A deep transfer learning framework for the automated assessment of corneal inflammation on in vivo confocal microscopy images

PURPOSE: Infiltration of activated dendritic cells and inflammatory cells in cornea represents an important marker for defining corneal inflammation. Deep transfer learning has presented a promising potential and is gaining more importance in computer assisted diagnosis. This study aimed to develop...

Descripción completa

Detalles Bibliográficos
Autores principales: Xu, Fan, Qin, Yikun, He, Wenjing, Huang, Guangyi, Lv, Jian, Xie, Xinxin, Diao, Chunli, Tang, Fen, Jiang, Li, Lan, Rushi, Cheng, Xiaohui, Xiao, Xiaolin, Zeng, Siming, Chen, Qi, Cui, Ling, Li, Min, Tang, Ningning
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Public Library of Science 2021
Materias:
Research Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8174724/
https://www.ncbi.nlm.nih.gov/pubmed/34081736
http://dx.doi.org/10.1371/journal.pone.0252653
_version_ 1783702961672683520
author Xu, Fan
Qin, Yikun
He, Wenjing
Huang, Guangyi
Lv, Jian
Xie, Xinxin
Diao, Chunli
Tang, Fen
Jiang, Li
Lan, Rushi
Cheng, Xiaohui
Xiao, Xiaolin
Zeng, Siming
Chen, Qi
Cui, Ling
Li, Min
Tang, Ningning
author_facet Xu, Fan
Qin, Yikun
He, Wenjing
Huang, Guangyi
Lv, Jian
Xie, Xinxin
Diao, Chunli
Tang, Fen
Jiang, Li
Lan, Rushi
Cheng, Xiaohui
Xiao, Xiaolin
Zeng, Siming
Chen, Qi
Cui, Ling
Li, Min
Tang, Ningning
author_sort Xu, Fan
collection PubMed
description PURPOSE: Infiltration of activated dendritic cells and inflammatory cells in cornea represents an important marker for defining corneal inflammation. Deep transfer learning has presented a promising potential and is gaining more importance in computer assisted diagnosis. This study aimed to develop deep transfer learning models for automatic detection of activated dendritic cells and inflammatory cells using in vivo confocal microscopy images. METHODS: A total of 3453 images was used to train the models. External validation was performed on an independent test set of 558 images. A ground-truth label was assigned to each image by a panel of cornea specialists. We constructed a deep transfer learning network that consisted of a pre-trained network and an adaptation layer. In this work, five pre-trained networks were considered, namely VGG-16, ResNet-101, Inception V3, Xception, and Inception-ResNet V2. The performance of each transfer network was evaluated by calculating the area under the curve (AUC) of receiver operating characteristic, accuracy, sensitivity, specificity, and G mean. RESULTS: The best performance was achieved by Inception-ResNet V2 transfer model. In the validation set, the best transfer system achieved an AUC of 0.9646 (P<0.001) in identifying activated dendritic cells (accuracy, 0.9319; sensitivity, 0.8171; specificity, 0.9517; and G mean, 0.8872), and 0.9901 (P<0.001) in identifying inflammatory cells (accuracy, 0.9767; sensitivity, 0.9174; specificity, 0.9931; and G mean, 0.9545). CONCLUSIONS: The deep transfer learning models provide a completely automated analysis of corneal inflammatory cellular components with high accuracy. The implementation of such models would greatly benefit the management of corneal diseases and reduce workloads for ophthalmologists.
format Online
Article
Text
id pubmed-8174724
institution National Center for Biotechnology Information
language English
publishDate 2021
publisher Public Library of Science
record_format MEDLINE/PubMed
spelling pubmed-81747242021-06-14 A deep transfer learning framework for the automated assessment of corneal inflammation on in vivo confocal microscopy images Xu, Fan Qin, Yikun He, Wenjing Huang, Guangyi Lv, Jian Xie, Xinxin Diao, Chunli Tang, Fen Jiang, Li Lan, Rushi Cheng, Xiaohui Xiao, Xiaolin Zeng, Siming Chen, Qi Cui, Ling Li, Min Tang, Ningning PLoS One Research Article PURPOSE: Infiltration of activated dendritic cells and inflammatory cells in cornea represents an important marker for defining corneal inflammation. Deep transfer learning has presented a promising potential and is gaining more importance in computer assisted diagnosis. This study aimed to develop deep transfer learning models for automatic detection of activated dendritic cells and inflammatory cells using in vivo confocal microscopy images. METHODS: A total of 3453 images was used to train the models. External validation was performed on an independent test set of 558 images. A ground-truth label was assigned to each image by a panel of cornea specialists. We constructed a deep transfer learning network that consisted of a pre-trained network and an adaptation layer. In this work, five pre-trained networks were considered, namely VGG-16, ResNet-101, Inception V3, Xception, and Inception-ResNet V2. The performance of each transfer network was evaluated by calculating the area under the curve (AUC) of