A Deep Learning Based Intelligent Decision Support System for Automatic Detection of Brain Tumor.
Zahid UllahMona JamjoomManikandan ThirumalaisamySamah H AlajmaniFarrukh SaleemAkbar Sheikh-AkbariUsman Ali KhanPublished in: Biomedical engineering and computational biology (2024)
Brain tumor (BT) is an awful disease and one of the foremost causes of death in human beings. BT develops mainly in 2 stages and varies by volume, form, and structure, and can be cured with special clinical procedures such as chemotherapy, radiotherapy, and surgical mediation. With revolutionary advancements in radiomics and research in medical imaging in the past few years, computer-aided diagnostic systems (CAD), especially deep learning, have played a key role in the automatic detection and diagnosing of various diseases and significantly provided accurate decision support systems for medical clinicians. Thus, convolution neural network (CNN) is a commonly utilized methodology developed for detecting various diseases from medical images because it is capable of extracting distinct features from an image under investigation. In this study, a deep learning approach is utilized to extricate distinct features from brain images in order to detect BT. Hence, CNN from scratch and transfer learning models (VGG-16, VGG-19, and LeNet-5) are developed and tested on brain images to build an intelligent decision support system for detecting BT. Since deep learning models require large volumes of data, data augmentation is used to populate the existing dataset synthetically in order to utilize the best fit detecting models. Hyperparameter tuning was conducted to set the optimum parameters for training the models. The achieved results show that VGG models outperformed others with an accuracy rate of 99.24%, average precision of 99%, average recall of 99%, average specificity of 99%, and average f 1-score of 99% each. The results of the proposed models compared to the other state-of-the-art models in the literature show better performance of the proposed models in terms of accuracy, sensitivity, specificity, and f 1-score. Moreover, comparative analysis shows that the proposed models are reliable in that they can be used for detecting BT as well as helping medical practitioners to diagnose BT.
Keyphrases
- deep learning
- convolutional neural network
- artificial intelligence
- healthcare
- machine learning
- neural network
- systematic review
- primary care
- magnetic resonance imaging
- high resolution
- coronary artery disease
- endothelial cells
- computed tomography
- multiple sclerosis
- photodynamic therapy
- brain injury
- subarachnoid hemorrhage
- blood brain barrier
- general practice