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使用智能手机进行深度学习辅助（自动）青光眼诊断。

Deep learning-assisted (automatic) diagnosis of glaucoma using a smartphone.

作者信息

Nakahara Kenichi, Asaoka Ryo, Tanito Masaki, Shibata Naoto, Mitsuhashi Keita, Fujino Yuri, Matsuura Masato, Inoue Tatsuya, Azuma Keiko, Obata Ryo, Murata Hiroshi

机构信息

Queue Inc, Tokyo, Japan.

Department of Ophthalmology, Seirei Hamamatsu General Hospital, Shizuoka, Japan

出版信息

Br J Ophthalmol. 2022 Apr;106(4):587-592. doi: 10.1136/bjophthalmol-2020-318107. Epub 2021 Jul 14.

DOI:10.1136/bjophthalmol-2020-318107

PMID:34261663

Abstract

BACKGROUND/AIMS: To validate a deep learning algorithm to diagnose glaucoma from fundus photography obtained with a smartphone.

METHODS

A training dataset consisting of 1364 colour fundus photographs with glaucomatous indications and 1768 colour fundus photographs without glaucomatous features was obtained using an ordinary fundus camera. The testing dataset consisted of 73 eyes of 73 patients with glaucoma and 89 eyes of 89 normative subjects. In the testing dataset, fundus photographs were acquired using an ordinary fundus camera and a smartphone. A deep learning algorithm was developed to diagnose glaucoma using a training dataset. The trained neural network was evaluated by prediction result of the diagnostic of glaucoma or normal over the test datasets, using images from both an ordinary fundus camera and a smartphone. Diagnostic accuracy was assessed using the area under the receiver operating characteristic curve (AROC).

RESULTS

The AROC with a fundus camera was 98.9% and 84.2% with a smartphone. When validated only in eyes with advanced glaucoma (mean deviation value < -12 dB, N=26), the AROC with a fundus camera was 99.3% and 90.0% with a smartphone. There were significant differences between these AROC values using different cameras.

CONCLUSION

The usefulness of a deep learning algorithm to automatically screen for glaucoma from smartphone-based fundus photographs was validated. The algorithm had a considerable high diagnostic ability, particularly in eyes with advanced glaucoma.

摘要

背景/目的：验证一种深度学习算法，用于从智能手机拍摄的眼底照片中诊断青光眼。

方法

使用普通眼底相机获取了一个训练数据集，其中包括1364张有青光眼指征的彩色眼底照片和1768张无青光眼特征的彩色眼底照片。测试数据集包括73例青光眼患者的73只眼和89例正常受试者的89只眼。在测试数据集中，使用普通眼底相机和智能手机获取眼底照片。开发了一种深度学习算法，使用训练数据集诊断青光眼。使用来自普通眼底相机和智能手机的图像，通过测试数据集上青光眼或正常诊断的预测结果对训练后的神经网络进行评估。使用受试者操作特征曲线下面积（AROC）评估诊断准确性。

结果

使用眼底相机时的AROC为98.9%，使用智能手机时为84.2%。仅在晚期青光眼患者（平均偏差值＜-12dB，N=26）的眼中进行验证时，使用眼底相机时的AROC为99.3%，使用智能手机时为90.0%。使用不同相机时，这些AROC值之间存在显著差异。

结论

验证了一种深度学习算法从基于智能手机的眼底照片中自动筛查青光眼的有效性。该算法具有相当高的诊断能力，尤其是在晚期青光眼患者的眼中。

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使用智能手机进行深度学习辅助（自动）青光眼诊断。

Deep learning-assisted (automatic) diagnosis of glaucoma using a smartphone.

作者信息

机构信息

出版信息

METHODS

RESULTS

CONCLUSION

方法

结果

结论

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