Recurrence prediction of gastric cancer based on multi-resolution feature fusion and context information_Journal of Biomedical Engineering

Authors：

ZHOU Hongyu ^1,2 , TAO Haibo ³ , XUE Feiyue ^1,2 , WANG Bin ^1,2 ,  JIN Huaiping ^1,2 , LI Zhenhui ³

1. Faculty of Information Engineering and Automation, Kunming University of Science and Technology, Kunming 650500, P. R. China;
2. Yunnan Key Laboratory of Artificial Intelligence, Kunming 650500, P. R. China;
3. Department of Radiology, Yunnan Cancer Hospital, Kunming 650118, P. R. China;

Corresponding author：

JIN Huaiping, Email: jinhuaiping@126.com

Keywords：

Pathological image of gastric cancer; Recurrence prediction; Deep learning; Feature fusion; Context information

DOI：

10.7507/1001-5515.202403014

Video：

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Pathological images of gastric cancer serve as the gold standard for diagnosing this malignancy. However, the recurrence prediction task often encounters challenges such as insignificant morphological features of the lesions, insufficient fusion of multi-resolution features, and inability to leverage contextual information effectively. To address these issues, a three-stage recurrence prediction method based on pathological images of gastric cancer is proposed. In the first stage, the self-supervised learning framework SimCLR was adopted to train low-resolution patch images, aiming to diminish the interdependence among diverse tissue images and yield decoupled enhanced features. In the second stage, the obtained low-resolution enhanced features were fused with the corresponding high-resolution unenhanced features to achieve feature complementation across multiple resolutions. In the third stage, to address the position encoding difficulty caused by the large difference in the number of patch images, we performed position encoding based on multi-scale local neighborhoods and employed self-attention mechanism to obtain features with contextual information. The resulting contextual features were further combined with the local features extracted by the convolutional neural network. The evaluation results on clinically collected data showed that, compared with the best performance of traditional methods, the proposed network provided the best accuracy and area under curve (AUC), which were improved by 7.63% and 4.51%, respectively. These results have effectively validated the usefulness of this method in predicting gastric cancer recurrence.

Citation： ZHOU Hongyu, TAO Haibo, XUE Feiyue, WANG Bin, JIN Huaiping, LI Zhenhui. Recurrence prediction of gastric cancer based on multi-resolution feature fusion and context information. Journal of Biomedical Engineering, 2024, 41(5): 886-894. doi: 10.7507/1001-5515.202403014 Copy

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20.	Chen T, Kornblith S, Norouzi M, et al. A simple framework for contrastive learning of visual representations// International Conference on Machine Learning (ICML). Online: PMLR, 2020: 1597-1607.
21.	Tan M, Le Q. Efficientnetv2: Smaller models and faster training// International Conference on Machine Learning. Online: PMLR, 2021: 10096-10106.
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1. Sung H, Ferlay J, Siegel R L, et al. Global cancer statistics 2020: GLOBOCAN estimates of incidence and mortality worldwide for 36 cancers in 185 countries. CA Cancer J Clin, 2021, 71(3): 209-249.
2. Zheng R, Zhang S, Zeng H, et al. Cancer incidence and mortality in China, 2016. J Natl Cancer Cent, 2022, 2(1): 1-9.
3. Rohatgi P R, Yao J C, Hess K, et al. Outcome of gastric cancer patients after successful gastrectomy: influence of the type of recurrence and histology on survival. Cancer-AM Cancer SOC, 2006, 107(11): 2576-2580.
4. Gurcan M N, Boucheron L E, Can A, et al. Histopathological image analysis: A review. IEEE Rev Biomed Eng, 2009, 2: 147-171.
5. Srinidhi C L, Ciga O, Martel A L. Deep neural network models for computational histopathology: A survey. Med Image Anal, 2021, 67: 101813.
6. Krizhevsky A, Sutskever I, Hinton G E. Imagenet classification with deep convolutional neural networks// Advances in Neural Information Processing Systems (NeurIPS). Stateline: NeurIPS, 2012: 25.
7. He K, Zhang X, Ren S, et al. Deep residual learning for image recognition// Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR). Las Vegas: IEEE, 2016: 770-778.
8. Chen X, Wang X, Zhang K, et al. Recent advances and clinical applications of deep learning in medical image analysis. Med Image Anal, 2022, 79: 102444.
9. 卜菊, 聂生东, 魏珑. 肺腺癌 CT 影像分子分型研究进展. 中国图象图形学报, 2022, 27(11): 3160-3171.
10. Kora P, Ooi C P, Faust O, et al. Transfer learning techniques for medical image analysis: A review. Biocybern Biomed Eng, 2022, 42(1): 79-107.
11. Laleh N G, Muti H S, Loeffler C M L, et al. Benchmarking weakly-supervised deep learning pipelines for whole slide classification in computational pathology. Med Image Anal, 2022, 79: 102474.
12. Campanella G, Hanna M G, Geneslaw L, et al. Clinical-grade computational pathology using weakly supervised deep learning on whole slide images. Nat Med, 2019, 25(8): 1301-1309.
13. 于凌涛, 夏永强, 闫昱晟, 等. 利用卷积神经网络分类乳腺癌病理图像. 哈尔滨工程大学学报, 2021, 42(4): 567-573.
14. 金怀平, 薛飞跃, 李振辉, 等. 基于病理图像集成深度学习的胃癌预后预测方法. 电子与信息学报, 2023, 45(7): 2623-2633.
15. Ilse M, Tomczak J, Welling M. Attention-based deep multiple instance learning// International Conference on Machine Learning (ICML). Stockholm: PMLR, 2018: 2127-2136.
16. Li B, Li Y, Eliceiri K W. Dual-stream multiple instance learning network for whole slide image classification with self-supervised contrastive learning// Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR). Beijing: IEEE, 2021: 14318-14328.
17. Lu M Y, Williamson D F K, Chen T Y, et al. Data-efficient and weakly supervised computational pathology on whole-slide images. Nat Biomed Eng, 2021, 5(6): 555-570.
18. Shao Z, Bian H, Chen Y, et al. Transmil: Transformer based correlated multiple instance learning for whole slide image classification// Advances in Neural Information Processing Systems (NeurIPS). Online: NeurIPS, 2021, 34: 2136-2147.
19. Deng J, Dong W, Socher R, et al. Imagenet: A large-scale hierarchical image database// 2009 IEEE Conference on Computer Vision and Pattern Recognition (CVPR). Miami: IEEE, 2009: 248-255.
20. Chen T, Kornblith S, Norouzi M, et al. A simple framework for contrastive learning of visual representations// International Conference on Machine Learning (ICML). Online: PMLR, 2020: 1597-1607.
21. Tan M, Le Q. Efficientnetv2: Smaller models and faster training// International Conference on Machine Learning. Online: PMLR, 2021: 10096-10106.
22. Chu X, Tian Z, Zhang B, et al. Conditional positional encodings for vision transformers. arXiv preprint arXiv, 2021: 2102.10882.
23. Dosovitskiy A, Beyer L, Kolesnikov A, et al. An image is worth 16x16 words: Transformers for image recognition at scale. arXiv preprint arXiv, 2020: 2010.11929.

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