血液代谢物与阻塞性睡眠呼吸暂停的因果效应:一项孟德尔随机研究。

Current neurovascular research Pub Date : 2024-01-01 DOI:10.2174/0115672026266627230921052416

Jing-Hao Wu, Ying-Hao Yang, Yun-Chao Wang, Wen-Kai Yu, Shan-Shan Li, Yun-Yun Mei, Ce-Zong, Zi-Han Zhou, Hang-Hang Zhu, Liu-Chang He, Xin-Yu Li, Chang-He Shi, Yu-Sheng Li

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引用次数: 0

摘要

背景：阻塞性睡眠呼吸暂停（OSA）是睡眠呼吸紊乱最常见的形式之一。研究表明，某些代谢变化在OSA的病理生理学中起着重要作用。然而，这些代谢产物与OSA之间的因果关系尚不清楚。目的：我们使用孟德尔随机化（MR）方法来研究代谢产物的遗传易感性与OSA之间的因果关系。方法：我们进行了2样本逆方差加权孟德尔随机化分析，以评估遗传确定的486种代谢产物对OSA的因果影响。进行多重敏感性分析以评估多效性。我们使用多变量孟德尔随机化分析来评估混杂因素，并使用孟德尔随机化贝叶斯模型平均值根据其遗传证据对重要生物标志物进行排名。我们还进行了代谢途径分析，以确定潜在的代谢途径。结果：我们确定了14种已知的OSA血清代谢产物（8种危险因素和6种保护因素）和12种未知的OSA相关血清代谢产物。这14种已知的代谢产物包括8种脂质（1-花生四烯酸甘油磷酸乙醇胺、十四烷二酸酯、表雄酮硫酸盐、乙酰甘油3磷酸盐、3-脱氢肉碱、Margarate17:0、二十二碳五烯酸3；22:5n3）、3种氨基酸（异戊酰基肉碱、3-甲基-2-氧代丁酸酯、蛋氨酸）、2种辅因子和维生素[胆红素（E，ZorZ，E），X-11593-O-甲基抗坏血酸]，1碳水化合物（1,6-脱水葡萄糖）。我们还确定了参与OSA发病机制的几种代谢途径。结论：本研究采用MR（孟德尔随机化）方法确定了OSA的6个保护因素和12个危险因素。3-脱氢肉碱是OSA最显著的危险因素。我们的研究还证实了参与OSA发病机制的几种重要代谢途径。缬氨酸、亮氨酸和异亮氨酸生物合成代谢途径是参与OSA发病机制的最重要代谢途径。

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Causal Effects of Blood Metabolites and Obstructive Sleep Apnea: A Mendelian Randomization Study.

Background: Obstructive sleep apnea (OSA) is one of the most common forms of sleep-disordered breathing. Studies have shown that certain changes in metabolism play an important role in the pathophysiology of OSA. However, the causal relationship between these metabolites and OSA remains unclear.

Aims: We use a mendelian randomization (MR) approach to investigate the causal associations between the genetic liability to metabolites and OSA.

Methods: We performed a 2-sample inverse-variance weighted mendelian randomization analysis to evaluate the causal effects of genetically determined 486 metabolites on OSA. Multiple sensitivity analyses were performed to assess pleiotropy. We used multivariate mendelian randomization analyses to assess confounding factors and mendelian randomization Bayesian model averaging to rank the significant biomarkers by their genetic evidence. We also conducted a metabolic pathway analysis to identify potential metabolic pathways.

Results: We identified 14 known serum metabolites (8 risk factors and 6 protective factors) and 12 unknown serum metabolites associated with OSA. These 14 known metabolites included 8 lipids( 1-arachidonoylglycerophosphoethanolamine, Tetradecanedioate, Epiandrosteronesulfate, Acetylca Glycerol3-phosphate, 3-dehydrocarnitine, Margarate17:0, Docosapentaenoaten3;22:5n3), 3 Aminoacids (Isovalerylcarnitine,3-methyl-2-oxobutyrate,Methionine), 2 Cofactors and vitamins [Bilirubin(E,ZorZ,E),X-11593--O-methylascorbate], 1Carbohydrate(1,6-anhydroglucose). We also identified several metabolic pathways that involved in the pathogenesis of OSA.

Conclusion: MR (mendelian randomization) approach was performed to identify 6 protective factors and 12 risk factors for OSA in the present study. 3-Dehydrocarnitine was the most significant risk factors for OSA. Our study also confirmed several significant metabolic pathways that were involved in the pathogenesis of OSA. Valine, leucine and isoleucine biosynthesis metabolic pathways were the most significant metabolic pathways that were involved in the pathogenesis of OSA.

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Current neurovascular research

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