Eun Young Choi, Dongyoung Kim, Jinyeong Kim, Eunjin Kim, Hyunseo Lee, Jinyoung Yeo, Tae Keun Yoo, Min Kim
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引用次数: 0
Abstract
Branch retinal vein occlusion (BRVO) is a leading cause of visual impairment in working-age individuals, though predicting its occurrence from retinal vascular features alone remains challenging. We developed a deep learning model to predict BRVO based on pre-onset, metadata-matched fundus hemisection images. This retrospective cohort study included patients diagnosed with unilateral BRVO from two Korean tertiary centers (2005-2023), using hemisection fundus images from 27 BRVO-affected eyes paired with 81 unaffected hemisections (27 counter and 54 contralateral) for training. A U-net model segmented retinal optic discs and blood vessels (BVs), dividing them into upper and lower halves labeled for BRVO occurrence. Both unimodal models (using either fundus or BV images) and a BV-enhanced multimodal model were constructed to predict future BRVO. The multimodal model outperformed the unimodal models achieving an area under the receiver operating characteristic curve of 0.76 (95% confidence interval [CI], 0.66-0.83) and accuracy of 68.5% (95% CI 58.9-77.1%), with predictions focusing on arteriovenous crossing regions in the retinal vascular arcade. These findings demonstrate the potential of the BV-enhanced multimodal approach for BRVO prediction and highlight the need for larger, multicenter datasets to improve its clinical utility and predictive accuracy.
视网膜分支静脉闭塞(BRVO)是工作年龄人群视力损害的主要原因,尽管仅从视网膜血管特征预测其发生仍然具有挑战性。我们开发了一个深度学习模型,基于发病前、元数据匹配的眼底半切面图像来预测BRVO。本回顾性队列研究纳入了来自韩国两个第三中心(2005-2023年)诊断为单侧BRVO的患者,使用27只BRVO受影响的眼睛的半切眼底图像与81只未受影响的半切眼底图像(27只对侧和54只对侧)进行训练。U-net模型对视网膜视盘和血管(BVs)进行分割,将其分为上半部分和下半部分,标记BRVO的发生。构建单模态模型(使用眼底或BV图像)和BV增强的多模态模型来预测未来的BRVO。多模态模型优于单模态模型,在受试者工作特征曲线下的面积为0.76(95%置信区间[CI], 0.66-0.83),准确率为68.5% (95% CI 58.9-77.1%),预测集中在视网膜血管拱桥的动静脉交叉区域。这些发现证明了bv增强的多模态方法预测BRVO的潜力,并强调需要更大的多中心数据集来提高其临床实用性和预测准确性。
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