Parallelistic Convolution Neural Network Approach for Brain Tumor Diagnosis.
Goodness Temofe MgbejimeMd Altab HossainGrace Ugochi NnejiHappy Nkanta MondayFavour EkongPublished in: Diagnostics (Basel, Switzerland) (2022)
Today, Magnetic Resonance Imaging (MRI) is a prominent technique used in medicine, produces a significant and varied range of tissue contrasts in each imaging modalities, and is frequently employed by medical professionals to identify brain malignancies. With brain tumor being a very deadly disease, early detection will help increase the likelihood that the patient will receive the appropriate medical care leading to either a full elimination of the tumor or the prolongation of the patient's life. However, manually examining the enormous volume of magnetic resonance imaging (MRI) images and identifying a brain tumor or cancer is extremely time-consuming and requires the expertise of a trained medical expert or brain doctor to manually detect and diagnose brain cancer using multiple Magnetic Resonance images (MRI) with various modalities. Due to this underlying issue, there is a growing need for increased efforts to automate the detection and diagnosis process of brain tumor without human intervention. Another major concern most research articles do not consider is the low quality nature of MRI images which can be attributed to noise and artifacts. This article presents a Contrast Limited Adaptive Histogram Equalization (CLAHE) algorithm to precisely handle the problem of low quality MRI images by eliminating noisy elements and enhancing the visible trainable features of the image. The enhanced image is then fed to the proposed PCNN to learn the features and classify the tumor using sigmoid classifier. To properly train the model, a publicly available dataset is collected and utilized for this research. Additionally, different optimizers and different values of dropout and learning rates are used in the course of this study. The proposed PCNN with Contrast Limited Adaptive Histogram Equalization (CLAHE) algorithm achieved an accuracy of 98.7%, sensitivity of 99.7%, and specificity of 97.4%. In comparison with other state-of-the-art brain tumor methods and pre-trained deep transfer learning models, the proposed PCNN model obtained satisfactory performance.
Keyphrases
- contrast enhanced
- magnetic resonance imaging
- deep learning
- magnetic resonance
- diffusion weighted
- diffusion weighted imaging
- neural network
- computed tomography
- convolutional neural network
- white matter
- healthcare
- resting state
- optical coherence tomography
- papillary thyroid
- randomized controlled trial
- case report
- endothelial cells
- photodynamic therapy
- functional connectivity
- multiple sclerosis
- real time pcr
- dual energy
- childhood cancer