Metabolomic profiling of plasma reveals differential disease severity markers in avian influenza A(H7N9) infection patients

Metabolomic profiling of plasma reveals differential disease severity markers in avian influenza A(H7N9) infection patients

Objectives: Avian influenza such as H7N9 is currently a major global public health risk, and at present, there is a lack of relevant diagnostic and treatment markers. Methods: We collected plasma samples from 104 confirmed H7N9 patients, 31 of whom died. Plasma metabolites were detected by UHPLC-HRM...

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Main Authors: Yuefeng Wang, Jili Ni, Mingzhu Huang, Wenxin Qu, Chang Liu, Zheying Mao, Jiaqi Bao, Weizhen Chen, Dongsheng Han, Fei Yu, Yifei Shen, Zhenzhen Deng, Shufa Zheng
Format: Article
Language:English
Published: Elsevier 2025-09-01
Series:International Journal of Infectious Diseases
Subjects:
H7N9
Metabolomic
Machine-learning
Death prediction model
Tryptophan metabolism
Online Access:http://www.sciencedirect.com/science/article/pii/S120197122500181X
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Summary:Objectives: Avian influenza such as H7N9 is currently a major global public health risk, and at present, there is a lack of relevant diagnostic and treatment markers. Methods: We collected plasma samples from 104 confirmed H7N9 patients, 31 of whom died. Plasma metabolites were detected by UHPLC-HRMS, and a survival prediction model based on metabolites was constructed by machine-learning models. Results: A total of 1536 metabolites were identified in the plasma samples of H7N9 patients, of which 64 metabolites were up-regulated and 35 metabolites were down-regulated in the death group. The enrichment analysis of tryptophan metabolism, porphyrin metabolism, and riboflavin metabolism were significantly up-regulated in the death group. We found that most lipids and lipid–like molecules were down-regulated in the death group, and organoheterocyclic compounds were significantly up-regulated in the death group. A machine-learning model was constructed for predicting mortality based on porphobilinogen, 5-hydroxyindole-3-acetic acid, L-kynurenine, Biliverdin, and D-dimer. The AUC on the test set was 0.929. Conclusion: We first revealed the plasma metabolomic characteristics of H7N9 patients and found that a machine-learning model based on plasma metabolites could predict the risk of death for H7N9 in the early stage of admission.
ISSN:1201-9712

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