Chuying Shi, Jack Lee, Di Shi, Gechun Wang, Fei Yuan, Benny Chung-Ying Zee
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In 10-fold validation, ARIA achieved sensitivities of 92.2 %, 92.7% and 85.7%, specificities of 88.8%, 86.7% and 80.2% and accuracies of 90.6%, 89.9% and 83.1% using the retinal features from the entire images, the ROI of the optic disc and the ROI of the macula, respectively. We found the model combining all the features has the best classification performance and obtained a sensitivity of 92.5%, a specificity of 92.1% and an accuracy of 92.4%, which is significantly different from other models (p<0.001). Conclusion We used two methods to improve the classification performance and found the best model to detect glaucoma on colour fundus retinal images. It can become a cost-effective and relatively more accurate glaucoma screening tool than conventional methods. Data are available on reasonable request.","PeriodicalId":9286,"journal":{"name":"BMJ Open Ophthalmology","volume":"32 1","pages":""},"PeriodicalIF":2.0000,"publicationDate":"2024-09-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Automatic retinal image analysis methods using colour fundus images for screening glaucomatous optic neuropathy\",\"authors\":\"Chuying Shi, Jack Lee, Di Shi, Gechun Wang, Fei Yuan, Benny Chung-Ying Zee\",\"doi\":\"10.1136/bmjophth-2023-001594\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Objectives Train an automatic retinal image analysis (ARIA) method to screen glaucomatous optic neuropathy (GON) on non-mydriatic retinal images labelled with the additional results of optical coherence tomography (OCT) and assess different models for the GON classification. Methods All the images were obtained from the hospital for training and 10-fold cross-validation. Two methods were used to improve the classification performance: (1) using images labelled with the additional results of OCT as the reference standard and (2) generating models using retinal features from the entire images, the region of interest (ROI) of the optic disc, and the ROI of the macula, and the combination of all the features. Results Overall, we collected 1338 images with paired OCT scans. In 10-fold validation, ARIA achieved sensitivities of 92.2 %, 92.7% and 85.7%, specificities of 88.8%, 86.7% and 80.2% and accuracies of 90.6%, 89.9% and 83.1% using the retinal features from the entire images, the ROI of the optic disc and the ROI of the macula, respectively. We found the model combining all the features has the best classification performance and obtained a sensitivity of 92.5%, a specificity of 92.1% and an accuracy of 92.4%, which is significantly different from other models (p<0.001). 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引用次数: 0
摘要
目的 在标有光学相干断层扫描(OCT)附加结果的非眼底视网膜图像上训练一种自动视网膜图像分析(ARIA)方法,以筛查青光眼性视神经病变(GON),并评估 GON 分类的不同模型。方法 所有图像均来自医院,用于训练和 10 倍交叉验证。为了提高分类性能,我们采用了两种方法:(1)使用 OCT 附加结果标记的图像作为参考标准;(2)使用整个图像、视盘感兴趣区(ROI)和黄斑感兴趣区的视网膜特征以及所有特征的组合生成模型。结果 我们共收集了 1338 张成对 OCT 扫描图像。在 10 倍验证中,ARIA 使用整个图像、视盘 ROI 和黄斑 ROI 的视网膜特征,灵敏度分别达到 92.2%、92.7% 和 85.7%,特异度分别达到 88.8%、86.7% 和 80.2%,准确度分别达到 90.6%、89.9% 和 83.1%。我们发现,结合所有特征的模型分类效果最好,灵敏度为 92.5%,特异度为 92.1%,准确率为 92.4%,与其他模型相比差异显著(p<0.001)。结论 我们用两种方法提高了分类性能,并找到了在彩色眼底视网膜图像上检测青光眼的最佳模型。与传统方法相比,它可以成为一种经济有效且相对更准确的青光眼筛查工具。如有合理要求,可提供相关数据。
Automatic retinal image analysis methods using colour fundus images for screening glaucomatous optic neuropathy
Objectives Train an automatic retinal image analysis (ARIA) method to screen glaucomatous optic neuropathy (GON) on non-mydriatic retinal images labelled with the additional results of optical coherence tomography (OCT) and assess different models for the GON classification. Methods All the images were obtained from the hospital for training and 10-fold cross-validation. Two methods were used to improve the classification performance: (1) using images labelled with the additional results of OCT as the reference standard and (2) generating models using retinal features from the entire images, the region of interest (ROI) of the optic disc, and the ROI of the macula, and the combination of all the features. Results Overall, we collected 1338 images with paired OCT scans. In 10-fold validation, ARIA achieved sensitivities of 92.2 %, 92.7% and 85.7%, specificities of 88.8%, 86.7% and 80.2% and accuracies of 90.6%, 89.9% and 83.1% using the retinal features from the entire images, the ROI of the optic disc and the ROI of the macula, respectively. We found the model combining all the features has the best classification performance and obtained a sensitivity of 92.5%, a specificity of 92.1% and an accuracy of 92.4%, which is significantly different from other models (p<0.001). Conclusion We used two methods to improve the classification performance and found the best model to detect glaucoma on colour fundus retinal images. It can become a cost-effective and relatively more accurate glaucoma screening tool than conventional methods. Data are available on reasonable request.