Classification of Alzheimer’s and Dementia subtypes using R-STDP driven spiking neural networks
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BRAC University
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Abstract
Early classification of Dementia which can further lead to Alzheimer’s disease remains
challenging due to subtle brain structural changes in MRI scans. This paper
presents a novel neuromorphic feature extraction approach combining biologically inspired
temporal encoding with Forward-Forward learning for the classification
of Alzheimer’s and dementia subtypes. Our methodology employs a three-stage
pipeline: neuromorphic preprocessing converts 32×32 brain MRI data into temporal
spike patterns across 20 time steps, incorporating skull stripping and CLAHE enhancement;
Forward-Forward learning with Reward-based Spike-Timing-Dependent
Plasticity (R-STDP) autoencoder extracts latent features without traditional backpropagation;
ensemble classification using Random Forest and Gradient Boosting
provides final predictions. The neuromorphic preprocessor generates 8,192-
dimensional feature vectors capturing temporal dynamics including first spike timing,
burst detection, temporal phases, and activity statistics. The Forward-Forward
R-STDP autoencoder learns biologically-plausible representations through positivenegative
sample discrimination with a 256-dimensional latent bottleneck. Advanced
feature selection reduces combined features to around 3000 optimal dimensions
through variance filtering, statistical selection, and recursive feature elimination.
Our system achieves 77.92% ensemble accuracy on Demented vs. NonDemented
classification, with 79.47% weighted precision and 77.69% out-of-bag score. Random
Forest achieves 78.77% accuracy while Gradient Boosting reaches 76.93%. Our
neuromorphic approach allows parallel processing, reducing computational overhead
compared to conventional deep learning and using biologically-inspired representations
to capture temporal patterns in brain imaging data. This framework aims to
provide an energy-efficient alternative to traditional deep learning while ensuring
that a robust classification performance is maintained for neurodegenerative disease
detection.
Description
Cataloged from PDF version of thesis.
Includes bibliographical references (pages 48-51).
This thesis is submitted in partial fulfillment of the requirements for the degree of Bachelor of Science in Computer Science, 2025.
Includes bibliographical references (pages 48-51).
This thesis is submitted in partial fulfillment of the requirements for the degree of Bachelor of Science in Computer Science, 2025.
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Thesis