Accurate prediction of glaucoma from colour fundus images with a convolutional neural network that relies on active and transfer learning.
Hemelings Ruben, Elen Bart, Barbosa-Breda João, Lemmens Sophie, Meire Maarten, Pourjavan Sayeh, Vandewalle Evelien, Van de Veire Sara, Blaschko Matthew B, De Boever Patrick
AI Summary
A deep learning model accurately detected glaucoma from fundus images (AUC 0.995, 98% sensitivity) using less data through active/transfer learning, offering efficient, explainable automated screening.
Abstract
Purpose
To assess the use of deep learning (DL) for computer-assisted glaucoma identification, and the impact of training using images selected by an active learning strategy, which minimizes labelling cost. Additionally, this study focuses on the explainability of the glaucoma classifier.
Methods
This original investigation pooled 8433 retrospectively collected and anonymized colour optic disc-centred fundus images, in order to develop a deep learning-based classifier for glaucoma diagnosis. The labels of the various deep learning models were compared with the clinical assessment by glaucoma experts. Data were analysed between March and October 2018. Sensitivity, specificity, area under the receiver operating characteristic curve (AUC), and amount of data used for discriminating between glaucomatous and non-glaucomatous fundus images, on both image and patient level.
Results
Trained using 2072 colour fundus images, representing 42% of the original training data, the trained DL model achieved an AUC of 0.995, sensitivity and specificity of, respectively, 98.0% (CI 95.5%-99.4%) and 91% (CI 84.0%-96.0%), for glaucoma versus non-glaucoma patient referral.
Conclusions
These results demonstrate the benefits of deep learning for automated glaucoma detection based on optic disc-centred fundus images. The combined use of transfer and active learning in the medical community can optimize performance of DL models, while minimizing the labelling cost of domain-specific mavens. Glaucoma experts are able to make use of heat maps generated by the deep learning classifier to assess its decision, which seems to be related to inferior and superior neuroretinal rim (within ONH), and RNFL in superotemporal and inferotemporal zones (outside ONH).
MeSH Terms
Shields Classification
Key Concepts5
A deep learning model trained with 2072 colour fundus images (42% of the original training data) achieved an AUC of 0.995 for discriminating between glaucomatous and non-glaucomatous fundus images.
A deep learning model trained with 2072 colour fundus images achieved a sensitivity of 98.0% (CI 95.5%-99.4%) for glaucoma versus non-glaucoma patient referral.
A deep learning model trained with 2072 colour fundus images achieved a specificity of 91% (CI 84.0%-96.0%) for glaucoma versus non-glaucoma patient referral.
Deep learning classifiers for glaucoma diagnosis generate heat maps that relate to the inferior and superior neuroretinal rim (within ONH) and RNFL in superotemporal and inferotemporal zones (outside ONH).
The combined use of transfer and active learning can optimize the performance of deep learning models for automated glaucoma detection while minimizing the labelling cost of domain-specific mavens.
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