Artificial intelligence-driven metabolomics of retinal nerve fibre layer to profile risks of mortality and cardiometabolic diseases

Shaopeng Yang; Zhuoyao Xin; Huangdong Li; Ziyu Zhu; Lisa Zhuoting Zhu; Xianwen Shang; Wenyong Huang; Lei Zhang; Mingguang He; Jost B Jonas; Nathan Congdon; Ching-Yu Cheng; Lingyi Liang; Wei Wang

doi:10.1038/s41467-025-66979-z

Artificial intelligence-driven metabolomics of retinal nerve fibre layer to profile risks of mortality and cardiometabolic diseases

Shaopeng Yang
, Zhuoyao Xin
, Huangdong Li
, Ziyu Zhu
, Lisa Zhuoting Zhu
, Xianwen Shang
, Wenyong Huang
, Lei Zhang
, Mingguang He
, Jost B Jonas
, Nathan Congdon
, Ching-Yu Cheng^*
, Lingyi Liang^*
, Wei Wang

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

Retinal nerve fibre layer (RNFL) is a non-invasive structural biomarker of cardiometabolic health, yet its biological underpinnings remain unknown. Here, we integrate advanced retinal optical biopsy and artificial intelligence (AI) algorithms with two complementary metabolomic assays across ethnically diverse cohorts to elucidate the metabolic basis underlying RNFL degeneration and its link to cardiometabolic disease (CMD) in Western cohort and Eastern cohort (Guangzhou Diabetic Eye Study, GDES). We identify 26 metabolic biomarkers significantly associated with RNFL thickness, most of which (ranging from 19 to 26) are linked to HDL composition and lipid transport, mediating a substantial proportion of the RNFL-CMD association (e.g., 63.7% for type 2 diabetes and 44.7% for myocardial infarction). AI-driven RNFL metabolic state model stratifies CMD risk with up to 21.8-fold enrichment between risk deciles and augments prediction while translating into clinical utility across genetic and demographic strata, particularly within socially vulnerable populations. This integrated approach highlights RNFL metabolic states as a shared basis underlying retinal-cardiometabolic connections and as early indicators that inform equitable CMD management.

Original language	English
Article number	11039
Number of pages	16
Journal	Nature Communications
Volume	16
DOIs	https://doi.org/10.1038/s41467-025-66979-z
Publication status	Published - 11 Dec 2025

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

Keywords

Risk Factors
Aged
Cohort Studies
Diabetes Mellitus, Type 2 - metabolism - mortality
Metabolomics - methods
Female
Adult
Artificial Intelligence
Middle Aged
Male
Cardiovascular Diseases - mortality - metabolism
Humans
Biomarkers - metabolism
Retina - metabolism - diagnostic imaging - pathology
Nerve Fibers - metabolism - pathology

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10.1038/s41467-025-66979-zLicence: CC BY-NC-ND

Artificial intelligence-driven metabolomics of retinal nerve fibre layer to profile risks of mortality and cardiometabolic diseases
Copyright 2025 the authors. This is an open access article published under a Creative Commons Attribution-NonCommercial-NoDerivs License (https://creativecommons.org/licenses/by-nc-nd/4.0/), which permits distribution and reproduction for non-commercial purposes, provided the author and source are cited.
Final published version, 4.49 MBLicence: CC BY-NC-ND

Cite this

Yang, S., Xin, Z., Li, H., Zhu, Z., Zhu, L. Z., Shang, X., Huang, W., Zhang, L., He, M., Jonas, J. B., Congdon, N., Cheng, C.-Y., Liang, L., & Wang, W. (2025). Artificial intelligence-driven metabolomics of retinal nerve fibre layer to profile risks of mortality and cardiometabolic diseases. Nature Communications, 16, Article 11039. https://doi.org/10.1038/s41467-025-66979-z

