Combining clinical chemistry with metabolomics for metabolic phenotyping at population levels.

IF 3.3 3区医学 Q2 ENDOCRINOLOGY & METABOLISM

Metabolomics Pub Date : 2025-08-29 DOI:10.1007/s11306-025-02331-2

Yun Xu, Ian D Wilson, Royston Goodacre

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引用次数: 0

Abstract

Introduction: Untargeted metabolic phenotyping (metabolomics/metabonomics), also known as metabotyping, has been shown to be able to discriminate reliably between different physiological or clinical conditions. However, we believe that standard panels of routinely collected clinical and clinical chemistry data also have the potential to provide assay panels that complement metabotyping.

Objectives: To test the above hypothesis and evaluate the use of multivariate statistical analyses to provided panels of clinical/clinical chemistry data measurements that predict the age, sex and body mass index (BMI) of 977 normal subjects and compare these predictions with results acquired by metabotyping on the same healthy individuals.

Methods: Metabotyping involved serum metabolomics using gas chromatography-mass spectrometry (GC-MS) and liquid chromatography-mass spectrometry (LC-MS) previously reported in our HUSERMET study (Dunn et al., 2015), while clinical chemistry data were obtained in clinic for 19 measurements assessing liver and kidney function, blood pressure, serum glucose, cations, as well as lipids. Multivariate analyses involved using support vector machines, random forest and partial least squares, to predict sex, age and BMI. These models used as inputs: (i) the clinical chemistry data alone; (ii) three metabolomics datasets; (iii) combinations of clinical chemistry with the metabolomics data. Model predictions were rigorously validated using 1,000 bootstrapping re-sampling coupled with permutation tests.

Results: Multivariate statistical analyses on the clinical chemistry data obtained for these healthy participants could be used to predict: their sex, based on creatinine; their age, based on systolic blood pressure, total serum protein and serum glucose; as well as BMI using alanine transaminase, total cholesterol (Total-c) to high-density lipoprotein cholesterol (HDL-c) ratio and diastolic blood pressure. Combining clinical chemistry and metabolomics data sets enhanced the predictions of these characteristics. Moreover, this powerful combination allowed for quantitative predictions of age and BMI.

Conclusion: Multivariate statistical analysis on clinical chemistry data from the HUSERMET study obtained similar predictions of age, sex or BMI, compared to metabotyping using GC-MS and LC-MS. These predictions from clinical chemistry data were between 71 and 85% accurate (depending on the MVA used) and compared favourably with metabolomics (71-91 depending on analytical method). Combining clinical chemistry and metabolomics data sets enhanced the predictions of these characteristics to 77-93% accuracy, suggesting that this augmentation of methods may be a useful approach in the search for clinical biomarkers.

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结合临床化学和代谢组学在人群水平上进行代谢表型分析。

非靶向代谢表型（代谢组学/代谢组学），也称为代谢分型，已被证明能够可靠地区分不同的生理或临床状况。然而，我们相信常规收集临床和临床化学数据的标准小组也有可能提供补充代谢分型的分析小组。目的：验证上述假设，并评估多变量统计分析的使用，以提供临床/临床化学数据测量面板，预测977名正常受试者的年龄、性别和体重指数（BMI），并将这些预测与同一健康个体的代谢分型结果进行比较。方法：代谢分型涉及血清代谢组学，使用气相色谱-质谱（GC-MS）和液相色谱-质谱（LC-MS），之前在我们的HUSERMET研究中报道过（Dunn et al., 2015），同时在临床获得19项测量的临床化学数据，评估肝肾功能、血压、血清葡萄糖、阳离子以及脂质。多变量分析包括使用支持向量机、随机森林和偏最小二乘来预测性别、年龄和BMI。这些模型用作输入：(i)单独的临床化学数据；（ii）三个代谢组学数据集；（iii）临床化学与代谢组学数据的结合。模型预测通过1000次自举重新抽样和排列测试进行了严格验证。结果：对这些健康受试者的临床化学数据进行多元统计分析，可根据肌酐预测其性别；年龄：根据收缩压、血清总蛋白、血清葡萄糖测定；以及使用丙氨酸转氨酶的BMI、总胆固醇（total -c）与高密度脂蛋白胆固醇（HDL-c）之比和舒张压。结合临床化学和代谢组学数据集增强了对这些特征的预测。此外，这种强大的组合可以对年龄和BMI进行定量预测。结论：与使用GC-MS和LC-MS进行代谢分型相比，对HUSERMET研究的临床化学数据进行多变量统计分析获得了类似的年龄、性别或BMI预测。这些来自临床化学数据的预测准确率在71- 85%之间（取决于所使用的MVA），与代谢组学（71- 91%，取决于分析方法）相比更具优势。结合临床化学和代谢组学数据集，对这些特征的预测准确率提高到77-93%，这表明这种方法的增强可能是寻找临床生物标志物的有用方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Metabolomics 医学-内分泌学与代谢

CiteScore

6.60

自引率

2.80%

发文量

审稿时长

2 months

期刊介绍： Metabolomics publishes current research regarding the development of technology platforms for metabolomics. This includes, but is not limited to: metabolomic applications within man, including pre-clinical and clinical pharmacometabolomics for precision medicine metabolic profiling and fingerprinting metabolite target analysis metabolomic applications within animals, plants and microbes transcriptomics and proteomics in systems biology Metabolomics is an indispensable platform for researchers using new post-genomics approaches, to discover networks and interactions between metabolites, pharmaceuticals, SNPs, proteins and more. Its articles go beyond the genome and metabolome, by including original clinical study material together with big data from new emerging technologies.