分散固相萃取-超高效液相色谱-串联质谱法测定农产品中乙拌磷及其代谢物

doi:10.3724/SP.J.1123.2021.04028

摘要/Abstract

摘要：

基于超高效液相色谱-串联质谱(UHPLC-MS/MS)建立定量分析乙拌磷及其5个代谢物(乙拌磷砜、乙拌磷亚砜、内吸磷-S、内吸磷-S-砜、内吸磷-S-亚砜)的方法,应用该方法分析其在农产品(豌豆、芦笋、小麦、咖啡豆和花生)中的残留量。对样品前处理及色谱条件进行优化,样品经过乙腈涡旋提取(小麦、咖啡豆和花生先加水润湿),经盐析分层,取上清液经50 mg C₁₈、50 mg PSA和50 mg NH₂混合分散固相萃取净化后,经Thermo Syncronis C₁₈色谱柱(150 mm×2.1 mm, 5 μm)分离,柱温40 ℃,进样量2 μL,以水和乙腈为流动相梯度洗脱后,采用ESI源,在正离子扫描和多反应监测(MRM)模式下检测,外标法定量。结果表明,乙拌磷及其代谢物在2.0~200.0 μg/L范围内线性关系良好,相关系数(R²)≥0.9981。方法的检出限(LOD)为0.02~2.0 μg/kg,并以最小添加水平5 μg/kg为定量限(LOQ)。乙拌磷及其代谢物在豌豆、芦笋、小麦、咖啡豆和花生中5、100、1000 μg/kg 3个添加水平下的平均回收率为75.0%~110.0%,相对标准偏差(RSD)为0.7%~14.9%,方法的准确度和精密度符合农药残留测定。应用建立的方法对市售的40份小麦样品和40份花生样品进行检测,均低于方法的检出限。该方法具有操作简单、快速、灵敏、准确的特点,适用于谷物、油料、蔬菜等多种农产品中乙拌磷及其代谢物的残留检测。

关键词: 超高效液相色谱-串联质谱, 分散固相萃取, 乙拌磷, 代谢物, 农产品

Abstract:

Disulfoton, an organophosphorus pesticide, is used to control cotton, beet, potato, and other seedling period aphids, leaf moths, underground pests, etc., with internal absorption, killing, gastric poisoning, and fumigation. Disulfoton is a highly toxic organophosphate pesticide, which can inhibit cholinesterase activity, resulting in neurophysiological disorders by inhalation, feeding, and transdermal absorption. Disulfoton is difficult to degrade in the environment, which leads to enrichment in organisms and interference with endocrine. This compound is harmful to the ecological environment and human health. To ensure the quality and safety of food, it is important to develop a detection method for disulfoton and its metabolites in agricultural products. A reliable method based on dispersive solid phase extraction (d-SPE) with ultra high performance liquid chromatography-tandem mass spectrometry (UHPLC-MS/MS) was developed for the determination of disulfoton and its metabolites (disulfoton sulfone, disulfoton sulfoxide, demeton-S, demeton-S sulfone, and demeton-S sulfoxide) in agricultural products (pea, asparagus, wheat, coffee bean, and peanut). The optimal extraction method was as follows: 5.0 g the samples were extracted with acetonitrile (wheat, coffee bean, and peanut presoaked in 5 mL water) in a 50 mL centrifuge tube, followed by 10 min vortex. Before 30 s vortex, 4 g NaCl was added. After 5 min centrifugation, 1.5 mL of the supernatant was cleaned up with 50 mg octadecylsilane bonded silica (C₁₈), 50 mg primary secondary amine (PSA), and 50 mg aminopropyl (NH₂) adsorbents. The analytes were separated on a Thermo Syncronis C₁₈ column (150 mm×2.1 mm, 5 μm) with gradient elution using water and acetonitrile at a column temperature of 40 ℃. The injection volume was 2 μL. Disulfoton and its metabolites were analyzed in multiple reaction monitoring (MRM) mode with positive electrospray ionization (ESI⁺) for the selective quantification. Qualitative and quantitative analyses were accorded to the retention times and characteristic ion pairs with one parent ion and two fragment ions. Quantitative analysis was performed by an external standard method using matrix-matched calibration curves. All the parameters that affected the extraction efficiencies were optimized. C₁₈, PSA, and NH₂ gave good recoveries of 87.9%-109.0%. Other adsorbents, multiwalled carbon nanotubes (MWCNTs), hydroxylated multiwalled carbon nanotubes (OH-MWCNTs), carboxylated multiwalled carbon nanotubes (COOH-MWCNTs), octylsilane bonded silica (C₈), strong cation exchange (SCX) and neutral alumina (N-Al₂O₃), led to recoveries below 56.2%. The combination of adsorbents was also considered. Seven different combinations of 50 mg C₁₈, 50 mg PSA, and 50 mg NH₂ were chosen for the optimization experiments. There were no obvious differences in these combinations, and the target analytes recoveries ranged from 81.0% to 109.3% with relative standard deviations (RSDs) between 0.6% and 12.5%. The matrix effect could affect the extraction efficiency. The adsorbents of 50 mg C₁₈, 50 mg PSA, and 50 mg NH₂ showed weaker matrix effects as compared with other combinations of adsorbents in the instrument. The results for the matrix effect showed that peanuts and asparagus exceeded 20%, requiring matrix-matched calibration curves. Under the optimized conditions, disulfoton and its metabolites showed good linearities (R²≥0.9981) in the range of 2.0-200.0 μg/L. The average spiked recoveries of disulfoton and its metabolites in peas, asparagus, wheat, peanuts, and coffee beans ranged from 75.0% to 110.0%, with RSDs of 0.7% to 14.9%. The limits of detection (LODs) were between 0.02 and 2.0 μg/kg, and the limits of quantification (LOQs) were 5.0 μg/kg. The method was applied for the detection of 80 commercial productions, and neither disulfoton nor its metabolites were found. The proposed method is rapid, accurate, highly selective, and sensitive, and it is suitable for the simultaneous determination of disulfoton and its metabolites in grain, oil crops, vegetables, and other matrices.