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title = "Artificial intelligence-driven metabolomics of retinal nerve fibre layer to profile risks of mortality and cardiometabolic diseases",

abstract = "Retinal nerve fibre layer (RNFL) is a non-invasive structural biomarker of cardiometabolic health, yet its biological underpinnings remain unknown. Here, we integrate advanced retinal optical biopsy and artificial intelligence (AI) algorithms with two complementary metabolomic assays across ethnically diverse cohorts to elucidate the metabolic basis underlying RNFL degeneration and its link to cardiometabolic disease (CMD) in Western cohort and Eastern cohort (Guangzhou Diabetic Eye Study, GDES). We identify 26 metabolic biomarkers significantly associated with RNFL thickness, most of which (ranging from 19 to 26) are linked to HDL composition and lipid transport, mediating a substantial proportion of the RNFL-CMD association (e.g., 63.7\% for type 2 diabetes and 44.7\% for myocardial infarction). AI-driven RNFL metabolic state model stratifies CMD risk with up to 21.8-fold enrichment between risk deciles and augments prediction while translating into clinical utility across genetic and demographic strata, particularly within socially vulnerable populations. This integrated approach highlights RNFL metabolic states as a shared basis underlying retinal-cardiometabolic connections and as early indicators that inform equitable CMD management. ",

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author = "Shaopeng Yang and Zhuoyao Xin and Huangdong Li and Ziyu Zhu and Zhu, \{Lisa Zhuoting\} and Xianwen Shang and Wenyong Huang and Lei Zhang and Mingguang He and Jonas, \{Jost B\} and Nathan Congdon and Ching-Yu Cheng and Lingyi Liang and Wei Wang",

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AU - Zhu, Lisa Zhuoting

AU - Shang, Xianwen

AU - Huang, Wenyong

AU - Zhang, Lei

AU - He, Mingguang

AU - Jonas, Jost B

AU - Congdon, Nathan

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AU - Wang, Wei

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N2 - Retinal nerve fibre layer (RNFL) is a non-invasive structural biomarker of cardiometabolic health, yet its biological underpinnings remain unknown. Here, we integrate advanced retinal optical biopsy and artificial intelligence (AI) algorithms with two complementary metabolomic assays across ethnically diverse cohorts to elucidate the metabolic basis underlying RNFL degeneration and its link to cardiometabolic disease (CMD) in Western cohort and Eastern cohort (Guangzhou Diabetic Eye Study, GDES). We identify 26 metabolic biomarkers significantly associated with RNFL thickness, most of which (ranging from 19 to 26) are linked to HDL composition and lipid transport, mediating a substantial proportion of the RNFL-CMD association (e.g., 63.7% for type 2 diabetes and 44.7% for myocardial infarction). AI-driven RNFL metabolic state model stratifies CMD risk with up to 21.8-fold enrichment between risk deciles and augments prediction while translating into clinical utility across genetic and demographic strata, particularly within socially vulnerable populations. This integrated approach highlights RNFL metabolic states as a shared basis underlying retinal-cardiometabolic connections and as early indicators that inform equitable CMD management.

AB - Retinal nerve fibre layer (RNFL) is a non-invasive structural biomarker of cardiometabolic health, yet its biological underpinnings remain unknown. Here, we integrate advanced retinal optical biopsy and artificial intelligence (AI) algorithms with two complementary metabolomic assays across ethnically diverse cohorts to elucidate the metabolic basis underlying RNFL degeneration and its link to cardiometabolic disease (CMD) in Western cohort and Eastern cohort (Guangzhou Diabetic Eye Study, GDES). We identify 26 metabolic biomarkers significantly associated with RNFL thickness, most of which (ranging from 19 to 26) are linked to HDL composition and lipid transport, mediating a substantial proportion of the RNFL-CMD association (e.g., 63.7% for type 2 diabetes and 44.7% for myocardial infarction). AI-driven RNFL metabolic state model stratifies CMD risk with up to 21.8-fold enrichment between risk deciles and augments prediction while translating into clinical utility across genetic and demographic strata, particularly within socially vulnerable populations. This integrated approach highlights RNFL metabolic states as a shared basis underlying retinal-cardiometabolic connections and as early indicators that inform equitable CMD management.

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JO - Nature Communications

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Artificial intelligence-driven metabolomics of retinal nerve fibre layer to profile risks of mortality and cardiometabolic diseases

Abstract

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Keywords

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