64).
This thesis is submitted in partial fulfillment of the requirements for the degree of Bachelor of Science in Computer Science, 2024.
Includes bibliographical references (pages 61-64).
This thesis is submitted in partial fulfillment of the requirements for the degree of Bachelor of Science in Computer Science, 2024.
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Thesis