Key words: ultra high performance liquid chromatography-tandem mass spectrometry (UHPLC-MS/MS), dispersive solid phase extraction (d-SPE), disulfoton, metabolites, agricultural products

中图分类号:

O658

孙强, 李玉博, 温广月, 王伟民, 董茂锋, 唐红霞. 分散固相萃取-超高效液相色谱-串联质谱法测定农产品中乙拌磷及其代谢物[J]. 色谱, 2022, 40(2): 130-138.

SUN Qiang, LI Yubo, WEN Guangyue, WANG Weimin, DONG Maofeng, TANG Hongxia. Determination of disulfoton and its metabolites in agricultural products by dispersive soild phase extraction-ultra high performance liquid chromatography-tandem mass spectrometry[J]. Chinese Journal of Chromatography, 2022, 40(2): 130-138.

图/表 5

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Compound	Retention time/min	Precursor ion (m/z)	Product ion (m/z)	Collision energy/V
Disulfoton	5.59	275.00	61.05^*	-33
			89.15	-22
Disulfoton sulfone	5.32	307.05	97.00^*	-33
			125.10	-18
Disulfoton sulfoxide	4.87	291.00	213.05^*	-10
			185.00	-14
Demeton-S	5.27	259.05	89.05^*	-22
			61.00	-34
Demeton-S sulfone	4.02	291.05	263.00^*	-13
			235.00	-16
Demeton-S sulfoxide	3.58	275.00	141.05^*	-21
			197.05	-12

Compound	Retention time/min	Precursor ion (m/z)	Product ion (m/z)	Collision energy/V
Disulfoton	5.59	275.00	61.05^*	-33
			89.15	-22
Disulfoton sulfone	5.32	307.05	97.00^*	-33
			125.10	-18
Disulfoton sulfoxide	4.87	291.00	213.05^*	-10
			185.00	-14
Demeton-S	5.27	259.05	89.05^*	-22
			61.00	-34
Demeton-S sulfone	4.02	291.05	263.00^*	-13
			235.00	-16
Demeton-S sulfoxide	3.58	275.00	141.05^*	-21
			197.05	-12

