MULTI-VIEW MAMMOGRAPHIC BREAST CANCER DETECTION USING DEEP LEARNING: A COMPREHENSIVE REVIEW OF FUSION, CROSS-VIEW CONSISTENCY, AND UNCERTAINTY METHODS

Sreeji K B; Dr. R. Khanchana

doi:10.69980/bs.v12i1.6709

Sreeji K B Research Scholar, Sri Ramakrishna College of Arts and Science for Women, Coimbatore
Dr. R. Khanchana Associate Professor, Sri Ramakrishna College of Arts and Science.

DOI: https://doi.org/10.69980/bs.v12i1.6709

Keywords: Multi-view mammography, Breast cancer detection, Cross-view consistency, Bayesian uncertainty quantification, Attention mechanism, Deep learning

Abstract

Breast cancer is currently among the primary causes of cancer-related mortality in women worldwide, and mammographic screening enables earlier detection of the disease, which plays a central role in enhancing survival outcomes. Standard screening protocols acquire craniocaudal (CC) and mediolateral oblique (MLO) projections, but the majority of deep learning systems process these views independently and without regard to the complementary diagnostic value that multi-view examination provides. This is a systematic review of deep learning methods in multi-view mammographic breast cancer detection, which discusses four interconnected themes: single-view CNN architectures and their inherent limitations, multi-view fusion strategies ranging from simple concatenation to cross-view attention mechanisms, cross-view consistency enforcement through dedicated loss formulations, and Bayesian uncertainty quantification methods including Monte Carlo dropout, deep ensembles and evidential learning. Surveyed benchmark datasets and evaluation protocols include RSNA, DDSM, MIAS, and VinDr-Mammo. Other emerging directions, such as transformer-based multi-view models, vision-language pretraining, and explainability by gradient-weighted visualisations, are also addressed. The main open challenges, especially dense tissue detection, calibration quality, and generalisation across imaging centres, are identified, and future research directions are outlined.

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References

1. Abdelrahman, L., Al Ghamdi, M., Collado-Mesa, F., & Abdel-Mottaleb, M. (2021). Convolutional neural networks for breast cancer detection in mammography: A survey. Computers in biology and medicine, 131, 104248.
2. Abdikenov, B., Zhaksylyk, T., Imasheva, A., Orazayev, Y., & Karibekov, T. (2025). Innovative Multi-View Strategies for AI-Assisted Breast Cancer Detection in Mammography. Journal of Imaging, 11(8), 247.
3. Al-Antari, M. A., Han, S. M., & Kim, T. S. (2020). Evaluation of deep learning detection and classification towards computer-aided diagnosis of breast lesions in digital X-ray mammograms. Computer methods and programs in biomedicine, 196, 105584.
4. Al-Dhabyani, W., Gomaa, M., Khaled, H., & Fahmy, A. (2020). Dataset of breast ultrasound images. Data in brief, 28, 104863.
5. Ayana, G., Dese, K., Dereje, Y., Kebede, Y., Barki, H., Amdissa, D., ... & Choe, S. W. (2023). Vision-transformer-based transfer learning for mammogram classification. Diagnostics, 13(2), 178.
6. Ayana, G., Park, J., Jeong, J. W., & Choe, S. W. (2022). A novel multistage transfer learning for ultrasound breast cancer image classification. Diagnostics, 12(1), 135.
7. Bannur, S., Hyland, S., Liu, Q., Perez-Garcia, F., Ilse, M., Castro, D. C., ... & Oktay, O. (2023). Learning to exploit temporal structure for biomedical vision-language processing. In Proceedings of the IEEE/CVF conference on computer vision and pattern recognition (pp. 15016-15027).
8. Begoli, E., Bhattacharya, T., & Kusnezov, D. (2019). The need for uncertainty quantification in machine-assisted medical decision making. Nature Machine Intelligence, 1(1), 20-23.
