Your search keyword '"Alqhtani, Samar M."' showing total 7 results

1. Next-Gen brain tumor classification: pioneering with deep learning and finetuned conditional generative adversarial networks.

Author

Asiri, Abdullah A., Aamir, Muhammad, Ali, Tariq, Shaf, Ahmad, Irfan, Muhammad, Mehdar, Khlood M., Alqhtani, Samar M., Alghamdi, Ali H., Alshamrani, Abdullah Fahad A., and Alshehri, Osama M.

Subjects

GENERATIVE adversarial networks, DEEP learning, BRAIN tumors, TUMOR classification, CONVOLUTIONAL neural networks, MACHINE learning

Abstract

Brain tumor has become one of the fatal causes of death worldwide in recent years, affecting many individuals annually and resulting in loss of lives. Brain tumors are characterized by the abnormal or irregular growth of brain tissues that can spread to nearby tissues and eventually throughout the brain. Although several traditional machine learning and deep learning techniques have been developed for detecting and classifying brain tumors, they do not always provide an accurate and timely diagnosis. This study proposes a conditional generative adversarial network (CGAN) that leverages the fine-tuning of a convolutional neural network (CNN) to achieve more precise detection of brain tumors. The CGAN comprises two parts, a generator and a discriminator, whose outputs are used as inputs for fine-tuning the CNN model. The publicly available dataset of brain tumor MRI images on Kaggle was used to conduct experiments for Datasets 1 and 2. Statistical values such as precision, specificity, sensitivity, F1-score, and accuracy were used to evaluate the results. Compared to existing techniques, our proposed CGAN model achieved an accuracy value of 0.93 for Dataset 1 and 0.97 for Dataset 2. [ABSTRACT FROM AUTHOR]

Published

2023

2. Effectiveness of Deep Learning Models for Brain Tumor Classification and Segmentation.

Author

Irfan, Muhammad, Shaf, Ahmad, Ali, Tariq, Farooq, Umar, Rahman, Saifur, Faraj Mursal, Salim Nasar, Jalalah, Mohammed, Alqhtani, Samar M., and AlShorman, Omar

Subjects

BRAIN tumors, DEEP learning, TUMOR classification, COMPUTER-aided diagnosis, CAUSES of death, CELL growth

Abstract

A brain tumor is a mass or growth of abnormal cells in the brain. In children and adults, brain tumor is considered one of the leading causes of death. There are several types of brain tumors, including benign (non-cancerous) and malignant (cancerous) tumors. Diagnosing brain tumors as early as possible is essential, as this can improve the chances of successful treatment and survival. Considering this problem, we bring forth a hybrid intelligent deep learning technique that uses several pre-trained models (Resnet50, Vgg16, Vgg19, U-Net) and their integration for computer-aided detection and localization systems in brain tumors. These pre-trained and integrated deep learning models have been used on the publicly available dataset from The Cancer Genome Atlas. The dataset consists of 120 patients. The pre-trained models have been used to classify tumor or no tumor images, while integrated models are applied to segment the tumor region correctly. We have evaluated their performance in terms of loss, accuracy, intersection over union, Jaccard distance, dice coefficient, and dice coefficient loss. From pre-trained models, the U-Net model achieves higher performance than other models by obtaining 95% accuracy. In contrast, U-Net with ResNet-50 outperforms all other models from integrated pre-trained models and correctly classified and segmented the tumor region. [ABSTRACT FROM AUTHOR]

Published

2023

3. Brain Tumor Detection and Classification Using Fine-Tuned CNN with ResNet50 and U-Net Model: A Study on TCGA-LGG and TCIA Dataset for MRI Applications.

Author

Asiri, Abdullah A., Shaf, Ahmad, Ali, Tariq, Aamir, Muhammad, Irfan, Muhammad, Alqahtani, Saeed, Mehdar, Khlood M., Halawani, Hanan Talal, Alghamdi, Ali H., Alshamrani, Abdullah Fahad A., and Alqhtani, Samar M.

