An adaptive deep learning approach based on InBNFus and CNNDen-GRU networks for breast cancer and maternal fetal classification using ultrasound imagesopen access
- Authors
- Fatima, Mamuna; Khan, Muhammad Attique; Mirza, Anwar M.; Shin, Jungpil; Alasiry, Areej; Marzougui, Mehrez; Cha, Jaehyuk; Chang, Byoungchol
- Issue Date
- Jul-2025
- Publisher
- Nature Publishing Group
- Keywords
- Breast cancer; Sparse autoencoders; Data augmentation; Image processing; Fusion; Classification; Explainable AI
- Citation
- Scientific Reports, v.15, no.1, pp 1 - 18
- Pages
- 18
- Indexed
- SCIE
SCOPUS
- Journal Title
- Scientific Reports
- Volume
- 15
- Number
- 1
- Start Page
- 1
- End Page
- 18
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/208350
- DOI
- 10.1038/s41598-025-03402-z
- ISSN
- 2045-2322
2045-2322
- Abstract
- Convolutional Neural Networks (CNNs), a sophisticated deep learning technique, have proven highly effective in identifying and classifying abnormalities related to various diseases. The manual classification of these is a hectic and time-consuming process; therefore, it is essential to develop a computerized technique. Most existing methods are designed to address a single specific problem, limiting their adaptability. In this work, we proposed a novel adaptive deep-learning framework for simultaneously classifying breast cancer and maternal-fetal ultrasound datasets. Data augmentation was applied in the preprocessing phase to address the data imbalance problem. After, two novel architectures are proposed: InBnFUS and CNNDen-GRU. The InBnFUS network combines 5-Blocks inception-based architecture (Model 1) and 5-Blocks inverted bottleneck-based architecture (Model 2) through a depth-wise concatenation layer, while CNNDen-GRU incorporates 5-Blocks dense architecture with an integrated GRU layer. Post-training features were extracted from the global average pooling and GRU layer and classified using neural network classifiers. The experimental evaluation achieved enhanced accuracy rates of 99.0% for breast cancer, 96.6% for maternal-fetal (common planes), and 94.6% for maternal-fetal (brain) datasets. Additionally, the models consistently achieve high precision, recall, and F1 scores across both datasets. A comprehensive ablation study has been performed, and the results show the superior performance of the proposed models.
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