9. Buda, M., Maki, A., & Mazurowski, M. A. (2018). A systematic study of the class imbalance problem in convolutional neural networks. Neural networks, 106, 249-259.
10. Carneiro, G., Nascimento, J., & Bradley, A. P. (2017). Automated analysis of unregistered multi-view mammograms with deep learning. IEEE transactions on medical imaging, 36(11), 2355-2365.
11. Carriero, A., Groenhoff, L., Vologina, E., Basile, P., & Albera, M. (2024). Deep learning in breast cancer imaging: state of the art and recent advancements in early 2024. Diagnostics, 14(8), 848.
12. Chattopadhay, A., Sarkar, A., Howlader, P., & Balasubramanian, V. N. (2018, March). Grad-cam++: Generalized gradient-based visual explanations for deep convolutional networks. In 2018 IEEE winter conference on applications of computer vision (WACV) (pp. 839-847). IEEE.
13. Chen, H., & Martel, A. L. (2025, September). Breast Cancer Detection from Multi-view Screening Mammograms with Visual Prompt Tuning. In Deep Breast Workshop on AI and Imaging for Diagnostic and Treatment Challenges in Breast Care (pp. 91-100). Cham: Springer Nature Switzerland.
14. Chen, H., Li, Y., Zhang, J., Yang, L., Sun, Y., Chen, Y., ... & Shen, D. (2025). An Alignment and Imputation Network (AINet) for Breast Cancer Diagnosis with Multimodal Multi-view Ultrasound Images. IEEE Transactions on Medical Imaging.
15. Chen, X., Li, Y., Hu, M., Salari, E., Chen, X., Qiu, R. L., ... & Yang, X. (2026). Leveraging pretrained vision‐language model for enhanced breast cancer diagnosis with multi‐view mammography. Medical Physics, 53(1), e70261.
16. Chen, Y., Partridge, G. J., Vazirabad, M., Ball, R. L., Trivedi, H. M., Kitamura, F. C., ... & Moy, L. (2025). Performance of algorithms submitted in the 2023 RSNA screening mammography breast cancer detection AI challenge. Radiology, 316(2), e241447.
17. Chen, Y., Wang, H., Wang, C., Tian, Y., Liu, F., Liu, Y., ... & Carneiro, G. (2022, September). Multi-view local co-occurrence and global consistency learning improve mammogram classification generalisation. In International Conference on Medical Image Computing and Computer-Assisted Intervention (pp. 3-13). Cham: Springer Nature Switzerland.
18. Chen, Y., Wang, P., Zeng, J., Tan, M., Shan, K., Nie, L., ... & Wang, T. (2026). MGScreener: A multi-view mammography-based model optimized with active learning for breast cancer diagnosis. Talanta, 129345.
19. Dembrower, K., Liu, Y., Azizpour, H., Eklund, M., Smith, K., Lindholm, P., & Strand, F. (2020). Comparison of a deep learning risk score and standard mammographic density score for breast cancer risk prediction. Radiology, 294(2), 265-272.
20. Dosovitskiy, A., Beyer, L., Kolesnikov, A., Weissenborn, D., Zhai, X., Unterthiner, T., ... & Houlsby, N. (2020). An image is worth 16x16 words: Transformers for image recognition at scale. arXiv preprint arXiv:2010.11929.
21. Elumalai, S., & Surendran, R. (2025, December). MBLC-Net: A Multiview Breast Lesion Characterization Network with Cross-View Feature Fusion and Region-Attentive Segmentation. In 2025 International Conference on NexGen Networks and Cybernetics (IC2NC) (pp. 642-648). IEEE.
22. Gal, Y., & Ghahramani, Z. (2016, June). Dropout as a bayesian approximation: Representing model uncertainty in deep learning. In international conference on machine learning (pp. 1050-1059). PMLR.
