无鞘流毛细管电泳-电喷雾串联质谱用于面粉中荧光增白剂的高灵敏检测

doi:10.3724/SP.J.1123.2023.11023

摘要/Abstract

摘要：

食品中残留的过量荧光增白剂(FWAs)对人体健康存在潜在威胁,因此,开发准确、高灵敏的FWAs检测方法在食品安全监测方面具有重要意义。本工作提出了利用无鞘流接口的毛细管电泳-电喷雾串联质谱(CE-ESI-MS/MS)的方法,以实现面粉样品中6种FWAs的高灵敏检测。实验采用超声辅助液相萃取法进行样品前处理,以减小复杂样品中基质效应的干扰。以氯仿-甲醇(3∶2, v/v)溶液作为萃取剂,在30 ℃下对样品中的FWAs进行萃取。萃取完成后,经离心、氮气吹干后用氯仿-甲醇(1∶4, v/v)复溶后检测。无鞘流CE-ESI-MS/MS方法采用正离子(ESI⁺)和多反应监测(MRM)模式,利用二级质谱对6种目标物同时进行定性定量分析,从而提高方法的检测通量和灵敏度。结果显示,本方法具有较宽的线性范围、良好的线性关系和较低的方法检出限(0.04~0.67 ng/g),在实际样品中3个水平下的加标回收率良好(86.2%~103.7%),日间和日内重复性(RSD)分别不大于11.5%和10.2%。上述研究表明,本方法适用于复杂基质中多种FWAs的准确、高灵敏检测,在面粉样品的质量评估和FWAs的污染监控方面具有潜在的应用价值。

关键词: 毛细管电泳, 无鞘流电喷雾电离串联质谱, 荧光增白剂, 面粉

Abstract:

Fluorescent whitening agents (FWAs) are dyes that emit visible blue or blue-purple fluorescence upon ultraviolet-light absorption. Taking advantage of light complementarity, FWAs can compensate for the yellow color of many substances to achieve a whitening effect; thus, they are used extensively in various applications. FWAs are generally stable, but their presence in the environment can lead to pollution and accumulation in the body through the food chain. Recent studies have revealed that some types of FWAs, such as coumarin-based FWAs, may exhibit photo-induced mutagenic effects that can trigger allergic reactions in humans and even pose carcinogenic risks. Hence, the development of an accurate and highly sensitive method for detecting FWAs in food-related samples is a crucial endeavor. Owing to the high polarity and structural similarity of FWAs, the accurate determination of these substances in complex food samples requires an analytical method that offers both efficient separation and sensitive detection. Capillary electrophoresis (CE) exhibits essential features such as high separation efficiency, short analysis times, very small sample injection requirements, minimal use of organic solvents, and simple operation. Thus, it is often used as an effective alternative to liquid chromatographic techniques. Over the past few decades, electrospray ionization mass spectrometry (ESI-MS) has been utilized as a highly sensitive and accurate detection method in numerous chemical analytical fields because it enables the analysis of molecular structures. By combining the high separation efficiency of CE with the high sensitivity of ESI-MS, a powerful tool for identifying and quantifying trace amounts of FWAs in food samples may be obtained. In this study, we present a method based on sheathless CE coupled with electrospray ionization tandem mass spectrometry (ESI-MS/MS) for the simultaneous detection of six trace FWAs in flour. In the proposed method, the CE separation device is directly coupled to the mass spectrometer through a sheathless interface without the need for a sheath liquid for electric contact, thereby avoiding the dilution of the analytes and improving detection sensitivity. Various conditions that could affect extraction recovery, separation efficiency, and detection sensitivity were evaluated and optimized. The FWAs were effectively extracted from the sample matrix with reduced matrix effects by ultrasonic-assisted extraction at a temperature of 30 ℃ for 20 min using CHCl₃-MeOH (3∶2, v/v) as the extraction solvent. The extract was centrifuged, dried under N₂, and reconstituted in CHCl₃-MeOH (1∶4, v/v) for subsequent analysis. During the detection process, the CE device was coupled to the ESI-MS/MS instrument via a highly sensitive porous spray needle, which served as the sheathless electrospray interface. The target FWAs were scanned in positive-ion mode (ESI⁺) to ensure the stability and intensity of the obtained signals. Additionally, multiple-reaction monitoring (MRM) mode and MS/MS analysis were used to simultaneously quantify the six targets with high selectivity. The developed sheathless CE-ESI-MS/MS method detected the FWAs with high sensitivity over wide linear ranges with low method limits of detection (0.04-0.67 ng/g). The recoveries of the six target FWAs at three spiked levels were between 77.5% and 97.2%, with good interday (RSD≤11.5%) and intraday (RSD≤10.2%) precision. Analyses of the six target FWAs in eight commercial flour samples were performed using this method, and four positive samples were identified. These results demonstrate that the proposed CE-ESI-MS/MS method is a promising strategy for the determination of trace FWAs in complex food sample matrices with efficient separation and high sensitivity.

Key words: capillary electrophoresis (CE), sheathless electrospray ionization-tandem mass spectrometry (sheathless ESI-MS/MS), fluorescent whitening agents (FWAs), flour

中图分类号:

O658

王安平, 陈楚诗, 杨巾栏, 杨丽. 无鞘流毛细管电泳-电喷雾串联质谱用于面粉中荧光增白剂的高灵敏检测[J]. 色谱, 2024, 42(6): 590-598.

