Artificial Intelligence-Enabled Retinal Vasculometry at Scale Utilizing the UK Biobank, CLSA, and NEL DESP Datasets

Roshan A. Welikala; Jiri Fajtl; Gordon Johnson; Farzana Rahman; Razvan Podoleanu; Paolo Remagnino; Ellen E. Freeman; Ryan Chambers; Louis Bolter; John Anderson; Abraham Olvera-Barrios; Alasdair  Warwick; Paul J. Foster; Royce Shakespeare; Rahul Ganguly; Catherine Egan; Adnan Tufail; Christopher  G. Owen; Alicja R. Rudnicka; Sarah Ann Barman

Artificial Intelligence-Enabled Retinal Vasculometry at Scale Utilizing the UK Biobank, CLSA, and NEL DESP Datasets

Published: 25 Sept 2024, Last Modified: 23 Oct 2024IEEE BHI'24EveryoneRevisionsBibTeXCC BY 4.0

Keywords: Retinal Vasculometry, Deep Learning, Artificial Intelligence, Epidemiological Studies, UK Biobank, CLSA, NEL DESP

TL;DR: AI-enabled retinal vasculometry system that measures vessel morphology for epidemiological studies. It has transitioned to a deep learning pipeline, enhancing performance, and has processed over 1.4 million images across three datasets.

Abstract: Retinal imaging offers a non-invasive means to assess the circulatory system, with morphological features of retinal vessels serving as biomarkers for systemic disease. QUARTZ (QUantitative Analysis of Retinal vessel Topology and siZe) is a fully automated artificial intelligence-enabled retinal vasculometry system designed to process large-scale retinal image datasets to obtain quantitative measures of vessel morphology for use in epidemiological studies. Previously reliant on traditional image processing and machine learning, QUARTZ has now transitioned to a deep learning pipeline. Currently individually trained versions are tailored to specific datasets. Evaluation using the UK Biobank retinal dataset shows improvements in performance metrics: the F1 score for vessel segmentation increased from 0.7753 to 0.8472, accuracy for the A/V segment-level decision increased from 0.8524 to 0.9022, the detection rate for optic disc localization increased from 0.9760 to 0.9933, and the F1 score for image quality classification increased from 0.8872 to 0.9750. QUARTZ distinguishes itself from other deep learning based retinal vasculometry systems through its efficient use of data, extracting valuable information despite issues such as low levels of illumination. The high performance of QUARTZ is consistent across two other extensive retinal datasets, namely the Canadian Longitudinal Study on Aging (CLSA) and the North East London Diabetic Eye Screening Programme (NEL DESP). Evaluation on subsets was preceded by the automatic processing of entire retinal datasets by QUARTZ, processing over 1.4 million images. These retinal vasculometry outputs will serve as a valuable resource for epidemiological studies.

Track: 11. General Track

Registration Id: 5XNNXX8PW3B

Submission Number: 149

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