23. Garrucho, L., Kushibar, K., Osuala, R., Diaz, O., Catanese, A., Del Riego, J., ... & Lekadir, K. (2023). High-resolution synthesis of high-density breast mammograms: Application to improved fairness in deep learning based mass detection. Frontiers in oncology, 12, 1044496.
24. Geras, K. J., Wolfson, S., Shen, Y., Wu, N., Kim, S., Kim, E., ... & Cho, K. (2017). High-resolution breast cancer screening with multi-view deep convolutional neural networks. arXiv preprint arXiv:1703.07047.
25. Ghosh, S., Poynton, C. B., Visweswaran, S., & Batmanghelich, K. (2024, October). Mammo-clip: A vision language foundation model to enhance data efficiency and robustness in mammography. In International conference on medical image computing and computer-assisted intervention (pp. 632-642). Cham: Springer Nature Switzerland.
26. Guan, S., & Loew, M. (2019). Breast cancer detection using synthetic mammograms from generative adversarial networks in convolutional neural networks. Journal of Medical Imaging, 6(3), 031411-031411.
27. Gudhe, N. R., Mazen, S., Sund, R., Kosma, V. M., Behravan, H., & Mannermaa, A. (2024). A multi-view deep evidential learning approach for mammogram density classification. IEEE Access, 12, 67889-67909.
28. Guo, C., Pleiss, G., Sun, Y., & Weinberger, K. Q. (2017, July). On calibration of modern neural networks. In International conference on machine learning (pp. 1321-1330). PMLR.
29. Haibe-Kains, B., Adam, G. A., Hosny, A., Khodakarami, F., Massive Analysis Quality Control (MAQC) Society Board of Directors Shraddha Thakkar 35 Kusko Rebecca 36 Sansone Susanna-Assunta 37 Tong Weida 35 Wolfinger Russ D. 38 Mason Christopher E. 39 Jones Wendell 40 Dopazo Joaquin 41 Furlanello Cesare 42, Waldron, L., ... & Aerts, H. J. (2020). Transparency and reproducibility in artificial intelligence. Nature, 586(7829), E14-E16.
30. He, K., Zhang, X., Ren, S., & Sun, J. (2016). Deep residual learning for image recognition. In Proceedings of the IEEE conference on computer vision and pattern recognition (pp. 770-778).
31. Huang, G., Liu, Z., Van Der Maaten, L., & Weinberger, K. Q. (2017). Densely connected convolutional networks. In Proceedings of the IEEE conference on computer vision and pattern recognition (pp. 4700-4708).
32. Hussain, S., Teevno, M. A., Naseem, U., Avalos, D. B. A., Cardona-Huerta, S., & Tamez-Pena, J. G. (2024). Multiview multimodal feature fusion for breast cancer classification using deep learning. IEEE Access, 13, 9265-9275.
33. Huynh, B. Q., Li, H., & Giger, M. L. (2016). Digital mammographic tumor classification using transfer learning from deep convolutional neural networks. Journal of Medical Imaging, 3(3), 034501-034501.
34. Isosalo, A., Inkinen, S. I., Turunen, T., Ipatti, P. S., Reponen, J., & Nieminen, M. T. (2023). Independent evaluation of a multi-view multi-task convolutional neural network breast cancer classification model using Finnish mammography screening data. Computers in Biology and Medicine, 161, 107023.
35. Jeny, A. A., Hamzehei, S., Jin, A., Baker, S. A., Van Rathe, T., Bai, J., ... & Nabavi, S. (2025). Hybrid transformer‐based model for mammogram classification by integrating prior and current images. Medical Physics, 52(5), 2999-3014.
36. Jeong, J. J., Vey, B. L., Bhimireddy, A., Kim, T., Santos, T., Correa, R., ... & Trivedi, H. (2023). The EMory BrEast imaging Dataset (EMBED): A racially diverse, granular dataset of 3.4 million screening and diagnostic mammographic images. Radiology: Artificial Intelligence, 5(1), e220047.
