Your search keyword '"Sadad, Tariq"' showing total 4 results

1. Automatic skin lesions detection from images through microscopic hybrid features set and machine learning classifiers.

Author

Alyami, Jaber, Rehman, Amjad, Sadad, Tariq, Alruwaythi, Maryam, Saba, Tanzila, and Bahaj, Saeed Ali

Abstract

Skin cancer occurrences increase exponentially worldwide due to the lack of awareness of significant populations and skin specialists. Medical imaging can help with early detection and more accurate diagnosis of skin cancer. The physicians usually follow the manual diagnosis method in their clinics but nonprofessional dermatologists sometimes affect the accuracy of the results. Thus, the automated system is required to assist physicians in diagnosing skin cancer at early stage precisely to decrease the mortality rate. This article presents an automatic skin lesions detection through a microscopic hybrid feature set and machine learning‐based classification. The employment of deep features through AlexNet architecture with local optimal‐oriented pattern can accurately predict skin lesions. The proposed model is tested on two open‐access datasets PAD‐UFES‐20 and MED‐NODE comprising melanoma and nevus images. Experimental results on both datasets exhibit the efficacy of hybrid features with the help of machine learning. Finally, the proposed model achieved 94.7% accuracy using an ensemble classifier. Research highlights: The deep features accurately predicted skin lesions through AlexNet architecture with local optimal‐oriented pattern.Proposed model is tested on two datasets PAD‐UFES‐20, MED‐NODE comprising melanoma, nevus images and exhibited high accuracy. [ABSTRACT FROM AUTHOR]

Published

2022

2. Optimizing the transfer‐learning with pretrained deep convolutional neural networks for first stage breast tumor diagnosis using breast ultrasound visual images.

Author

Saba, Tanzila, Abunadi, Ibrahim, Sadad, Tariq, Khan, Amjad Rehman, and Bahaj, Saeed Ali

Abstract

Female accounts for approximately 50% of the total population worldwide and many of them had breast cancer. Computer‐aided diagnosis frameworks could reduce the number of needless biopsies and the workload of radiologists. This research aims to detect benign and malignant tumors automatically using breast ultrasound (BUS) images. Accordingly, two pretrained deep convolutional neural network (CNN) models were employed for transfer learning using BUS images like AlexNet and DenseNet201. A total of 697 BUS images containing benign and malignant tumors are preprocessed and performed classification tasks using the transfer learning‐based CNN models. The classification accuracy of the benign and malignant tasks is completed and achieved 92.8% accuracy using the DensNet201 model. The results thus achieved compared in state of the art using benchmark data set and concluded proposed model outperforms in accuracy from first stage breast tumor diagnosis. Finally, the proposed model could help radiologists diagnose benign and malignant tumors swiftly by screening suspected patients. [ABSTRACT FROM AUTHOR]

Published

2022

3. Internet of medical things embedding deep learning with data augmentation for mammogram density classification.

Author

Sadad, Tariq, Khan, Amjad Rehman, Hussain, Ayyaz, Tariq, Usman, Fati, Suliman Mohamed, Bahaj, Saeed Ali, and Munir, Asim

Abstract

Females are approximately half of the total population worldwide, and most of them are victims of breast cancer (BC). Computer‐aided diagnosis (CAD) frameworks can help radiologists to find breast density (BD), which further helps in BC detection precisely. This research detects BD automatically using mammogram images based on Internet of Medical Things (IoMT) supported devices. Two pretrained deep convolutional neural network models called DenseNet201 and ResNet50 were applied through a transfer learning approach. A total of 322 mammogram images containing 106 fatty, 112 dense, and 104 glandular cases were obtained from the Mammogram Image Analysis Society dataset. The pruning out irrelevant regions and enhancing target regions is performed in preprocessing. The overall classification accuracy of the BD task is performed and accomplished 90.47% through DensNet201 model. Such a framework is beneficial in identifying BD more rapidly to assist radiologists and patients without delay. [ABSTRACT FROM AUTHOR]

Published

2021

4. Brain tumor detection and multi‐classification using advanced deep learning techniques.

Author

Sadad, Tariq, Rehman, Amjad, Munir, Asim, Saba, Tanzila, Tariq, Usman, Ayesha, Noor, and Abbasi, Rashid

Abstract

A brain tumor is an uncontrolled development of brain cells in brain cancer if not detected at an early stage. Early brain tumor diagnosis plays a crucial role in treatment planning and patients' survival rate. There are distinct forms, properties, and therapies of brain tumors. Therefore, manual brain tumor detection is complicated, time‐consuming, and vulnerable to error. Hence, automated computer‐assisted diagnosis at high precision is currently in demand. This article presents segmentation through Unet architecture with ResNet50 as a backbone on the Figshare data set and achieved a level of 0.9504 of the intersection over union (IoU). The preprocessing and data augmentation concept were introduced to enhance the classification rate. The multi‐classification of brain tumors is performed using evolutionary algorithms and reinforcement learning through transfer learning. Other deep learning methods such as ResNet50, DenseNet201, MobileNet V2, and InceptionV3 are also applied. Results thus obtained exhibited that the proposed research framework performed better than reported in state of the art. Different CNN, models applied for tumor classification such as MobileNet V2, Inception V3, ResNet50, DenseNet201, NASNet and attained accuracy 91.8, 92.8, 92.9, 93.1, 99.6%, respectively. However, NASNet exhibited the highest accuracy. [ABSTRACT FROM AUTHOR]

Published

2021