Compound	Matrix	Regression equation	R²	LOD/ (μg/kg)	Recoveries (RSDs) (n=5)/%
Compound	Matrix	Regression equation	R²	LOD/ (μg/kg)	5 μg/kg	100 μg/kg	1000 μg/kg
Disulfoton	pea	y=9.29×10²x-1.55×10³	0.9981	2.0	93.6 (13.7)	90.4 (10.7)	89.0 (9.5)
	asparagus	y=4.60×10²x-6.20×10²	0.9988	2.0	93.8 (14.4)	97.8 (7.9)	96.0 (3.8)
	wheat	y=2.49×10²x+4.66×10²	0.9996	2.0	79.6 (10.8)	84.0 (12.1)	83.4 (9.1)
	peanut	y=2.64×10²x-3.91×10²	0.9983	2.0	99.2 (9.3)	95.0 (9.2)	104.2 (6.3)
	coffee bean	y=7.16×10²x+4.95×10²	0.9995	2.0	81.6 (9.1)	76.4 (7.3)	103.2 (6.4)
Disulfoton sulfone	pea	y=2.94×10⁴x-4.97×10⁴	0.9986	0.1	79.4 (4.8)	106.6 (6.9)	75.0 (3.3)
	asparagus	y=7.04×10³x-8.24×10³	0.9991	0.2	101.0 (7.8)	102.6 (5.5)	80.2 (2.8)
	wheat	y=4.15×10³x-3.91×10³	0.9994	0.5	79.2 (9.8)	81.2 (10.8)	79.8 (5.3)
	peanut	y=1.00×10⁴x+1.47×10⁴	0.9993	0.1	110.0 (6.6)	92.0 (7.7)	93.4 (4.3)
	coffee bean	y=1.32×10⁴x+1.59×10⁴	0.9998	0.09	80.4 (9.9)	103.0 (3.0)	103.2 (3.8)
Disulfoton sulfoxide	pea	y=1.61×10⁵x-2.25×10⁵	0.9999	0.02	104.4 (6.0)	99.0 (5.8)	83.6 (9.8)
	asparagus	y=3.62×10⁴x-3.58×10⁴	0.9993	0.05	90.6 (4.2)	106.4 (4.6)	99.4 (5.2)
	wheat	y=1.96×10⁴x+2.65×10⁴	0.9996	0.1	80.2 (14.9)	82.4 (6.5)	84.4 (8.7)
	peanut	y=7.27×10⁴x-1.03×10⁵	0.9997	0.04	93.8 (3.8)	89.0 (3.2)	92.8 (2.8)
	coffee bean	y=9.16×10⁴x-7.05×10⁴	0.9997	0.02	87.8 (10.3)	101.0 (0.7)	101.8 (0.8)
Demeton-S	pea	y=5.04×10⁴x-5.38×10⁴	0.9997	0.04	88.8 (10.2)	86.4 (11.2)	105.0 (6.1)
	asparagus	y=1.96×10⁴x+1.56×10³	0.9999	0.1	93.4 (1.4)	100.6 (5.5)	105.0 (1.8)
	wheat	y=1.32×10⁴x+2.51×10⁴	0.9984	0.2	94.2 (11.4)	80.6 (8.4)	77.0 (4.9)
	peanut	y=4.03×10⁴x+1.39×10⁴	0.9997	0.04	88.6 (4.3)	90.2 (1.8)	99.2 (3.2)
	coffee bean	y=4.36×10⁴x+8.87×10⁴	0.9994	0.03	88.0 (2.8)	102.4 (1.5)	103.4 (3.3)
Demeton-S sulfone	pea	y=8.70×10⁴x-1.92×10⁵	0.9995	0.02	79.6 (6.6)	105.8 (7.3)	79.6 (6.7)
	asparagus	y=1.75×10⁴x-2.63×10⁴	0.9993	0.1	88.6 (9.3)	107.6 (7.4)	86.2 (3.1)
	wheat	y=7.86×10³x-1.19×10⁴	0.9994	0.3	83.2 (14.7)	76.2 (5.8)	79.8 (9.1)
	peanut	y=4.12×10⁴x-6.54×10⁴	0.9988	0.04	105.8 (5.2)	85.6 (6.0)	87.6 (2.5)
	coffee bean	y=5.16×10⁴x+8.34×10³	0.9999	0.04	96.0 (11.7)	96.2 (0.9)	93.0 (1.7)
Demeton-S sulfoxide	pea	y=7.47×10⁴x-5.29×10⁴	0.9999	0.03	96.6 (3.0)	104.0 (6.8)	94.2 (8.5)
	asparagus	y=2.97×10⁴x+5.01×10⁴	0.9997	0.06	95.4 (5.2)	105.8 (7.9)	105.8 (3.6)
	wheat	y=8.12×10³x-1.08×10⁴	0.9991	0.3	81.4 (14.0)	86.2 (3.0)	86.0 (6.8)
	peanut	y=5.78×10⁴x-6.57×10⁴	0.9995	0.03	84.8 (10.9)	87.0 (13.0)	87.0 (1.4)
	coffee bean	y=8.99×10⁴x+1.44×10⁵	0.9995	0.02	103.0 (7.3)	90.8 (1.4)	93.2 (3.3)

