Automated cone photoreceptor detection using synthetic data and deep learning in confocal adaptive optics scanning laser ophthalmoscope images
Mital Shah, Laura K. Young, Susan M. Downes, Hannah E. Smithson, Ana I. L. Namburete

TL;DR
This paper introduces a deep learning method using synthetic data to automatically detect cone photoreceptors in eye images, achieving performance comparable to manual labeling.
Contribution
A novel U-Net model trained with synthetic and real data achieves high accuracy in detecting photoreceptors in AOSLO images.
Findings
The U-Net model achieved a mean Dice coefficient of 0.989 on a test set compared to manual labeling.
The model generalized well to an independent dataset with a Dice coefficient of 0.962.
Performance was comparable to two existing automated methods and manual labeling.
Abstract
Adaptive optics scanning laser ophthalmoscope (AOSLO) imaging enables the cone photoreceptor mosaic to be visualised in the living human eye. Performing quantitative analysis of these images requires identification of individual photoreceptors. This is typically performed by manual labelling, which is subjective, time consuming and not feasible on a large scale. Automated algorithms to replace manual labelling are required and deep learning-based methods provide an effective way of achieving this. However, this approach requires large volumes of annotated training data that are difficult to acquire. Synthetic data may help to bridge this lack of annotated training data. A U-Net configuration was trained using a large synthetic dataset of confocal AOSLO images generated using ERICA alongside a smaller dataset of real confocal AOSLO images (Milwaukee dataset). Model performance was…
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Taxonomy
TopicsOphthalmology and Visual Impairment Studies · Retinal Imaging and Analysis · Retinopathy of Prematurity Studies