WANG Anping, CHEN Chushi, YANG Jinlan, YANG Li. Highly sensitive detection of fluorescent whitening agents in flour using sheathless capillary electrophoresis-electrospray ionization-tandem mass spectrometry[J]. Chinese Journal of Chromatography, 2024, 42(6): 590-598.

图/表 8

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FWA	Molecular formula	[M+H]⁺	DP/V	ColE/eV
FWA52	C₁₄H₁₇NO₂	232.1650	30	40
FWA135	C₁₈H₁₄N₂O₂	291.1510	30	40
FWA184	C₂₆H₂₆N₂O₂S	431.2328	40	40
FWA185	C₁₈H₁₀N₂O₂S	319.0953	40	45
FWA367	C₂₄H₁₄N₂O₂	363.1595	50	40
FWA393	C₂₈H₁₈N₂O₂	415.2624	50	45

FWA	Molecular formula	[M+H]⁺	DP/V	ColE/eV
FWA52	C₁₄H₁₇NO₂	232.1650	30	40
FWA135	C₁₈H₁₄N₂O₂	291.1510	30	40
FWA184	C₂₆H₂₆N₂O₂S	431.2328	40	40
FWA185	C₁₈H₁₀N₂O₂S	319.0953	40	45
FWA367	C₂₄H₁₄N₂O₂	363.1595	50	40
FWA393	C₂₈H₁₈N₂O₂	415.2624	50	45

Compound	Linear range/ (ng/g)	Regression equation	R²	mLOD/ (ng/g)	mLOQ/ (ng/g)	iLOD/ (ng/g)	iLOQ/ (ng/g)	ME	Repeatabilities (RSDs/%)
Compound	Linear range/ (ng/g)	Regression equation	R²	mLOD/ (ng/g)	mLOQ/ (ng/g)	iLOD/ (ng/g)	iLOQ/ (ng/g)	ME	T	A
FWA52	0.2-25	y=23.37x+93.29	0.989	0.07	0.20	0.55	1.75	1.04	7.3	9.7
FWA135	0.5-25	y=20.26x+22.35	0.990	0.16	0.50	1.20	3.50	0.80	8.1	8.7
FWA184	0.3-25	y=154.49x+38.71	0.993	0.04	0.28	0.35	1.00	0.90	6.9	9.0
FWA185	0.5-50	y=23.38x+51.05	0.994	0.17	0.50	1.20	3.45	1.15	7.4	10.3
FWA367	0.5-50	y=10.63x+2.85	0.991	0.17	0.50	1.00	3.20	0.87	9.1	10.2
FWA393	2.2-100	y=59.83x+66.82	0.996	0.67	2.20	2.20	6.50	1.02	6.9	10.7

Compound	Linear range/ (ng/g)	Regression equation	R²	mLOD/ (ng/g)	mLOQ/ (ng/g)	iLOD/ (ng/g)	iLOQ/ (ng/g)	ME	Repeatabilities (RSDs/%)
Compound	Linear range/ (ng/g)	Regression equation	R²	mLOD/ (ng/g)	mLOQ/ (ng/g)	iLOD/ (ng/g)	iLOQ/ (ng/g)	ME	T	A
FWA52	0.2-25	y=23.37x+93.29	0.989	0.07	0.20	0.55	1.75	1.04	7.3	9.7
FWA135	0.5-25	y=20.26x+22.35	0.990	0.16	0.50	1.20	3.50	0.80	8.1	8.7
FWA184	0.3-25	y=154.49x+38.71	0.993	0.04	0.28	0.35	1.00	0.90	6.9	9.0
FWA185	0.5-50	y=23.38x+51.05	0.994	0.17	0.50	1.20	3.45	1.15	7.4	10.3
FWA367	0.5-50	y=10.63x+2.85	0.991	0.17	0.50	1.00	3.20	0.87	9.1	10.2
FWA393	2.2-100	y=59.83x+66.82	0.996	0.67	2.20	2.20	6.50	1.02	6.9	10.7

Compound	Added/(ng/g)			Recoveries (RSDs)/%(n=5)			Repeatabilities (RSDs)/%(n=5)
Compound	1×mLOQ	2×mLOQ	10×mLOQ	1×mLOQ	2×mLOQ	10×mLOQ	Intraday	Interday
FWA52	2.0	4.0	20.0	102.2 (7.4)	92.4 (9.2)	89.2 (8.7)	8.9	9.1
FWA135	4.5	9.0	45.0	90.4 (7.9)	89.5 (9.2)	101.4 (9.6)	10.2	11.5
FWA184	1.5	3.0	15.0	100.2 (6.9)	86.2 (7.2)	91.2 (9.0)	7.9	9.4
FWA185	5.0	10.0	50.0	95.3 (7.4)	101.9 (9.5)	92.6 (6.3)	8.6	10.2
FWA367	5.0	10.0	50.0	87.4 (6.5)	88.2 (8.7)	92.7 (7.8)	9.6	11.3
FWA393	15.0	30.0	150.0	103.7 (9.8)	88.6 (9.4)	87.5 (10.2)	7.8	10.7