37. Jones, M. A., Sadeghipour, N., Chen, X., Islam, W., & Zheng, B. (2023). A multi‐stage fusion framework to classify breast lesions using deep learning and radiomics features computed from four‐view mammograms. Medical physics, 50(12), 7670-7683.
38. Kelly, C. J., Karthikesalingam, A., Suleyman, M., Corrado, G., & King, D. (2019). Key challenges for delivering clinical impact with artificial intelligence. BMC medicine, 17(1), 195.
39. Kendall, A., & Gal, Y. (2017). What uncertainties do we need in bayesian deep learning for computer vision?. Advances in neural information processing systems, 30.
40. Kurz, A., Hauser, K., Mehrtens, H. A., Krieghoff-Henning, E., Hekler, A., Kather, J. N., ... & Brinker, T. J. (2022). Uncertainty estimation in medical image classification: systematic review. JMIR Medical Informatics, 10(8), e36427.
41. Lakshminarayanan, B., Pritzel, A., & Blundell, C. (2017). Simple and scalable predictive uncertainty estimation using deep ensembles. Advances in neural information processing systems, 30.
42. Lee, R. S., Gimenez, F., Hoogi, A., Miyake, K. K., Gorovoy, M., & Rubin, D. L. (2017). A curated mammography data set for use in computer-aided detection and diagnosis research. Scientific data, 4(1), 170177.
43. Li, Z., Cui, Z., Wang, S., Qi, Y., Ouyang, X., Chen, Q., ... & Cheng, J. Z. (2021, September). Domain generalization for mammography detection via multi-style and multi-view contrastive learning. In International conference on medical image computing and computer-assisted intervention (pp. 98-108). Cham: Springer International Publishing.
44. Li, Z., Cui, Z., Zhang, L., Wang, S., Lei, C., Ouyang, X., ... & Cheng, J. Z. (2025). Domain generalization for mammographic image analysis with contrastive learning. Computers in Biology and Medicine, 185, 109455.
45. Lin, T. Y., Goyal, P., Girshick, R., He, K., & Dollár, P. (2017). Focal loss for dense object detection. In Proceedings of the IEEE international conference on computer vision (pp. 2980-2988).
46. Liu, Y., Zhang, F., Chen, C., Wang, S., Wang, Y., & Yu, Y. (2021). Act like a radiologist: towards reliable multi-view correspondence reasoning for mammogram mass detection. IEEE Transactions on Pattern Analysis and Machine Intelligence, 44(10), 5947-5961.
47. Lopez, E., Betello, F., Carmignani, F., Grassucci, E., & Comminiello, D. (2024). Attention-map augmentation for hypercomplex breast cancer classification. Pattern Recognition Letters, 182, 140-146.
48. Lotter, W., Diab, A. R., Haslam, B., Kim, J. G., Grisot, G., Wu, E., ... & Gregory Sorensen, A. (2021). Robust breast cancer detection in mammography and digital breast tomosynthesis using an annotation-efficient deep learning approach. Nature medicine, 27(2), 244-249.
49. Manigrasso, F., Milazzo, R., Russo, A. S., Lamberti, F., Strand, F., Pagnani, A., & Morra, L. (2025). Mammography classification with multi-view deep learning techniques: Investigating graph and transformer-based architectures. Medical Image Analysis, 99, 103320.
50. Mann, R. M., Athanasiou, A., Baltzer, P. A., Camps-Herrero, J., Clauser, P., Fallenberg, E. M., ... & European Society of Breast Imaging (EUSOBI). (2022). Breast cancer screening in women with extremely dense breasts recommendations of the European Society of Breast Imaging (EUSOBI). European radiology, 32(6), 4036-4045.
51. McKinney, S. M., Sieniek, M., Godbole, V., et al. (2020). International evaluation of an AI system for breast cancer screening. Nature, 577, 89–94.
