Deep Learning and Glaucoma Specialists: The Relative Importance of Optic Disc Features to Predict Glaucoma Referral in Fundus Photos
Sonia Phene, R. Carter Dunn, Naama Hammel, Yun Liu, Jonathan Krause,, Naho Kitade, Mike Schaekermann, Rory Sayres, Derek J. Wu, Ashish Bora,, Christopher Semturs, Anita Misra, Abigail E. Huang, Arielle Spitze, Felipe A., Medeiros, April Y. Maa, Monica Gandhi, Greg S. Corrado

TL;DR
This study developed a deep learning algorithm that analyzes fundus photos to detect glaucomatous optic nerve damage, showing high accuracy and potential to improve glaucoma screening and early diagnosis.
Contribution
The paper introduces a novel deep learning model trained on a large dataset that outperforms many graders in detecting referable glaucoma from fundus images.
Findings
Algorithm achieved AUC up to 0.945 for referable GON.
Deep learning showed higher sensitivity than most graders.
Key features for detection included vertical cup-to-disc ratio and neuroretinal rim notching.
Abstract
Glaucoma is the leading cause of preventable, irreversible blindness world-wide. The disease can remain asymptomatic until severe, and an estimated 50%-90% of people with glaucoma remain undiagnosed. Glaucoma screening is recommended for early detection and treatment. A cost-effective tool to detect glaucoma could expand screening access to a much larger patient population, but such a tool is currently unavailable. We trained a deep learning algorithm using a retrospective dataset of 86,618 images, assessed for glaucomatous optic nerve head features and referable glaucomatous optic neuropathy (GON). The algorithm was validated using 3 datasets. For referable GON, the algorithm had an AUC of 0.945 (95% CI, 0.929-0.960) in dataset A (1205 images, 1 image/patient; 18.1% referable), images adjudicated by panels of Glaucoma Specialists (GSs); 0.855 (95% CI, 0.841-0.870) in dataset B (9642…
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