A generalised computer vision model for improved glaucoma screening using fundus images.
Chaurasia Abadh K, Liu Guei-Sheung, Greatbatch Connor J, Gharahkhani Puya, Craig Jamie E, Mackey David A, MacGregor Stuart, Hewitt Alex W
AI Summary
A deep learning model effectively screened for glaucoma using fundus images, achieving high accuracy (AUROC 0.9920). This model shows promise for population-level screening, despite needing further validation on diverse datasets.
Abstract
Importance
Worldwide, glaucoma is a leading cause of irreversible blindness. Timely detection is paramount yet challenging, particularly in resource-limited settings. A novel, computer vision-based model for glaucoma screening using fundus images could enhance early and accurate disease detection.
Objective
To develop and validate a generalised deep-learning-based algorithm for screening glaucoma using fundus image.
Design, setting and participants: The glaucomatous fundus data were collected from 20 publicly accessible databases worldwide, resulting in 18,468 images from multiple clinical settings, of which 10,900 were classified as healthy and 7568 as glaucoma. All the data were evaluated and downsized to fit the model's input requirements. The potential model was selected from 20 pre-trained models and trained on the whole dataset except Drishti-GS. The best-performing model was further trained to classify healthy and glaucomatous fundus images using Fastai and PyTorch libraries.
Main outcomes and measures: The model's performance was compared against the actual class using the area under the receiver operating characteristic (AUROC), sensitivity, specificity, accuracy, precision and the F1-score.
Results
The high discriminative ability of the best-performing model was evaluated on a dataset comprising 1364 glaucomatous discs and 2047 healthy discs. The model reflected robust performance metrics, with an AUROC of 0.9920 (95% CI: 0.9920-0.9921) for both the glaucoma and healthy classes. The sensitivity, specificity, accuracy, precision, recall and F1-scores were consistently higher than 0.9530 for both classes. The model performed well on an external validation set of the Drishti-GS dataset, with an AUROC of 0.8751 and an accuracy of 0.8713.
Conclusions and relevance: This study demonstrated the high efficacy of our classification model in distinguishing between glaucomatous and healthy discs. However, the model's accuracy slightly dropped when evaluated on unseen data, indicating potential inconsistencies among the datasets-the model needs to be refined and validated on larger, more diverse datasets to ensure reliability and generalisability. Despite this, our model can be utilised for screening glaucoma at the population level.
MeSH Terms
Shields Classification
Key Concepts5
The best-performing computer vision model for glaucoma screening using fundus images achieved an AUROC of 0.9920 (95% CI: 0.9920-0.9921) for both glaucoma and healthy classes when evaluated on a dataset of 1364 glaucomatous discs and 2047 healthy discs.
The best-performing computer vision model for glaucoma screening using fundus images demonstrated sensitivity, specificity, accuracy, precision, recall, and F1-scores consistently higher than 0.9530 for both glaucoma and healthy classes when evaluated on a dataset of 1364 glaucomatous discs and 2047 healthy discs.
The developed computer vision model for glaucoma screening performed well on an external validation set of the Drishti-GS dataset, achieving an AUROC of 0.8751 and an accuracy of 0.8713.
A deep-learning-based algorithm for screening glaucoma using fundus images was developed and validated using 18,468 images from 20 publicly accessible databases worldwide, comprising 10,900 healthy and 7568 glaucomatous images.
The computer vision classification model for distinguishing between glaucomatous and healthy discs showed a slight drop in accuracy when evaluated on unseen data, suggesting potential inconsistencies among datasets and a need for refinement and validation on larger, more diverse datasets.
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