52. Monticciolo, D. L., Malak, S. F., Friedewald, S. M., Eby, P. R., Newell, M. S., Moy, L., ... & Smetherman, D. (2021). Breast cancer screening recommendations inclusive of all women at average risk: update from the ACR and Society of Breast Imaging. Journal of the American College of Radiology, 18(9), 1280-1288.
53. Moor, M., Banerjee, O., Abad, Z. S. H., Krumholz, H. M., Leskovec, J., Topol, E. J., & Rajpurkar, P. (2023). Foundation models for generalist medical artificial intelligence. Nature, 616(7956), 259-265.
54. Naeini, M. P., Cooper, G., & Hauskrecht, M. (2015, February). Obtaining well calibrated probabilities using bayesian binning. In Proceedings of the AAAI conference on artificial intelligence (Vol. 29, No. 1).
55. Nair, T., Precup, D., Arnold, D. L., & Arbel, T. (2020). Exploring uncertainty measures in deep networks for multiple sclerosis lesion detection and segmentation. Medical image analysis, 59, 101557.
56. Nguyen, H. T., Nguyen, H. Q., Pham, H. H., Lam, K., Le, L. T., Dao, M., & Vu, V. (2023). VinDr-Mammo: A large-scale benchmark dataset for computer-aided diagnosis in full-field digital mammography. Scientific Data, 10(1), 277.
57. Nguyen, H. T., Tran, S. B., Nguyen, D. B., Pham, H. H., & Nguyen, H. Q. (2022, July). A novel multi-view deep learning approach for BI-RADS and density assessment of mammograms. In 2022 44th Annual international conference of the IEEE engineering in medicine & biology society (EMBC) (pp. 2144-2148). IEEE.
58. Niu, Z., Zhong, G., & Yu, H. (2021). A review on the attention mechanism of deep learning. Neurocomputing, 452, 48-62.
59. Nixon, J., Dusenberry, M. W., Zhang, L., Jerfel, G., & Tran, D. (2019, June). Measuring calibration in deep learning. In CVPR workshops (Vol. 2, No. 7).
60. Obermeyer, Z., & Emanuel, E. J. (2016). Predicting the future—big data, machine learning, and clinical medicine. The New England journal of medicine, 375(13), 1216.
61. Ovadia, Y., Fertig, E., Ren, J., Nado, Z., Sculley, D., Nowozin, S., ... & Snoek, J. (2019). Can you trust your model's uncertainty? evaluating predictive uncertainty under dataset shift. Advances in neural information processing systems, 32.
62. Panch, T., Szolovits, P., & Atun, R. (2018). Artificial intelligence, machine learning and health systems. Journal of global health, 8(2), 020303.
63. Perez, L., & Wang, J. (2017). The effectiveness of data augmentation in image classification using deep learning. arXiv preprint arXiv:1712.04621.
64. Radford, A., Kim, J. W., Hallacy, C., Ramesh, A., Goh, G., Agarwal, S., ... & Sutskever, I. (2021, July). Learning transferable visual models from natural language supervision. In International conference on machine learning (pp. 8748-8763). PmLR.
65. Radiological Society of North America. (2025). RSNA screening mammography breast cancer detection. GitHub. Retrieved February 4, 2025, from https://github.com/RSNA/AI-Challenge-Data/wiki/RSNA-Screening-Mammography-Breast-Cancer-Detection
66. Raghu, M., Zhang, C., Kleinberg, J., & Bengio, S. (2019). Transfusion: Understanding transfer learning for medical imaging. Advances in neural information processing systems, 32.
67. Rajpurkar, P., Chen, E., Banerjee, O., & Topol, E. J. (2022). AI in health and medicine. Nature medicine, 28(1), 31-38.
68. Ribli, D., Horváth, A., Unger, Z., Pollner, P., & Csabai, I. (2018). Detecting and classifying lesions in mammograms with deep learning. Scientific reports, 8(1), 4165.
69. Rieke, N., Hancox, J., Li, W., Milletari, F., Roth, H. R., Albarqouni, S., ... & Cardoso, M. J. (2020). The future of digital health with federated learning. NPJ digital medicine, 3(1), 119.