receiver operating characteristic, accuracy, sensitivity, specificity, and G mean. RESULTS: The best performance was achieved by Inception-ResNet V2 transfer model. In the validation set, the best transfer system achieved an AUC of 0.9646 (P<0.001) in identifying activated dendritic cells (accuracy, 0.9319; sensitivity, 0.8171; specificity, 0.9517; and G mean, 0.8872), and 0.9901 (P<0.001) in identifying inflammatory cells (accuracy, 0.9767; sensitivity, 0.9174; specificity, 0.9931; and G mean, 0.9545). CONCLUSIONS: The deep transfer learning models provide a completely automated analysis of corneal inflammatory cellular components with high accuracy. The implementation of such models would greatly benefit the management of corneal diseases and reduce workloads for ophthalmologists. Public Library of Science 2021-06-03 /pmc/articles/PMC8174724/ /pubmed/34081736 http://dx.doi.org/10.1371/journal.pone.0252653 Text en © 2021 Xu et al https://creativecommons.org/licenses/by/4.0/This is an open access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/) , which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
spellingShingle Research Article
Xu, Fan
Qin, Yikun
He, Wenjing
Huang, Guangyi
Lv, Jian
Xie, Xinxin
Diao, Chunli
Tang, Fen
Jiang, Li
Lan, Rushi
Cheng, Xiaohui
Xiao, Xiaolin
Zeng, Siming
Chen, Qi
Cui, Ling
Li, Min
Tang, Ningning
A deep transfer learning framework for the automated assessment of corneal inflammation on in vivo confocal microscopy images
title A deep transfer learning framework for the automated assessment of corneal inflammation on in vivo confocal microscopy images
title_full A deep transfer learning framework for the automated assessment of corneal inflammation on in vivo confocal microscopy images
title_fullStr A deep transfer learning framework for the automated assessment of corneal inflammation on in vivo confocal microscopy images
title_full_unstemmed A deep transfer learning framework for the automated assessment of corneal inflammation on in vivo confocal microscopy images
title_short A deep transfer learning framework for the automated assessment of corneal inflammation on in vivo confocal microscopy images
title_sort deep transfer learning framework for the automated assessment of corneal inflammation on in vivo confocal microscopy images
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8174724/
https://www.ncbi.nlm.nih.gov/pubmed/34081736
http://dx.doi.org/10.1371/journal.pone.0252653
work_keys_str_mv AT xufan adeeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT qinyikun adeeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT hewenjing adeeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT huangguangyi adeeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT lvjian adeeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT xiexinxin adeeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT diaochunli adeeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT tangfen adeeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT jiangli adeeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT lanrushi adeeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT chengxiaohui adeeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT xiaoxiaolin adeeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT zengsiming adeeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT chenqi adeeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT cuiling adeeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT limin adeeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT tangningning adeeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT xufan deeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT qinyikun deeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT hewenjing deeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT huangguangyi deeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT lvjian deeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT xiexinxin deeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT diaochunli deeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT tangfen deeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT jiangli deeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT lanrushi deeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT chengxiaohui deeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT xiaoxiaolin deeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT zengsiming deeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT chenqi deeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT cuiling deeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT limin deeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages
AT tangningning deeptransferlearningframeworkfortheautomatedassessmentofcornealinflammationoninvivoconfocalmicroscopyimages

Ejemplares similares