Parallel deep neural networks for endoscopic oct image segmentation

Dawei Li; Jimin Wu; Yufan He; Xinwen Yao; Wu Yuan; Defu Chen; Hyeon Cheol Park; Shaoyong Yu; Jerry L. Prince; Xingde Li

doi:10.1364/BOE.10.001126

Parallel deep neural networks for endoscopic oct image segmentation

Dawei Li, Jimin Wu, Yufan He, Xinwen Yao, Wu Yuan, Defu Chen, Hyeon Cheol Park, Shaoyong Yu, Jerry L. Prince, Xingde Li

School of Medicine

Research output: Contribution to journal › Article › peer-review

12 Scopus citations

Abstract

We report parallel-trained deep neural networks for automated endoscopic OCT image segmentation feasible even with a limited training data set. These U-Net-based deep neural networks were trained using a modified dice loss function and manual segmentations of ultrahigh-resolution cross-sectional images collected by an 800 nm OCT endoscopic system. The method was tested on in vivo guinea pig esophagus images. Results showed its robust layer segmentation capability with a boundary error of 1.4 µm insensitive to lay topology disorders. To further illustrate its clinical potential, the method was applied to differentiating in vivo OCT esophagus images from an eosinophilic esophagitis (EOE) model and its control group, and the results clearly demonstrated quantitative changes in the top esophageal layers’ thickness in the EOE model.

Original language	English (US)
Article number	#349139
Pages (from-to)	1126-1135
Number of pages	10
Journal	Biomedical Optics Express
Volume	10
Issue number	3
DOIs	https://doi.org/10.1364/BOE.10.001126
State	Published - Mar 1 2019

ASJC Scopus subject areas

Biotechnology
Atomic and Molecular Physics, and Optics

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title = "Parallel deep neural networks for endoscopic oct image segmentation",

abstract = "We report parallel-trained deep neural networks for automated endoscopic OCT image segmentation feasible even with a limited training data set. These U-Net-based deep neural networks were trained using a modified dice loss function and manual segmentations of ultrahigh-resolution cross-sectional images collected by an 800 nm OCT endoscopic system. The method was tested on in vivo guinea pig esophagus images. Results showed its robust layer segmentation capability with a boundary error of 1.4 µm insensitive to lay topology disorders. To further illustrate its clinical potential, the method was applied to differentiating in vivo OCT esophagus images from an eosinophilic esophagitis (EOE) model and its control group, and the results clearly demonstrated quantitative changes in the top esophageal layers{\textquoteright} thickness in the EOE model.",

author = "Dawei Li and Jimin Wu and Yufan He and Xinwen Yao and Wu Yuan and Defu Chen and Park, {Hyeon Cheol} and Shaoyong Yu and Prince, {Jerry L.} and Xingde Li",

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AU - Li, Dawei

AU - Wu, Jimin

AU - He, Yufan

AU - Yao, Xinwen

AU - Yuan, Wu

AU - Chen, Defu

AU - Park, Hyeon Cheol

AU - Yu, Shaoyong

AU - Prince, Jerry L.

AU - Li, Xingde

PY - 2019/3/1

Y1 - 2019/3/1

N2 - We report parallel-trained deep neural networks for automated endoscopic OCT image segmentation feasible even with a limited training data set. These U-Net-based deep neural networks were trained using a modified dice loss function and manual segmentations of ultrahigh-resolution cross-sectional images collected by an 800 nm OCT endoscopic system. The method was tested on in vivo guinea pig esophagus images. Results showed its robust layer segmentation capability with a boundary error of 1.4 µm insensitive to lay topology disorders. To further illustrate its clinical potential, the method was applied to differentiating in vivo OCT esophagus images from an eosinophilic esophagitis (EOE) model and its control group, and the results clearly demonstrated quantitative changes in the top esophageal layers’ thickness in the EOE model.

AB - We report parallel-trained deep neural networks for automated endoscopic OCT image segmentation feasible even with a limited training data set. These U-Net-based deep neural networks were trained using a modified dice loss function and manual segmentations of ultrahigh-resolution cross-sectional images collected by an 800 nm OCT endoscopic system. The method was tested on in vivo guinea pig esophagus images. Results showed its robust layer segmentation capability with a boundary error of 1.4 µm insensitive to lay topology disorders. To further illustrate its clinical potential, the method was applied to differentiating in vivo OCT esophagus images from an eosinophilic esophagitis (EOE) model and its control group, and the results clearly demonstrated quantitative changes in the top esophageal layers’ thickness in the EOE model.

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Parallel deep neural networks for endoscopic oct image segmentation

Abstract

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