An efficient deep learning-based approach for Glioblastoma detection from MRI images
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BRAC University
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Abstract
In essence, an abnormal increase of brain cells is referred to as a brain tumor. Tumors
come in two varieties: benign (non-cancerous) and malignant (cancerous). Cancerous
tumors can originate in the brain itself (Primary) or spread from elsewhere from
other parts of the body as well (secondary or metastatic tumors). One of the most
aggressive and malignant forms of brain tumor is Glioblastoma which is also known
as glioblastoma multiforme (GBM). Glial cells are the supportive cells in the brain
which is the main origin of GBM tumors. The rapid growth of GBM and its tendency
to spread into nearby brain tissue makes complete surgical removal of the
tumor challenging. The main purpose of this study was to build an efficient model
with the application of deep learning techniques to detect glioblastoma accurately.
We implemented a binaraized version of ResNet18, VGG16, and DenseNet121 with
the Binary Weight Networks (BWN) approach. This conversion to binary values
saved almost 30x memory. In Binary Weight Networks (BWN) the weights are
binary value but the inputs are not binarized, input data remains full-precision format.
Applying binary operation in convolution layers helped 40x faster operations
in convolution compared to full precision operations. This memory savings will help
us to run those models in real-time only using CPU rather than heavy GPU. Our
simple binary models are efficient and accurate also on detecting Glioma. We evaluated
our model’s performance with TCGA-GBM and IXI dataset using accuracy,
confusion matrix, and ROC curve matrics. For ResNet18 we got 89% accuracy. For
DenseNet121, we got 85% accuracy. And for VGG16, we got 87% accuracy. The
classification with a Binary Weight Network version of ResNet18, DenseNet121, and
VGG16 is as closely accurate as the full precision. We compared our binary models
with full-precision models, which gave us a balance between accuracy and efficiency,
with a 33x reduction in model size and 30x memory saving.
Description
Cataloged from PDF version of thesis.
Includes bibliographical references (pages 46-49).
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 46-49).
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