70. Salama, W. M., & Aly, M. H. (2021). Deep learning in mammography images segmentation and classification: Automated CNN approach. Alexandria Engineering Journal, 60(5), 4701-4709.
71. Schaffter, T., Buist, D. S. M., Lee, C. I., et al. (2020). Evaluation of combined artificial intelligence and radiologist assessment to interpret screening mammograms. JAMA Network Open, 3(3), e200265.
72. Selvaraju, R. R., Cogswell, M., Das, A., Vedantam, R., Parikh, D., & Batra, D. (2017). Grad-cam: Visual explanations from deep networks via gradient-based localization. In Proceedings of the IEEE international conference on computer vision (pp. 618-626).
73. Sensoy, M., Kaplan, L., & Kandemir, M. (2018). Evidential deep learning to quantify classification uncertainty. Advances in neural information processing systems, 31.
74. Seo, J. W., Kim, Y. J., & Kim, K. G. (2025). Leveraging paired mammogram views with deep learning for comprehensive breast cancer detection. Scientific Reports, 15(1), 4406.
75. Shamshad, F., Khan, S., Zamir, S. W., Khan, M. H., Hayat, M., Khan, F. S., & Fu, H. (2023). Transformers in medical imaging: A survey. Medical image analysis, 88, 102802.
76. Shen, L., Margolies, L. R., Rothstein, J. H., Fluder, E., McBride, R., & Sieh, W. (2019). Deep learning to improve breast cancer detection on screening mammography. Scientific reports, 9(1), 12495.
77. Shorten, C., & Khoshgoftaar, T. M. (2019). A survey on image data augmentation for deep learning. Journal of big data, 6(1), 1-48.
78. Siegel, R. L., Miller, K. D., Wagle, N. S., & Jemal, A. (2023). Cancer statistics, 2023. CA: A Cancer Journal for Clinicians, 73(1), 17–48.
79. Sprague, B. L., Gangnon, R. E., Burt, V., Trentham-Dietz, A., Hampton, J. M., Wellman, R. D., ... & Miglioretti, D. L. (2014). Prevalence of mammographically dense breasts in the United States. Journal of the National Cancer Institute, 106(10), dju255.
80. Su, C., Gong, Z., & Cao, J. (2025). Multi-view co-occurrence and dual-modality framework for breast cancer classification. Journal of King Saud University Computer and Information Sciences, 37(5), 78.
81. Suckling, J. (1994). The mammographic images analysis society digital mammogram database. In Exerpta Medica. International Congress Series, 1994 (Vol. 1069, pp. 375-378).
82. Sung, H., Ferlay, J., Siegel, R. L., Laversanne, M., Soerjomataram, I., Jemal, A., & Bray, F. (2021). Global cancer statistics 2020: GLOBOCAN estimates of incidence and mortality worldwide for 36 cancers in 185 countries. CA: A Cancer Journal for Clinicians, 71(3), 209–249.
83. Tajbakhsh, N., Shin, J. Y., Gurudu, S. R., Hurst, R. T., Kendall, C. B., Gotway, M. B., & Liang, J. (2016). Convolutional neural networks for medical image analysis: Full training or fine tuning?. IEEE transactions on medical imaging, 35(5), 1299-1312.
84. Tan, H., Wu, Q., Wu, Y., Zheng, B., Wang, B., Chen, Y., ... & Wang, M. (2025). Mammography-based artificial intelligence for breast cancer detection, diagnosis, and BI-RADS categorization using multi-view and multi-level convolutional neural networks. Insights into Imaging, 16(1), 109.
85. Tian, R., Zhang, C., Jiang, W., Li, C., Yu, Z., Liu, W., ... & Liu, B. (2026). Cross-difference-driven dual-stream contrast multi-view network for mammogram classification. Multimedia Systems, 32(3), 179.
