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Compound Figure Separation of Biomedical Images: Mining Large Datasets for Self-supervised Learning

With the rapid development of self-supervised learning (e.g., contrastive learning), the importance of having large-scale images (even without annotations) for training a more generalizable AI model has been widely recognized in medical image analysis. However, collecting large-scale task-specific u...

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Autores principales: Yao, Tianyuan, Qu, Chang, Long, Jun, Liu, Quan, Deng, Ruining, Tian, Yuanhan, Xu, Jiachen, Jha, Aadarsh, Asad, Zuhayr, Bao, Shunxing, Zhao, Mengyang, Fogo, Agnes B., Landman, Bennett A., Yang, Haichun, Chang, Catie, Huo, Yuankai
Formato: Online Artículo Texto
Lenguaje:English
Publicado: 2022
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10112832/
https://www.ncbi.nlm.nih.gov/pubmed/37077404
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author Yao, Tianyuan
Qu, Chang
Long, Jun
Liu, Quan
Deng, Ruining
Tian, Yuanhan
Xu, Jiachen
Jha, Aadarsh
Asad, Zuhayr
Bao, Shunxing
Zhao, Mengyang
Fogo, Agnes B.
Landman, Bennett A.
Yang, Haichun
Chang, Catie
Huo, Yuankai
author_facet Yao, Tianyuan
Qu, Chang
Long, Jun
Liu, Quan
Deng, Ruining
Tian, Yuanhan
Xu, Jiachen
Jha, Aadarsh
Asad, Zuhayr
Bao, Shunxing
Zhao, Mengyang
Fogo, Agnes B.
Landman, Bennett A.
Yang, Haichun
Chang, Catie
Huo, Yuankai
author_sort Yao, Tianyuan
collection PubMed
description With the rapid development of self-supervised learning (e.g., contrastive learning), the importance of having large-scale images (even without annotations) for training a more generalizable AI model has been widely recognized in medical image analysis. However, collecting large-scale task-specific unannotated data at scale can be challenging for individual labs. Existing online resources, such as digital books, publications, and search engines, provide a new resource for obtaining large-scale images. However, published images in healthcare (e.g., radiology and pathology) consist of a considerable amount of compound figures with subplots. In order to extract and separate compound figures into usable individual images for downstream learning, we propose a simple compound figure separation (SimCFS) framework without using the traditionally required detection bounding box annotations, with a new loss function and a hard case simulation. Our technical contribution is four-fold: (1) we introduce a simulation-based training framework that minimizes the need for resource extensive bounding box annotations; (2) we propose a new side loss that is optimized for compound figure separation; (3) we propose an intra-class image augmentation method to simulate hard cases; and (4) to the best of our knowledge, this is the first study that evaluates the efficacy of leveraging self-supervised learning with compound image separation. From the results, the proposed SimCFS achieved state-of-the-art performance on the ImageCLEF 2016 Compound Figure Separation Database. The pretrained self-supervised learning model using large-scale mined figures improved the accuracy of downstream image classification tasks with a contrastive learning algorithm. The source code of SimCFS is made publicly available at https://github.com/hrlblab/ImageSeperation.
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spelling pubmed-101128322023-04-18 Compound Figure Separation of Biomedical Images: Mining Large Datasets for Self-supervised Learning Yao, Tianyuan Qu, Chang Long, Jun Liu, Quan Deng, Ruining Tian, Yuanhan Xu, Jiachen Jha, Aadarsh Asad, Zuhayr Bao, Shunxing Zhao, Mengyang Fogo, Agnes B. Landman, Bennett A. Yang, Haichun Chang, Catie Huo, Yuankai J Mach Learn Biomed Imaging Article With the rapid development of self-supervised learning (e.g., contrastive learning), the importance of having large-scale images (even without annotations) for training a more generalizable AI model has been widely recognized in medical image analysis. However, collecting large-scale task-specific unannotated data at scale can be challenging for individual labs. Existing online resources, such as digital books, publications, and search engines, provide a new resource for obtaining large-scale images. However, published images in healthcare (e.g., radiology and pathology) consist of a considerable amount of compound figures with subplots. In order to extract and separate compound figures into usable individual images for downstream learning, we propose a simple compound figure separation (SimCFS) framework without using the traditionally required detection bounding box annotations, with a new loss function and a hard case simulation. Our technical contribution is four-fold: (1) we introduce a simulation-based training framework that minimizes the need for resource extensive bounding box annotations; (2) we propose a new side loss that is optimized for compound figure separation; (3) we propose an intra-class image augmentation method to simulate hard cases; and (4) to the best of our knowledge, this is the first study that evaluates the efficacy of leveraging self-supervised learning with compound image separation. From the results, the proposed SimCFS achieved state-of-the-art performance on the ImageCLEF 2016 Compound Figure Separation Database. The pretrained self-supervised learning model using large-scale mined figures improved the accuracy of downstream image classification tasks with a contrastive learning algorithm. The source code of SimCFS is made publicly available at https://github.com/hrlblab/ImageSeperation. 2022-08 2022-09-04 /pmc/articles/PMC10112832/ /pubmed/37077404 Text en https://creativecommons.org/licenses/by/4.0/License: CC-BY 4.0 (https://creativecommons.org/licenses/by/4.0/) .
spellingShingle Article
Yao, Tianyuan
Qu, Chang
Long, Jun
Liu, Quan
Deng, Ruining
Tian, Yuanhan
Xu, Jiachen
Jha, Aadarsh
Asad, Zuhayr
Bao, Shunxing
Zhao, Mengyang
Fogo, Agnes B.
Landman, Bennett A.
Yang, Haichun
Chang, Catie
Huo, Yuankai
Compound Figure Separation of Biomedical Images: Mining Large Datasets for Self-supervised Learning
title Compound Figure Separation of Biomedical Images: Mining Large Datasets for Self-supervised Learning
title_full Compound Figure Separation of Biomedical Images: Mining Large Datasets for Self-supervised Learning
title_fullStr Compound Figure Separation of Biomedical Images: Mining Large Datasets for Self-supervised Learning
title_full_unstemmed Compound Figure Separation of Biomedical Images: Mining Large Datasets for Self-supervised Learning
title_short Compound Figure Separation of Biomedical Images: Mining Large Datasets for Self-supervised Learning
title_sort compound figure separation of biomedical images: mining large datasets for self-supervised learning
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10112832/
https://www.ncbi.nlm.nih.gov/pubmed/37077404
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