Optimal deep transfer learning driven computer‐aided breast cancer classification using ultrasound images

Breast cancer (BC) is regarded as the second leading type of cancer among women globally. Ultrasound images are typically used for the identification and classification of abnormalities that exist in the breast. To enhance diagnosis performance, the computer assisted diagnosis (CAD) model finds it e...

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Vydáno v:Expert systems Ročník 41; číslo 4
Hlavní autoři: Ragab, Mahmoud, Khadidos, Alaa O., Alshareef, Abdulrhman M., Khadidos, Adil O., Altwijri, Mohammed, Alhebaishi, Nawaf
Médium: Journal Article
Jazyk:angličtina
Vydáno: Oxford Blackwell Publishing Ltd 01.04.2024
Témata:
Abnormalities
Algorithms
Artificial neural networks
Breast cancer
Classification
computer‐aided diagnosis
Cost reduction
Deep learning
Diagnosis
Feature extraction
Image classification
Image enhancement
Image segmentation
Machine learning
Medical imaging
Ultrasonic imaging
Ultrasonic testing
ultrasound images
ISSN:0266-4720, 1468-0394
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Shrnutí:Breast cancer (BC) is regarded as the second leading type of cancer among women globally. Ultrasound images are typically used for the identification and classification of abnormalities that exist in the breast. To enhance diagnosis performance, the computer assisted diagnosis (CAD) model finds it effective for identifying and classifying BC. Generally, the CAD technique contains distinct procedures like feature extraction, preprocessing, segmentation, and classification. The recent developments of deep learning (DL) algorithms in the form of CAD system helps to minimize the cost and enhance the ability of radiologists to interpret medical images. Therefore, this study develops an optimal deep transfer learning driven computer aided BC classification (ODTLD‐CABCC) technique on ultrasound images. The presented ODTLD‐CABCC algorithm undergoes pre‐processing in two levels such as median filtering based noise removal and graph cut segmentation. Furthermore, the residual network (ResNet101) model can be used as a feature extractor. Finally, the sailfish optimizer (SFO) with a labelled weighted extreme learning machine (LWELM) algorithm is used for the classification process. The SFO technique is employed to choose optimal parameters involved in the LWELM algorithm. A comprehensive set of simulations are conducted on the benchmark data and the experimental outcomes are examined under numerous aspects. The comparative examination represents the supremacy of the ODTLD‐CABCC technique over the other approaches.
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ISSN:0266-4720
1468-0394
DOI:10.1111/exsy.13515