Targeted metabolomics in children with autism spectrum disorder with and without developmental regression.

IF 3.5 3区医学 Q2 ENDOCRINOLOGY & METABOLISM

Metabolic brain disease Pub Date : 2025-04-15 DOI:10.1007/s11011-025-01604-y

Chakkera Priyanka, Rita Christopher, Madhu Nagappa, John Vijay Sagar Kommu, Meghana Byalalu Krishnadevaraje, Durai Murukan Gunasekaran, Binu V S Nair, Raghavendra Kenchaiah, Nandakumar Dalavalaikodihalli Nanjaiah, Mariamma Philip, Sanjay K Shivanna, Pragalath Kumar Appadorai, Hansashree Padmanabha

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引用次数: 0

Abstract

Early diagnosis and intervention in children with autism spectrum disorder (ASD) is crucial. At present, diagnosis of ASD is primarily based on subjective tools. Identifying metabolic biomarkers will aid in early diagnosis of ASD complementing the assessment tools. The study aimed to conduct targeted metabolomic analysis and determine the plasma metabolites that can discriminate children with ASD from typically developing children (TD), and to determine the utility of machine learning in classifying ASD children based on the metabotypes. This was a multi-centric, analytical, case-control study conducted between April 2021-April 2023. Fasting plasma samples were obtained from seventy ASD and fifty-eight TD children, aged 2 to 12 years. Samples were quantitively analysed for 52 targeted metabolites (13 amino acids, 37 acylcarnitines, adenosine and 2-deoxyadenosine levels) using tandem mass spectrometry. An in-depth statistical analysis was performed. A total of 26 metabolites (11 amino acids, 14 acyl carnitines and adenosine) were found to be significantly (p < 0.005) different between ASD and TD children. Adenosine and amino acid levels were significantly decreased in ASD children. Among acyl carnitines, short- and long-chain acyl carnitine levels were significantly decreased, while medium-chain acyl carnitine levels were significantly increased in ASD children. Octenoylcarnitine-C8:1 (Cut-off value- 0.025 mmol/L, AUC- 0.683) and adenosine (Cut-off value- 0.025 mmol/L, AUC- 0.673) were found to predict children with ASD at a sensitivity of 55.7% and 57.1%, specificity of 79.3% and 72.4% respectively. Based on the metabolites, machine learning models like Support Vector Machine (SVM) and Random Forest (RF) were able to discriminate ASD from TD children with the classification accuracy score being highest in RF (79.487%, AUC- 0.800). Significant abnormalities in plasma metabolites were observed leading to disturbances in the Krebs cycle, urea cycle and fatty acid oxidation, suggesting mitochondrial dysfunction that may possibly contribute in the pathobiology of ASD. Octenoylcarnitine-C8:1 and Adenosine may serve as potential metabolic biomarkers for ASD.

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伴有或不伴有发育倒退的自闭症谱系障碍儿童的靶向代谢组学研究。

儿童自闭症谱系障碍（ASD）的早期诊断和干预至关重要。目前，ASD的诊断主要是基于主观工具。识别代谢生物标志物将有助于ASD的早期诊断，补充评估工具。本研究旨在进行有针对性的代谢组学分析，确定能够区分ASD儿童和典型发育儿童（TD）的血浆代谢物，并确定机器学习在基于代谢型对ASD儿童进行分类中的效用。这是一项多中心、分析性、病例对照研究，于2021年4月至2023年4月进行。从70名2至12岁的ASD和58名TD儿童中获取空腹血浆样本。采用串联质谱法对样品进行52种目标代谢物（13种氨基酸、37种酰基肉碱、腺苷和2-脱氧腺苷水平）的定量分析。进行了深入的统计分析。共有26种代谢物（11种氨基酸、14种酰基肉碱和腺苷）在ASD和TD儿童之间存在显著差异（p < 0.005）。ASD患儿的腺苷和氨基酸水平显著降低。在酰基肉毒碱中，短链和长链肉毒碱水平显著降低，中链肉毒碱水平显著升高。辛烷酰肉碱c8:1（临界值- 0.025 mmol/L, AUC- 0.683）和腺苷（临界值- 0.025 mmol/L, AUC- 0.673）预测儿童ASD的敏感性分别为55.7%和57.1%，特异性分别为79.3%和72.4%。基于代谢物，支持向量机（SVM）和随机森林（RF）等机器学习模型能够区分ASD和TD儿童，其中RF分类准确率得分最高（79.487%,AUC- 0.800）。血浆代谢物的显著异常导致克雷布斯循环、尿素循环和脂肪酸氧化紊乱，提示线粒体功能障碍可能与ASD的病理生物学有关。辛烷酰肉碱c8:1和腺苷可能作为ASD潜在的代谢生物标志物。

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

Metabolic brain disease 医学-内分泌学与代谢

CiteScore

5.90

自引率

5.60%

发文量

248

审稿时长

6-12 weeks

期刊介绍： Metabolic Brain Disease serves as a forum for the publication of outstanding basic and clinical papers on all metabolic brain disease, including both human and animal studies. The journal publishes papers on the fundamental pathogenesis of these disorders and on related experimental and clinical techniques and methodologies. Metabolic Brain Disease is directed to physicians, neuroscientists, internists, psychiatrists, neurologists, pathologists, and others involved in the research and treatment of a broad range of metabolic brain disorders.