Subjects

BRAIN tumors, TUMOR classification, MAGNETIC resonance imaging, PROBLEM solving

Abstract

Nowadays, brain tumors have become a leading cause of mortality worldwide. The brain cells in the tumor grow abnormally and badly affect the surrounding brain cells. These cells could be either cancerous or non-cancerous types, and their symptoms can vary depending on their location, size, and type. Due to its complex and varying structure, detecting and classifying the brain tumor accurately at the initial stages to avoid maximum death loss is challenging. This research proposes an improved fine-tuned model based on CNN with ResNet50 and U-Net to solve this problem. This model works on the publicly available dataset known as TCGA-LGG and TCIA. The dataset consists of 120 patients. The proposed CNN and fine-tuned ResNet50 model are used to detect and classify the tumor or no-tumor images. Furthermore, the U-Net model is integrated for the segmentation of the tumor regions correctly. The model performance evaluation metrics are accuracy, intersection over union, dice similarity coefficient, and similarity index. The results from fine-tuned ResNet50 model are IoU: 0.91, DSC: 0.95, SI: 0.95. In contrast, U-Net with ResNet50 outperforms all other models and correctly classified and segmented the tumor region. [ABSTRACT FROM AUTHOR]

Published

2023

4. Exploring the Power of Deep Learning: Fine-Tuned Vision Transformer for Accurate and Efficient Brain Tumor Detection in MRI Scans.

Author

Asiri, Abdullah A., Shaf, Ahmad, Ali, Tariq, Shakeel, Unza, Irfan, Muhammad, Mehdar, Khlood M., Halawani, Hanan Talal, Alghamdi, Ali H., Alshamrani, Abdullah Fahad A., and Alqhtani, Samar M.

Subjects

TRANSFORMER models, BRAIN tumors, DEEP learning, FEATURE selection, MEDICAL sciences, MAGNETIC resonance imaging

Abstract

A brain tumor is a significant health concern that directly or indirectly affects thousands of people worldwide. The early and accurate detection of brain tumors is vital to the successful treatment of brain tumors and the improved quality of life of the patient. There are several imaging techniques used for brain tumor detection. Among these techniques, the most common are MRI and CT scans. To overcome the limitations associated with these traditional techniques, computer-aided analysis of brain images has gained attention in recent years as a promising approach for accurate and reliable brain tumor detection. In this study, we proposed a fine-tuned vision transformer model that uses advanced image processing and deep learning techniques to accurately identify the presence of brain tumors in the input data images. The proposed model FT-ViT involves several stages, including the processing of data, patch processing, concatenation, feature selection and learning, and fine tuning. Upon training the model on the CE-MRI dataset containing 5712 brain tumor images, the model could accurately identify the tumors. The FT-Vit model achieved an accuracy of 98.13%. The proposed method offers high accuracy and can significantly reduce the workload of radiologists, making it a practical approach in medical science. However, further research can be conducted to diagnose more complex and rare types of tumors with more accuracy and reliability. [ABSTRACT FROM AUTHOR]

Published

2023

5. Multi-Level Deep Generative Adversarial Networks for Brain Tumor Classification on Magnetic Resonance Images.

Author

Asiri, Abdullah A., Shaf, Ahmad, Ali, Tariq, Aamir, Muhammad, Usman, Ali, Irfan, Muhammad, Alshamrani, Hassan A., Mehdar, Khlood M., Alshehri, Osama M., and Alqhtani, Samar M.

Subjects

GENERATIVE adversarial networks, MAGNETIC resonance imaging, BRAIN tumors, CONTRAST-enhanced magnetic resonance imaging, TUMOR classification

Abstract

The brain tumor is an abnormal and hysterical growth of brain tissues, and the leading cause of death affected patients worldwide. Even in this technology-based arena, brain tumor images with proper labeling and acquisition still have a problem with the accurate and reliable generation of realistic images of brain tumors that are completely different from the original ones. The artificially created medical image data would help improve the learning ability of physicians and other computer-aided systems for the generation of augmented data. To overcome the highlighted issue, a Generative Adversarial Network (GAN) deep learning technique in which two neural networks compete to become more accurate in creating artificially realistic data for MRI images. The GAN network contains mainly two parts known as generator and discriminator. Commonly, a generator is the convolutional neural network, and a discriminator is the deconvolutional neural network. In this research, the publicly accessible Contrast-Enhanced Magnetic Resonance Imaging (CE-MRI) dataset collected from 2005-to 2020 from different hospitals in China consists of four classes has been used. Our proposed method is simple and achieved an accuracy of 96%. We compare our technique results with the existing results, indicating that our proposed technique outperforms the best results associated with the existing methods. [ABSTRACT FROM AUTHOR]

Published

2023

6. A U-Net-Based CNN Model for Detection and Segmentation of Brain Tumor.

Author

Ghulam, Rehana, Fatima, Sammar, Ali, Tariq, Zafar, Nazir Ahmad, Asiri, Abdullah A., Alshamrani, Hassan A., Alqhtani, Samar M., and Mehdar, Khlood M.