86. Tian, Y., Xu, Z., Ma, Y., et al. (2025). Survey on deep learning in multimodal medical imaging for cancer detection. Neural Computing & Applications, 37, 22239–22254.
87. Tjoa, E., & Guan, C. (2020). A survey on explainable artificial intelligence (xai): Toward medical xai. IEEE transactions on neural networks and learning systems, 32(11), 4793-4813.
88. Topol, E. J. (2019). High-performance medicine: the convergence of human and artificial intelligence. Nature medicine, 25(1), 44-56.
89. Van der Velden, B. H., Kuijf, H. J., Gilhuijs, K. G., & Viergever, M. A. (2022). Explainable artificial intelligence (XAI) in deep learning-based medical image analysis. Medical image analysis, 79, 102470.
90. Vaswani, A., Shazeer, N., Parmar, N., Uszkoreit, J., Jones, L., Gomez, A. N., ... & Polosukhin, I. (2017). Attention is all you need. Advances in neural information processing systems, 30.
91. Walton, W. C., Kim, S. J., & Mullen, L. A. (2022). Automated registration for dual-view x-ray mammography using convolutional neural networks. IEEE Transactions on Biomedical Engineering, 69(11), 3538-3550.
92. Wang, L. (2024). Mammography with deep learning for breast cancer detection. Frontiers in Oncology, 14, 1281922.
93. Wen, X., Li, J., & Yang, L. (2024). Breast cancer diagnosis method based on cross-mammogram four-view interactive learning. Tomography, 10(6), 848-868.
94. Woo, S., Park, J., Lee, J. Y., & Kweon, I. S. (2018). Cbam: Convolutional block attention module. In Proceedings of the European conference on computer vision (ECCV) (pp. 3-19).
95. Wu, N., Phang, J., Park, J., Shen, Y., Huang, Z., Zorin, M., ... & Geras, K. J. (2019). Deep neural networks improve radiologists’ performance in breast cancer screening. IEEE transactions on medical imaging, 39(4), 1184-1194.
96. Xia, L., An, J., Ma, C., Hou, H., Hou, Y., Cui, L., ... & Gao, Z. (2023). Neural network model based on global and local features for multi-view mammogram classification. Neurocomputing, 536, 21-29.
97. Yala, A., Mikhael, P. G., Strand, F., Lin, G., Satuluru, S., Kim, T., ... & Barzilay, R. (2022). Multi-institutional validation of a mammography-based breast cancer risk model. Journal of Clinical Oncology, 40(16), 1732-1740.
98. Yang, S., Zhang, C., Zang, Q., Yu, J., Zeng, L., Luo, X., ... & Xie, Y. (2024). Mammo-Clustering: A Multi-views Tri-level Information Fusion Context Clustering Framework for Localization and Classification in Mammography. arXiv preprint arXiv:2409.14876.
99. Zhao, H., Zhang, C., Wang, F., Li, Z., & Gao, S. (2025). Paradigm-Shifting Attention-based hybrid view learning for enhanced mammography breast cancer classification with Multi-Scale and Multi-View fusion. IEEE Journal of Biomedical and Health Informatics.
100. Zhao, X., Yu, L., & Wang, X. (2020, May). Cross-view attention network for breast cancer screening from multi-view mammograms. In ICASSP 2020-2020 IEEE international conference on acoustics, speech and signal processing (ICASSP) (pp. 1050-1054). IEEE.
101. Zheng, S. F., Lee, H., Kooi, T., & Diba, A. (2025). MV-MLM: Bridging Multi-View Mammography and Language for Breast Cancer Diagnosis and Risk Prediction. In Proceedings of the IEEE/CVF International Conference on Computer Vision (pp. 1213-1222).

MULTI-VIEW MAMMOGRAPHIC BREAST CANCER DETECTION USING DEEP LEARNING: A COMPREHENSIVE REVIEW OF FUSION, CROSS-VIEW CONSISTENCY, AND UNCERTAINTY METHODS

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