Zeng Yong-Fu, Chen Mei-Fang, Shao Yu, Yan Yong-Huan, Zhang Hai-Chao, Wang Jing, Ai Lian-Feng, Kang Wei-Jun
School of Public Health, Hebei Medical University, Shijiazhuang 050017, China.
Hebei Key Laboratory of Environment and Population Health, Shijiazhuang 050017, China.
Se Pu. 2023 May 8;41(5):386-396. doi: 10.3724/SP.J.1123.2022.09017.
An analytical method based on ultra-performance liquid chromatography-tandem mass spectrometry was developed for the simultaneous determination of 27 pharmaceutical and personal-care product (PPCP) residues in plants. The enrichment and cleanup of PPCPs in plants were achieved using an HLB extraction column, and the separation was performed on a BEH C18 column (100 mm×2.1 mm, 1.7 μm) with 0.1% formic acid water-acetonitrile as the mobile phase via gradient elution. PPCPs were detected with electrospray ionization mass spectrometry in positive-ion multiple-reaction monitoring (MRM) mode. The limits of detection and quantification of the 27 PPCPs in plants were 0.01-0.30 μg/kg and 0.03-0.98 μg/kg, respectively. Good linearities were observed with coefficients of determination () >0.99. The spiked recoveries were between 80.8% and 122.3% with relative standard deviations (RSDs) between 1.0% and 9.9%. The method was subsequently used to study sprouts grown in different concentrations of PPCPs. A total of 10 PPCPs were detected in sprouts grown in medium with a low concentration PPCPs, 13 PPCPs were detected in sprouts grown in medium with a moderate concentration of PPCPs, and 19 PPCPs were detected in sprouts grown in medium with a high concentration of PPCPs. These results showed that plants grown in water bodies contaminated with PPCPs or irrigated with water contaminated with PPCPs absorbed and accumulated these substances and that the amount and type of PPCPs absorbed by plants were closely related to the levels of PPCPs in the external environment. Analysis of the contents of PPCPs in different plant tissues revealed a general distribution of root>stem>leaf. Haemosibutramine showed a tissue distribution of leaf>stem>root, while glibenclamide showed a distribution of root>leaf>stem; these results revealed differences in the distribution of PPCPs in plants. Calculation of the transfer factor (TF) of the PPCPs in plants demonstrated significant differences in the transferability of different PPCPs, with TF=2.34 for haemosibutramine and TF=1.25 for chlorosibutramine. The results showed that among the drugs that migrated in plants, haemonosibutramine and chlorosibutramine had the strongest migration ability in sprouts, followed by nicardipine and chlorpheniramine maleate, and amantadine, -monodesmethyl sibutramine, carbamazepine and flumequine had the weakest migration ability. Once absorbed, these compounds were transferred to the stems and/or leaves, where they accumulate and cause potential harm by contaminating other plant organs. Therefore, PPCPs such as homosibutramine and chlorosibutramine, which easily migrate in plants, should be given extra attention in future studies. The method is simple in pre-treatment, sensitive and accurate, and can be widely applied to the detection of PPCP residues in plant samples.
建立了一种基于超高效液相色谱 - 串联质谱的分析方法,用于同时测定植物中27种药品及个人护理用品(PPCP)残留。采用HLB萃取柱对植物中的PPCP进行富集和净化,在BEH C18柱(100 mm×2.1 mm,1.7 μm)上,以0.1%甲酸水 - 乙腈为流动相,通过梯度洗脱进行分离。采用电喷雾电离质谱在正离子多反应监测(MRM)模式下检测PPCP。植物中27种PPCP的检测限和定量限分别为0.01 - 0.30 μg/kg和0.03 - 0.98 μg/kg。测定系数()>0.99,线性关系良好。加标回收率在80.8%至122.3%之间,相对标准偏差(RSD)在1.0%至9.9%之间。该方法随后用于研究在不同浓度PPCP中生长的豆芽。在低浓度PPCP培养基中生长的豆芽中检测到10种PPCP,在中等浓度PPCP培养基中生长的豆芽中检测到13种PPCP,在高浓度PPCP培养基中生长的豆芽中检测到19种PPCP。这些结果表明,生长在受PPCP污染水体中或用受PPCP污染水灌溉的植物吸收并积累了这些物质,且植物吸收的PPCP的量和种类与外部环境中PPCP的水平密切相关。对不同植物组织中PPCP含量的分析表明,其一般分布为根>茎>叶。去甲西布曲明的组织分布为叶>茎>根,而格列本脲的分布为根>叶>茎;这些结果揭示了PPCP在植物中的分布差异。计算植物中PPCP的转移因子(TF)表明,不同PPCP的转移能力存在显著差异,去甲西布曲明的TF = 2.34,氯西布曲明的TF = 1.25。结果表明,在植物中迁移的药物中,去甲西布曲明和氯西布曲明在豆芽中的迁移能力最强,其次是尼卡地平和马来酸氯苯那敏,金刚烷胺、去甲基西布曲明、卡马西平和氟甲喹的迁移能力最弱。一旦被吸收,这些化合物会转移到茎和/或叶中,在那里积累并通过污染其他植物器官造成潜在危害。因此,在未来的研究中,应特别关注像去甲西布曲明和氯西布曲明这样容易在植物中迁移的PPCP。该方法预处理简单,灵敏且准确,可广泛应用于植物样品中PPCP残留的检测。
