Human-Machine Interactive Tissue Prototype Learning for Label-Efficient Histopathology Image Segmentation
Authors: 
Wentao Pan, Jiangpeng Yan, Hanbo Chen, Jiawei Yang, Zhe Xu, Xiu Li, Jianhua YaoAuthors Info & Claims
Pages 679 - 691
Abstract
Deep learning have greatly advanced histopathology image segmentation but usually require abundant annotated data. However, due to the gigapixel scale of whole slide images and pathologists’ heavy daily workload, obtaining pixel-level labels for supervised learning in clinical practice is often infeasible. Alternatively, weakly-supervised segmentation methods have been explored with less laborious image-level labels, but their performance is unsatisfactory due to the lack of dense supervision. Inspired by the recent success of self-supervised learning, we present a label-efficient tissue prototype dictionary building pipeline and propose to use the obtained prototypes to guide histopathology image segmentation. Particularly, taking advantage of self-supervised contrastive learning, an encoder is trained to project the unlabeled histopathology image patches into a discriminative embedding space where these patches are clustered to identify the tissue prototypes by efficient pathologists’ visual examination. Then, the encoder is used to map the images into the embedding space and generate pixel-level pseudo tissue masks by querying the tissue prototype dictionary. Finally, the pseudo masks are used to train a segmentation network with dense supervision for better performance. Experiments on two public datasets demonstrate that our method can achieve comparable segmentation performance as the fully-supervised baselines with less annotation burden and outperform other weakly-supervised methods. Codes are available at https://github.com/WinterPan2017/proto2seg.
References
[1]
Amgad M, Elfandy H, et al. Structured crowdsourcing enables convolutional segmentation of histology images Bioinformatics 2019 35 18 3461-3467
[2]
Arthur, D., Vassilvitskii, S.: K-means++: the advantages of careful seeding. In: SODA, pp. 1027–1035 (2007)
[3]
Bejnordi BE et al. Diagnostic assessment of deep learning algorithms for detection of lymph node metastases in women with breast cancer JAMA 2017 318 22 2199-2210
[4]
Chan, L., Hosseini, M.S., Rowsell, C., et al.: HistoSegNet: semantic segmentation of histological tissue type in whole slide images. In: ICCV, pp. 10662–10671 (2019)
[5]
Chattopadhay, A., Sarkar, A., et al.: Grad-CAM++: generalized gradient-based visual explanations for deep convolutional networks. In: WACV, pp. 839–847 (2018)
[6]
Chaurasia, A., Culurciello, E.: LinkNet: exploiting encoder representations for efficient semantic segmentation. In: VCIP, pp. 1–4 (2017)
[7]
Chen, T., Kornblith, S., Norouzi, M., Hinton, G.: A simple framework for contrastive learning of visual representations. In: ICML, pp. 1597–1607 (2020)
[8]
Ester, M., Kriegel, H.P., Sander, J., et al.: A density-based algorithm for discovering clusters in large spatial databases with noise. In: KDD, vol. 96, pp. 226–231 (1996)
[9]
Grill, J.B., Strub, F., Altché, F., et al.: Bootstrap your own latent-a new approach to self-supervised learning. In: NeurIPS, pp. 21271–21284 (2020)
[10]
He, K., Fan, H., Wu, Y., Xie, S., Girshick, R.: Momentum contrast for unsupervised visual representation learning. In: CVPR, pp. 9729–9738 (2020)
[11]
He, K., Zhang, X., Ren, S., Sun, J.: Deep residual learning for image recognition. In: CVPR, pp. 770–778 (2016)
[12]
Ilse, M., Tomczak, J., Welling, M.: Attention-based deep multiple instance learning. In: ICML, pp. 2127–2136 (2018)
[13]
Liu F and Deng Y Determine the number of unknown targets in open world based on elbow method IEEE Trans. Fuzzy Syst. 2020 29 5 986-995
[14]
Lu MY et al. Data-efficient and weakly supervised computational pathology on whole-slide images Nat. Biomed. Eng. 2021 5 6 555-570
[15]
