Hybrid Quantum Graph Neural Network for Brain Tumor MR Image Classification: HYBRID QUANTUM GRAPH NEURAL NETWORK FOR BRAIN TUMOR MR IMAGE

S P Rajamohana; Vani Yelamali; Pallavi Soni; Manjunath Vanahalli; Prabu Prasad

doi:10.56042/jsir.v84i1.14112

Authors

S P Rajamohana Department of Computer science, School of Engineering & Technology, Pondicherry University, Karaikal 609 605, Puducherry, India
Vani Yelamali Department of Computer Science and Engineering, Indian Institute of Information Technology Dharwad 580 009, Karnataka, India
Pallavi Soni Quantum Computing Researcher, Kwantum G Research Labs Pvt Ltd, Bangalore 560 064, Karnataka, India
Manjunath Vanahalli Department of Computer Science and Engineering, Indian Institute of Information Technology Dharwad 580 009, Karnataka, India
Prabu Prasad Department of Computer Science and Engineering, Indian Institute of Information Technology Dharwad 580 009, Karnataka, India

DOI:

https://doi.org/10.56042/jsir.v84i1.14112

Keywords:

Brain tumor MRI classification, Graph convolutional neural network, Quantum graph neural network

Abstract

Brain tumor rank as the tenth leading cause of mortality among both adults and children. Early detection and treatment significantly enhance survival rates. Recent advancements in deep learning have demonstrated promise in identifying and classifying brain tumors using Magnetic Resonance Imaging (MRI) scans. This paper presents a novel approach that integrates classical and hybrid quantum-inspired graph neural networks for tumor classification. Classical Graph Convolutional Neural Networks (GCNN) analyse complex relationships within medical imaging data, while hybrid Quantum Graph Neural Networks (QGNN) improves performance by leveraging principles of quantum computing. Previous studies highlight the challenges posed by the diverse nature of brain imaging data. This study compares various classification approaches, emphasizing architectures, training techniques, and performance metrics. The objective is to train and evaluate models for identifying brain tumors from MRI scans. The hybrid QGNN demonstrates accuracy and loss metrics comparable to advanced classical GCNN, with accuracy improving from 0.41(41%) to 0.64(64%) during training and from 0.31(31%) to 0.52(52%) in validation datasets, thereby showcasing its effectiveness in distinguishing between normal and tumor images.