超高效液相色谱-串联质谱法直接测定水中5种黄原酸

IF 1.2 4区 化学 Q4 CHEMISTRY, ANALYTICAL 色谱 Pub Date : 2023-04-01 DOI:10.3724/SP.J.1123.2022.09002
Wei-Hong Zhu, Chao Wang, Lin-Lin Zhang, Mao Yuan
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引用次数: 0

摘要

具有乙基、丙基、丁基、戊基等不同烷基的黄药在金属矿物的采矿浮选中被大量广泛应用。黄原酸通过选矿废水排放进入环境水体,在水中被电离或水解成黄原酸(XAs)的离子或分子。砷危害水生动植物和人体健康。据我们所知,XA分析主要局限于丁基黄药。此外,用现有的方法无法分别测定XAs的同分异构体和同分异构体。本文建立了一种基于超高效液相色谱-串联质谱(UPLC-MS/MS)的分离分析水中5种XAs的新方法,即乙基-、异丙基-、正丁基-、异丁基-和戊基-XAs。水样经0.22 μm亲水性聚四氟乙烯(PTFE)膜过滤后,直接注入UPLC-MS/MS仪。采用Waters Acquity UPLC BEH C18色谱柱(100 mm×2.1 mm, 1.7 μm)进行分离,以氨溶液(pH 11)-乙腈(9∶1,v/v)为流动相进行等压洗脱。采用负电喷雾电离(ESI-)和多重反应监测(MRM)模式对5种XAs进行了检测。采用内标法定量。综合优化预处理条件和UPLC-MS/MS条件,实现5种XAs的直接进样分离分析。在过滤过程中,XAs在疏水PTFE、亲水性PTFE、亲水性聚丙烯和聚丙烯膜上的吸附可以忽略。而在尼龙膜和聚醚砜膜上表现出明显的吸附作用。5种XAs主要在ESI-模式下形成[M-H]-母离子,碰撞破碎后获得的主要子离子取决于XAs的烷基。将流动相中氨溶液的pH值提高到11,可使正丁基和异丁基xas的异构体分离。优化后的流动相抑制了amyl-XA色谱峰的尾迹,有效地改善了xa的所有色谱峰形。选择BEH C18柱作为色谱柱,与T3 C18柱相比,BEH C18柱与高ph溶液的相容性更好。8 d的保存实验表明,在室温下,5种XAs的浓度随时间的推移而降低;在分析的xa中,乙基xa的浓度下降最为显著。在4℃和-20℃条件下,5种XAs在第8天的回收率仍然很高,分别为101% ~ 105%和100% ~ 106%。高浓度XAs的保存效果与低浓度XAs相似。在pH为11、避光温度为4℃的条件下,延长保存时间至8天。地表水和地下水中5种XA样品均未观察到明显的基质效应,但工业污水对乙基和异丙基XA有明显的基质抑制作用。由于乙基xas和异丙基xas的停留时间短,工业废水中的共助干扰物抑制了质谱信号。5种XAs在0.25 ~ 100 μg/L范围内线性良好,相关系数均大于0.9996。方法检出限低至0.03 ~ 0.04 μg/L,日内精密度为1.3% ~ 2.1%,日内精密度为3.3% ~ 4.1%。在低、中、高加标水平(1.00、20.0、80.0 μg/L)下加标回收率分别为96.9% ~ 133%、100% ~ 107%、104% ~ 112%。相应的rsd分别为2.1% ~ 3.0%、0.4% ~ 1.9%和0.4% ~ 1.6%。该方法已成功应用于地表水、地下水和工业污水中砷的分析。该方法无需繁琐的前处理过程,可分离检测各种XAs的同族异构体,其优点是样本量小、操作简单、灵敏度高、保存时间长。该技术在XA环境监测、水质评价、矿物浮选研究等方面具有良好的应用前景。
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[Direct determination of five xanthic acids in water by ultra performance liquid chromatography-tandem mass spectrometry].

