Channing Division of Network Medicine, Brigham and Women's Hospital and Harvard Medical School, Boston, MA, USA.
Channing Division of Network Medicine, Brigham and Women's Hospital and Harvard Medical School, Boston, MA, USA; Department of Environmental Health, Harvard T.H. Chan School of Public Health, Boston, MA, USA.
Chemosphere. 2023 May;324:138228. doi: 10.1016/j.chemosphere.2023.138228. Epub 2023 Mar 4.
Exposure to per- and polyfluoroalkyl substances (PFAS) through the environment can lead to harmful health outcomes and the development of disease. However, little is known about how PFAS impact underlying biology that contributes to these adverse health effects. The metabolome represents the end product of cellular processes and has been used previously to understand physiological changes that lead to disease. In this study, we investigated whether exposure to PFAS was associated with the global, untargeted metabolome. In a cohort of 459 pregnant mothers and 401 children, we quantified plasma concentrations of six individual PFAS- PFOA, PFOS, PFHXS, PFDEA, and PFNA- and performed plasma metabolomic profiling by UPLC-MS. In adjusted linear regression analysis, we found associations between plasma PFAS and perturbations in lipid and amino acid metabolites in both mothers and children. In mothers, metabolites of 19 lipid pathways and 8 amino acid pathways were significantly associated with PFAS exposure at an FDR<0.05 threshold; in children, metabolites of 28 lipid pathways and 10 amino acid pathways exhibited significant associations at FDR<0.05 with PFAS exposure. Our investigation found that metabolites of the Sphingomyelin, Lysophospholipid, Long Chain Polyunsaturated Fatty Acid (n3 and n6), Fatty Acid- Dicarboxylate, and Urea Cycle showed the most significant associations with PFAS, suggesting these may be particular pathways of interest in the physiological response to PFAS. To our knowledge, this is the first study to characterize associations between the global metabolome and PFAS across multiple periods in the life course to understand impacts on underlying biology, and the findings presented here are relevant in understanding how PFAS disrupt normal biological function and may ultimately give rise to harmful health effects.
环境中接触到的全氟和多氟烷基物质(PFAS)可能导致有害的健康后果和疾病的发展。然而,人们对 PFAS 如何影响导致这些不良健康影响的潜在生物学知之甚少。代谢组学代表细胞过程的最终产物,以前曾被用于了解导致疾病的生理变化。在这项研究中,我们调查了 PFAS 暴露是否与全球非靶向代谢组学有关。在一个由 459 名孕妇和 401 名儿童组成的队列中,我们定量了六种个体 PFAS(全氟辛酸、全氟辛烷磺酸、PFHxS、PFDA、PFNA)在血浆中的浓度,并通过 UPLC-MS 进行了血浆代谢组学分析。在调整后的线性回归分析中,我们发现母亲和儿童的血浆 PFAS 与脂质和氨基酸代谢物的变化之间存在关联。在母亲中,19 种脂质途径和 8 种氨基酸途径的代谢物与 PFAS 暴露在 FDR<0.05 阈值下显著相关;在儿童中,28 种脂质途径和 10 种氨基酸途径的代谢物与 PFAS 暴露在 FDR<0.05 下显著相关。我们的研究发现,神经鞘磷脂、溶血磷脂、长链多不饱和脂肪酸(n3 和 n6)、脂肪酸二羧酸和尿素循环的代谢物与 PFAS 之间的关联最为显著,这表明这些途径可能是 PFAS 对生理反应的特别感兴趣的途径。据我们所知,这是第一项描述整个代谢组学与一生中多个时期的 PFAS 之间的关联的研究,以了解对潜在生物学的影响,这里提出的研究结果对于理解 PFAS 如何破坏正常的生物学功能并最终导致有害的健康影响是相关的。