Subjects

BRAIN tumors, DEEP learning, MAGNETIC resonance imaging, CONVOLUTIONAL neural networks, IMAGE segmentation

Abstract

Human brain consists of millions of cells to control the overall structure of the human body. When these cells start behaving abnormally, then brain tumors occurred. Precise and initial stage brain tumor detection has always been an issue in the field of medicines for medical experts. To handle this issue, various deep learning techniques for brain tumor detection and segmentation techniques have been developed, which worked on different datasets to obtain fruitful results, but the problem still exists for the initial stage of detection of brain tumors to save human lives. For this purpose, we proposed a novel U-Net-based Convolutional Neural Network (CNN) technique to detect and segmentizes the brain tumor for Magnetic Resonance Imaging (MRI). Moreover, a 2-dimensional publicly available Multimodal Brain Tumor Image Segmentation (BRATS2020) dataset with 1840 MRI images of brain tumors has been used having an image size of 240×240 pixels. After initial dataset preprocessing the proposed model is trained by dividing the dataset into three parts i.e., testing, training, and validation process. Our model attained an accuracy value of 0.98%on the BRATS2020 dataset, which is the highest one as compared to the already existing techniques. [ABSTRACT FROM AUTHOR]

Published

2023

7. Enhancement of Medical Images through an Iterative McCann Retinex Algorithm: A Case of Detecting Brain Tumor and Retinal Vessel Segmentation.

Author

Almalki, Yassir Edrees, Jandan, Nisar Ahmed, Soomro, Toufique Ahmed, Ali, Ahmed, Kumar, Pardeep, Irfan, Muhammad, Keerio, Muhammad Usman, Rahman, Saifur, Alqahtani, Ali, Alqhtani, Samar M., Hakami, Mohammed Awaji M., S, Alqahtani Saeed, Aldhabaan, Waleed A., and Khairallah, Abdulrahman Samir

Subjects

RETINAL blood vessels, IMAGE intensifiers, BRAIN tumors, DIAGNOSTIC imaging, MAGNETIC resonance imaging, IMAGE databases, IMAGE segmentation

Abstract

Analyzing medical images has always been a challenging task because these images are used to observe complex internal structures of the human body. This research work is based on the study of the retinal fundus and magnetic resonance images (MRI) for the analysis of ocular and cerebral abnormalities. Typically, clinical quality images of the eyes and brain have low-varying contrast, making it challenge to diagnose a specific disease. These issues can be overcome, and preprocessing or an image enhancement technique is required to properly enhance images to facilitate postprocessing. In this paper, we propose an iterative algorithm based on the McCann Retinex algorithm for retinal and brain MRI. The foveal avascular zone (FAZ) region of retinal images and the coronal, axial, and sagittal brain images are enhanced during the preprocessing step. The High-Resolution Fundus (HRF) and MR brain Oasis images databases are used, and image contrast and peak signal-to-noise ratio (PSNR) are used to assess the enhancement step parameters. The average PSNR enhancement on images from the Oasis brain MRI database was about 3 dB with an average contrast of 57.4. The average PSNR enhancement of the HRF database images was approximately 2.5 dB with a contrast average of 40 over the database. The proposed method was also validated in the postprocessing steps to observe its impact. A well-segmented image was obtained with an accuracy of 0.953 and 0.0949 on the DRIVE and STARE databases. Brain tumors were detected from the Oasis brain MRI database with an accuracy of 0.97. This method can play an important role in helping medical experts diagnose eye diseases and brain tumors from retinal images and Oasis brain images. [ABSTRACT FROM AUTHOR]

Published

2022