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Open Access 01-12-2024 | Biomarkers | Research

Ocular biomarkers of cognitive decline based on deep-learning retinal vessel segmentation

Authors: Rui Li, Ying Hui, Xiaoyue Zhang, Shun Zhang, Bin Lv, Yuan Ni, Xiaoshuai Li, Xiaoliang Liang, Ling Yang, Han Lv, Zhiyu Yin, Hongyang Li, Yingping Yang, Guangfeng Liu, Jing Li, Guotong Xie, Shouling Wu, Zhenchang Wang

Published in: BMC Geriatrics | Issue 1/2024

Abstract

Background

The current literature shows a strong relationship between retinal neuronal and vascular alterations in dementia. The purpose of the study was to use NFN+ deep learning models to analyze retinal vessel characteristics for cognitive impairment (CI) recognition.

Methods

We included 908 participants from a community-based cohort followed for over 15 years (the prospective KaiLuan Study) who underwent brain magnetic resonance imaging (MRI) and fundus photography between 2021 and 2022. The cohort consisted of both cognitively healthy individuals (N = 417) and those with cognitive impairment (N = 491). We employed the NFN+ deep learning framework for retinal vessel segmentation and measurement. Associations between Retinal microvascular parameters (RMPs: central retinal arteriolar / venular equivalents, arteriole to venular ratio, fractal dimension) and CI were assessed by Pearson correlation. P < 0.05 was considered statistically significant. The correlation between the CI and RMPs were explored, then the correlation coefficients between CI and RMPs were analyzed. Random Forest nonlinear classification model was used to predict whether one having cognitive decline or not. The assessment criterion was the AUC value derived from the working characteristic curve.

Results

The fractal dimension (FD) and global vein width were significantly correlated with the CI (P < 0.05). Age (0.193), BMI (0.154), global vein width (0.106), retinal vessel FD (0.099), and CRAE (0.098) were the variables in this model that were ranked in order of feature importance. The AUC values of the model were 0.799.

Conclusions

Establishment of a predictive model based on the extraction of vascular features from fundus images has a high recognizability and predictive power for cognitive function and can be used as a screening method for CI.

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Title: Ocular biomarkers of cognitive decline based on deep-learning retinal vessel segmentation
Authors: Rui Li
Ying Hui
Xiaoyue Zhang
Shun Zhang
Bin Lv
Yuan Ni
Xiaoshuai Li
Xiaoliang Liang
Ling Yang
Han Lv
Zhiyu Yin
Hongyang Li
Yingping Yang
Guangfeng Liu
Jing Li
Guotong Xie
Shouling Wu
Zhenchang Wang
Publication date: 01-12-2024
Publisher: BioMed Central
Keyword: Biomarkers
Published in: BMC Geriatrics / Issue 1/2024
Electronic ISSN: 1471-2318
DOI: https://doi.org/10.1186/s12877-023-04593-8

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