五年真实世界数据中新生血管年龄相关性黄斑变性的自动液算法验证。

VALIDATION OF AN AUTOMATED FLUID ALGORITHM ON REAL-WORLD DATA OF NEOVASCULAR AGE-RELATED MACULAR DEGENERATION OVER FIVE YEARS.

机构信息

Department of Ophthalmology and Optometry, Medical University of Vienna, Spitalgasse, Vienna, Austria.

RetInSight GmbH, Elisabethstrasse, Vienna, Austria; and.

出版信息

Retina. 2022 Sep 1;42(9):1673-1682. doi: 10.1097/IAE.0000000000003557.

DOI:10.1097/IAE.0000000000003557

PMID:35994584

Abstract

BACKGROUND/PURPOSE: To apply an automated deep learning automated fluid algorithm on data from real-world management of patients with neovascular age-related macular degeneration for quantification of intraretinal/subretinal fluid volumes in optical coherence tomography images.

METHODS

Data from the Vienna Imaging Biomarker Eye Study (VIBES, 2007-2018) were analyzed. Databases were filtered for treatment-naive neovascular age-related macular degeneration with a baseline optical coherence tomography and at least one follow-up and 1,127 eyes included. Visual acuity and optical coherence tomography at baseline, Months 1 to 3/Years 1 to 5, age, sex, and treatment number were included. Artificial intelligence and certified manual grading were compared in a subanalysis of 20%. Main outcome measures were fluid volumes.

RESULTS

Intraretinal/subretinal fluid volumes were maximum at baseline (intraretinal fluid: 21.5/76.6/107.1 nL; subretinal fluid 13.7/86/262.5 nL in the 1/3/6-mm area). Intraretinal fluid decreased to 5 nL at M1-M3 (1-mm) and increased to 11 nL (Y1) and 16 nL (Y5). Subretinal fluid decreased to a mean of 4 nL at M1-M3 (1-mm) and remained stable below 7 nL until Y5. Intraretinal fluid was the only variable that reflected VA change over time. Comparison with human expert readings confirmed an area under the curve of >0.9.

CONCLUSION

The Vienna Fluid Monitor can precisely quantify fluid volumes in optical coherence tomography images from clinical routine over 5 years. Automated tools will introduce precision medicine based on fluid guidance into real-world management of exudative disease, improving clinical outcomes while saving resources.

摘要

背景/目的：将自动深度学习自动液体算法应用于真实世界中新生血管性年龄相关性黄斑变性患者管理的数据中，以量化光学相干断层扫描图像中的视网膜内/下液体量。

方法

对 2007 年至 2018 年维也纳成像生物标志物眼研究（VIBES）的数据进行了分析。对未经治疗的新生血管性年龄相关性黄斑变性的基线光学相干断层扫描和至少一次随访的数据库进行了过滤，共纳入 1127 只眼。包括视力和基线、1 至 3 个月/1 至 5 年、年龄、性别和治疗次数的光学相干断层扫描。在 20%的亚分析中比较了人工智能和经过认证的手动分级。主要观察指标为液体量。

结果

视网膜内/下液体量在基线时最大（视网膜内液体：1/3/6mm 区域的 21.5/76.6/107.1nL；视网膜下液体 13.7/86/262.5nL）。视网膜内液体在 M1-M3（1mm）降至 5nL，并在 Y1 增至 11nL，在 Y5 增至 16nL。视网膜下液体在 M1-M3（1mm）降至平均 4nL，并在 Y5 之前保持稳定在 7nL 以下。视网膜内液体是唯一能反映随时间变化的 VA 的变量。与人类专家读数的比较证实，曲线下面积>0.9。

结论

Vienna 液体监测器可以在 5 年内精确地量化来自临床常规的光学相干断层扫描图像中的液体量。自动化工具将基于液体引导的精准医学引入渗出性疾病的真实世界管理中，在节省资源的同时提高临床疗效。

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五年真实世界数据中新生血管年龄相关性黄斑变性的自动液算法验证。

VALIDATION OF AN AUTOMATED FLUID ALGORITHM ON REAL-WORLD DATA OF NEOVASCULAR AGE-RELATED MACULAR DEGENERATION OVER FIVE YEARS.

机构信息

出版信息

METHODS

RESULTS

CONCLUSION

方法

结果

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