Xanthates with different alkyl groups, such as ethyl, propyl, butyl, and amyl groups, are widely used in large quantities in the mining flotation of metallic minerals. Xanthates enter environmental waters through mineral processing wastewater discharge and are ionized or hydrolyzed into ions or molecules of xanthic acids (XAs) in water. XAs endanger aquatic plants and animals, as well as human health. To the best of our knowledge, XA analysis is mainly limited to butyl xanthate. Moreover, the isomers and congeners of XAs cannot be determined separately using the existing methods. Herein, a novel method based on ultra performance liquid chromatography-tandem mass spectrometry (UPLC-MS/MS) was established to separate and analyze five XAs, namely, ethyl-, isopropyl-, n-butyl-, isobutyl-, and amyl-XAs, in water. Water samples were filtered through a 0.22 μm hydrophilic polytetrafluoroethylene (PTFE) membrane and directly injected into the UPLC-MS/MS instrument. Separation was performed using a Waters Acquity UPLC BEH C18 column (100 mm×2.1 mm, 1.7 μm) with ammonia solution (pH 11)-acetonitrile (9∶1, v/v) as the mobile phase for isocratic elution. The five XAs were detected in the negative electrospray ionization (ESI-) and multiple reaction monitoring (MRM) modes. An internal standard method was used for quantification. The pretreatment and UPLC-MS/MS conditions were comprehensively optimized to achieve the separation and analysis of the five XAs via direct injection. The XAs showed negligible adsorption on hydrophobic PTFE, hydrophilic PTFE, hydrophilic polypropylene, and polypropylene membranes during filtration. However, the amyl-XA showed obvious adsorption on nylon and polyether sulfone membranes. The five XAs mainly formed [M-H]- parent ions in the ESI- mode and the main daughter ions obtained following collisional fragmentation depended on the alkyl groups of the XAs. Increasing the pH of the ammonia solution in the mobile phase to 11 led to the isomeric separation of n-butyl- and isobutyl-XAs. The optimized mobile phase inhibited the tailing of the chromatographic peak of amyl-XA and effectively improved all the chromatographic peak shapes of XAs. The BEH C18 column was selected as the chromatographic column owing to its better compatibility with high-pH solutions compared with the T3 C18 column. Preservation experiments conducted over 8 d showed that the concentration of all five XAs decreased over time at room temperature; among the XAs analyzed, the concentration of ethyl-XA revealed the most significant decrease. However, the recoveries of the five XAs at 4 and -20 ℃ remained high, ranging from 101% to 105% and from 100% to 106%, respectively, on the 8th day. The preservation observed with a high concentration of XAs was similar to that found with a low concentration. The preservation time was extended to 8 days at pH 11 and 4 ℃ away from the light. No significant matrix effects were observed for the five XA samples in surface water and groundwater, but industrial sewage exerted obvious matrix inhibitory effects on ethyl- and isopropyl-XAs. Owing to the short retention times of ethyl- and isopropyl-XAs, the co-fluxed interferents in the industrial sewage depressed the MS signals. The five XAs showed good linearity in the range of 0.25-100 μg/L, with correlation coefficients greater than 0.9996. The method detection limits were as low as 0.03-0.04 μg/L, and the intra- and inter-day precisions were 1.3%-2.1% and 3.3%-4.1%, respectively. The recoveries obtained under low, medium, and high spiked levels (1.00, 20.0, 80.0 μg/L) were 96.9%-133%, 100%-107%, and 104%-112%, respectively. The corresponding RSDs were 2.1%-3.0%, 0.4%-1.9%, and 0.4%-1.6%, respectively. The optimized method was successfully applied to the analysis of XAs in surface water, groundwater, and industrial sewage. The method could separate and detect various congeners and isomers of XAs without the need for cumbersome pretreatment processes, and its advantages include smaller sample requirements, simpler operation, higher sensitivity, and longer preservation time. The proposed technique presents excellent application potential in XA environmental monitoring and water evaluation, and mineral flotation studies.

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来源期刊
色谱
色谱 CHEMISTRY, ANALYTICAL-
CiteScore
1.30
自引率
42.90%
发文量
7198
期刊介绍: "Chinese Journal of Chromatography" mainly reports the basic research results of chromatography, important application results of chromatography and its interdisciplinary subjects and their progress, including the application of new methods, new technologies, and new instruments in various fields, the research and development of chromatography instruments and components, instrument analysis teaching research, etc. It is suitable for researchers engaged in chromatography basic and application technology research in scientific research institutes, master and doctoral students in chromatography and related disciplines, grassroots researchers in the field of analysis and testing, and relevant personnel in chromatography instrument development and operation units. The journal has columns such as special planning, focus, perspective, research express, research paper, monograph and review, micro review, technology and application, and teaching research.
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