Litcius/Paper detail

Physics-informed deep generative learning for quantitative assessment of the retina

Emmeline Brown, Andrew A. Guy, Natalie Holroyd, Paul W. Sweeney, Lucie Gourmet, Hannah Coleman, Claire Walsh, Athina E. Markaki, Rebecca J. Shipley, Ranjan Rajendram, Simon Walker‐Samuel

2024Nature Communications22 citationsDOIOpen Access PDF

Abstract

Disruption of retinal vasculature is linked to various diseases, including diabetic retinopathy and macular degeneration, leading to vision loss. We present here a novel algorithmic approach that generates highly realistic digital models of human retinal blood vessels, based on established biophysical principles, including fully-connected arterial and venous trees with a single inlet and outlet. This approach, using physics-informed generative adversarial networks (PI-GAN), enables the segmentation and reconstruction of blood vessel networks with no human input and which out-performs human labelling. Segmentation of DRIVE and STARE retina photograph datasets provided near state-of-the-art vessel segmentation, with training on only a small (n = 100) simulated dataset. Our findings highlight the potential of PI-GAN for accurate retinal vasculature characterization, with implications for improving early disease detection, monitoring disease progression, and improving patient care.

Topics & Concepts

SegmentationComputer scienceRetinaGenerative grammarArtificial intelligenceDiabetic retinopathyRetinalMacular degenerationDeep learningComputer visionPattern recognition (psychology)OphthalmologyNeuroscienceMedicineBiologyDiabetes mellitusEndocrinologyRetinal Imaging and AnalysisAI in cancer detectionDigital Imaging for Blood Diseases