An Integrated Deep Learning Framework for Effective Brain Tumor
Localization, Segmentation, and Classification from Magnetic Resonance Images
- URL: http://arxiv.org/abs/2409.17273v1
- Date: Wed, 25 Sep 2024 18:38:57 GMT
- Title: An Integrated Deep Learning Framework for Effective Brain Tumor
Localization, Segmentation, and Classification from Magnetic Resonance Images
- Authors: Pandiyaraju V, Shravan Venkatraman, Abeshek A, Aravintakshan S A,
Pavan Kumar S, Madhan S
- Abstract summary: Tumors in the brain result from abnormal cell growth within the brain tissue, arising from various types of brain cells.
Our research proposes DL frameworks for localizing, segmenting, and classifying the grade of these gliomas from MRI images to solve this critical issue.
Our proposed models demonstrated promising results, with the potential to advance medical AI by enabling early diagnosis and providing more accurate treatment options for patients.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Tumors in the brain result from abnormal cell growth within the brain tissue,
arising from various types of brain cells. When left undiagnosed, they lead to
severe neurological deficits such as cognitive impairment, motor dysfunction,
and sensory loss. As the tumor grows, it causes an increase in intracranial
pressure, potentially leading to life-threatening complications such as brain
herniation. Therefore, early detection and treatment are necessary to manage
the complications caused by such tumors to slow down their growth. Numerous
works involving deep learning (DL) and artificial intelligence (AI) are being
carried out to assist physicians in early diagnosis by utilizing the scans
obtained through Magnetic Resonance Imaging (MRI). Our research proposes DL
frameworks for localizing, segmenting, and classifying the grade of these
gliomas from MRI images to solve this critical issue. In our localization
framework, we enhance the LinkNet framework with a VGG19- inspired encoder
architecture for improved multimodal tumor feature extraction, along with
spatial and graph attention mechanisms to refine feature focus and
inter-feature relationships. Following this, we integrated the SeResNet101 CNN
model as the encoder backbone into the LinkNet framework for tumor
segmentation, which achieved an IoU Score of 96%. To classify the segmented
tumors, we combined the SeResNet152 feature extractor with an Adaptive Boosting
classifier, which yielded an accuracy of 98.53%. Our proposed models
demonstrated promising results, with the potential to advance medical AI by
enabling early diagnosis and providing more accurate treatment options for
patients.
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