室内灰尘中传统邻苯二甲酸酯及新型替代品的赋存特征、神经毒性风险与潜在机制OA
Occurrence characteristics,neurotoxicity risk,and potential mechanisms of traditional phthalate esters and novel alternatives in indoor dust
传统邻苯二甲酸酯(PAEs)及其新型替代品作为常用增塑剂,易从材料中迁移并富集于室内灰尘,对人体健康构成潜在风险.尽管其致癌与生殖毒性已被广泛研究,但其神经毒性,尤其是新型替代品的作用仍显不足.为此,本研究分析了校园典型微环境室内灰尘中目标化合物的污染特征,结合灰尘的经口摄入、吸入和皮肤接触 3 种暴露途径,以及吸收、分布、代谢、排泄和毒性模型,系统评估了不同人群的神经毒性健康风险,并进一步利用网络毒理学和分子对接技术探究其潜在毒性机制.结果表明,宿舍区域目标化合物的含量最高,主要组分包括邻苯二甲酸二(2-乙基己基)酯、对苯二甲酸二辛酯、乙酰柠檬酸三丁酯及偏苯三酸三辛酯.暴露评估表明,经口摄入是人体暴露的主要途径.毒性当量(TEQ)分析显示,18~60 岁女性面临的神经毒性风险高于男性.在机制上,网络毒理学筛选出 59 个核心靶点,主要富集于内分泌抵抗和癌症通路,表明这些化合物可能通过干扰细胞稳态与信号转导诱发神经毒性.分子对接识别出邻苯二甲酸二苯酯和邻苯二甲酸二环己酯为关键风险驱动因子,相比之下,芳香环和酯基较少的替代品(如己二酸庚基壬基酯、己二酸二异丁酯和己二酸二异癸烷基酯)表现出更低的神经健康风险和毒性潜力.构效关系分析表明,芳香环与酯基的协同作用是诱导神经毒性的关键机制.本研究通过整合环境暴露特征、TEQ 评估与分子机制分析,揭示了高校特定人群的神经毒性风险特征,阐明了分子结构对神经毒性的影响机制,从而为低神经毒性替代品的定向筛选和室内环境健康风险管理提供了参考依据.
Traditional phthalate esters(PAEs)and their novel alternatives are widely used as plasticizers.Owing to their non-covalent bonding with polymer matrices,these compounds readily migrate from materials and accumulate in indoor dust,posing potential risks to human health.Although their carcinogenic and reproductive toxicities have been extensively studied,their neu-rotoxicity,particularly that of novel alternatives,remains poorly understood.To address this knowledge gap,this study adopted an integrated approach combining pollution profiling,health risk assessment,and mechanistic investigation to systematically evaluate the neurotoxicity risks and potential mechanisms of PAEs and their alternatives in typical campus microenvironments(classrooms,laboratories,offices,cafeterias,and dormitories).The contamination profile of target compounds in indoor dust was determined using comprehensive two-dimensional gas chroma-tography coupled with time-of-flight mass spectrometry(GC×GC-TOF MS).By integrating three exposure pathways(ingestion,inhalation,and dermal contact of dust)with absorption,distribution,metabolism,excretion,and toxicity(ADMET)models,the estimated daily intakes(EDIs)and neurotoxic health risks for different populations were assessed.Furthermore,network toxicology and molecular docking techniques were employed to elucidate the potential toxic mechanisms.Results indicated that dormitories exhibited the highest contents of target compounds,with major components including di-2-ethylhexyl phthalate(DEHP),di(2-ethylhexyl)tetrahydrophthalate(DEHTH),acetyl tri-n-butyl citrate(ATBC),and trioctyl trimellitate(TOTM).Exposure assessment identified ingestion as the predominant exposure route.Using the ADMET model,toxicity equivalency factor(TEF)and toxic equivalent quantity(TEQ)were quantified for five neurotoxicity-related health endpoints,including phenotypic neurotoxicity,estrogen receptor activity,oxidative stress,mitochondrial dysfunction,and DNA damage.Risk assessment based on TEQ revealed that females aged 18-60 years faced higher neurotoxicity risks than males,although no statistically significant gender differences in EDI were observed across all age groups.Mechanistically,network toxicology identified 59 core targets associated with neurotoxicity,including oncogene,non-receptor tyrosine kinase(SRC),serine/threonine kinase 1(AKT1),estrogen receptor 1(ESR1),mitogen-activated protein kinase(MAPK1,MAPK3),heat shock protein 90 alpha family class a member 1(HSP90AA1),and Kirsten rat sarcoma viral oncogene homolog(KRAS).Functional enrichment analysis showed that these core targets were predominantly enriched in pathways related to en-docrine resistance and cancer,suggesting that these compounds may induce neurotoxicity by disrupting cellular homeostasis and signal transduction.Molecular docking supported specific binding interactions between representative compounds and core proteins,validating the predicted asso-ciations.Notably,diphenyl phthalate(DPhP)and dicyclohexyl phthalate(DCHP)were identified as the key risk drivers.In contrast,novel alternatives with fewer aromatic rings and ester groups,such as diheptyl,N-nonyl adipate(DHeNoA),diisobutyl adipate(DiBA),and diisodecyl adipate(DiDeA),exhibited lower neurotoxic potential.Structure-activity relationship analysis suggested that the synergistic effect of aromatic rings and ester groups is a critical mechanism inducing neurotoxicity.By integrating environmental exposure profiling,TEQ-based risk assessment,and molecular mechanism analysis,this study not only delineates the neurotoxicity risk profile for specific campus populations but also elucidates the influence of molecular structure on neurotoxicity,providing a scientific basis for the targeted screening of low-neurotoxicity alternatives and informed risk management of indoor environmental health.
李伟;高珂;华凯;王林啸;魏巍;鲁理平
北京工业大学环境科学系区域大气复合污染防治北京市重点实验室,北京 100124北京工业大学环境科学系区域大气复合污染防治北京市重点实验室,北京 100124北京工业大学环境科学系区域大气复合污染防治北京市重点实验室,北京 100124北京工业大学环境科学系区域大气复合污染防治北京市重点实验室,北京 100124北京工业大学环境科学系区域大气复合污染防治北京市重点实验室,北京 100124北京工业大学环境科学系区域大气复合污染防治北京市重点实验室,北京 100124
化学化工
邻苯二甲酸酯新型替代品室内灰尘赋存特征神经毒性风险潜在机制
phthalate estersnovel alternativesindoor dustoccurrence characteristicsneurotoxicity riskpotential mechanisms
《色谱》 2026 (5)
575-588,14
国家自然科学基金(22206009)北京市自然科学基金(8232020). National Natural Science Foundation of China(No.22206009)Beijing Natural Science Foundation(No.8232020).
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