Sarfraz, S., Sharma, V., Stiefelhagen, R.: Efficient parameter-free clustering using first neighbor relations. In: CVPR, pp. 8934–8943 (2019)
[16]
Selvaraju, R.R., Cogswell, M., Das, A., et al.: Grad-CAM: visual explanations from deep networks via gradient-based localization. In: ICCV, pp. 618–626 (2017)
[17]
Xu, G., Song, Z., Sun, Z., et al.: CAMEL: a weakly supervised learning framework for histopathology image segmentation. In: CVPR, pp. 10682–10691 (2019)
[18]
Xu Z, Lu D, Luo J, et al. Anti-interference from noisy labels: mean-teacher-assisted confident learning for medical image segmentation IEEE Trans. Med. Imaging 2022 41 11 3062-3073
[19]
Xu Z, et al., et al. de Bruijne M, et al., et al. Noisy labels are treasure: mean-teacher-assisted confident learning for hepatic vessel segmentation Medical Image Computing and Computer Assisted Intervention – MICCAI 2021 2021 Cham Springer 3-13
[20]
Xu Z et al. Wang L, Dou Q, Fletcher PT, Speidel S, Li S, et al. Denoising for relaxing: unsupervised domain adaptive fundus image segmentation without source data Medical Image Computing and Computer Assisted Intervention - MICCAI 2022 2022 Cham Springer 214-224
[21]
Yan, J., Chen, H., Li, X., Yao, J.: Deep contrastive learning based tissue clustering for annotation-free histopathology image analysis. Comput. Med. Imaging Graph. 97, 102053 (2022)
[22]
Yang, J., et al.: Towards better understanding and better generalization of low-shot classification in histology images with contrastive learning. In: ICLR (2022)
[23]
Yang P, Hong Z, Yin X, Zhu C, Jiang R, et al. de Bruijne M et al. Self-supervised visual representation learning for histopathological images Medical Image Computing and Computer Assisted Intervention – MICCAI 2021 2021 Cham Springer 47-57
[24]
Zhou, B., Khosla, A., Lapedriza, A., Oliva, A., Torralba, A.: Learning deep features for discriminative localization. In: CVPR, pp. 2921–2929 (2016)
Recommendations
Weakly Supervised Random Forest for Multi-Label Image Clustering and Segmentation
ICMR '15: Proceedings of the 5th ACM on International Conference on Multimedia RetrievalClustering is a useful statistical tool in data mining and computer vision. Supervised information is introduced to improve the clustering performance. However, labeling each piece of data accurately is extremely expensive when the amount of data is ...
Transductive Multilabel Learning via Label Set Propagation
The problem of multilabel classification has attracted great interest in the last decade, where each instance can be assigned with a set of multiple class labels simultaneously. It has a wide variety of real-world applications, e.g., automatic image ...
Semi-Supervised Unpaired Multi-Modal Learning for Label-Efficient Medical Image Segmentation
Medical Image Computing and Computer Assisted Intervention – MICCAI 2021AbstractMulti-modal learning using unpaired labeled data from multiple modalities to boost the performance of deep learning models on each individual modality has attracted a lot of interest in medical image segmentation recently. However, existing ...
Comments
Please enable JavaScript to view thecomments powered by Disqus.Information & Contributors
Information
Published In
Jun 2023
835 pages
ISBN:978-3-031-34047-5
DOI:10.1007/978-3-031-34048-2
© The Author(s), under exclusive license to Springer Nature Switzerland AG 2023.
Publisher
Springer-Verlag
Berlin, Heidelberg
Publication History
Published: 12 June 2023
Author Tags
Qualifiers
- Article
Contributors
Other Metrics
Bibliometrics & Citations
Bibliometrics
Article Metrics
- 0Total Citations
- 0Total Downloads
- Downloads (Last 12 months)0
- Downloads (Last 6 weeks)0
Reflects downloads up to 20 Nov 2024
Other Metrics
Citations
View Options
View options
Login options
Check if you have access through your login credentials or your institution to get full access on this article.
Sign in