Compound	Matrix	Regression equation	R²	LOD/ (μg/kg)	Recoveries (RSDs) (n=5)/%
Compound	Matrix	Regression equation	R²	LOD/ (μg/kg)	5 μg/kg	100 μg/kg	1000 μg/kg
Disulfoton	pea	y=9.29×10²x-1.55×10³	0.9981	2.0	93.6 (13.7)	90.4 (10.7)	89.0 (9.5)
	asparagus	y=4.60×10²x-6.20×10²	0.9988	2.0	93.8 (14.4)	97.8 (7.9)	96.0 (3.8)
	wheat	y=2.49×10²x+4.66×10²	0.9996	2.0	79.6 (10.8)	84.0 (12.1)	83.4 (9.1)
	peanut	y=2.64×10²x-3.91×10²	0.9983	2.0	99.2 (9.3)	95.0 (9.2)	104.2 (6.3)
	coffee bean	y=7.16×10²x+4.95×10²	0.9995	2.0	81.6 (9.1)	76.4 (7.3)	103.2 (6.4)
Disulfoton sulfone	pea	y=2.94×10⁴x-4.97×10⁴	0.9986	0.1	79.4 (4.8)	106.6 (6.9)	75.0 (3.3)
	asparagus	y=7.04×10³x-8.24×10³	0.9991	0.2	101.0 (7.8)	102.6 (5.5)	80.2 (2.8)
	wheat	y=4.15×10³x-3.91×10³	0.9994	0.5	79.2 (9.8)	81.2 (10.8)	79.8 (5.3)
	peanut	y=1.00×10⁴x+1.47×10⁴	0.9993	0.1	110.0 (6.6)	92.0 (7.7)	93.4 (4.3)
	coffee bean	y=1.32×10⁴x+1.59×10⁴	0.9998	0.09	80.4 (9.9)	103.0 (3.0)	103.2 (3.8)
Disulfoton sulfoxide	pea	y=1.61×10⁵x-2.25×10⁵	0.9999	0.02	104.4 (6.0)	99.0 (5.8)	83.6 (9.8)
	asparagus	y=3.62×10⁴x-3.58×10⁴	0.9993	0.05	90.6 (4.2)	106.4 (4.6)	99.4 (5.2)
	wheat	y=1.96×10⁴x+2.65×10⁴	0.9996	0.1	80.2 (14.9)	82.4 (6.5)	84.4 (8.7)
	peanut	y=7.27×10⁴x-1.03×10⁵	0.9997	0.04	93.8 (3.8)	89.0 (3.2)	92.8 (2.8)
	coffee bean	y=9.16×10⁴x-7.05×10⁴	0.9997	0.02	87.8 (10.3)	101.0 (0.7)	101.8 (0.8)
Demeton-S	pea	y=5.04×10⁴x-5.38×10⁴	0.9997	0.04	88.8 (10.2)	86.4 (11.2)	105.0 (6.1)
	asparagus	y=1.96×10⁴x+1.56×10³	0.9999	0.1	93.4 (1.4)	100.6 (5.5)	105.0 (1.8)
	wheat	y=1.32×10⁴x+2.51×10⁴	0.9984	0.2	94.2 (11.4)	80.6 (8.4)	77.0 (4.9)
	peanut	y=4.03×10⁴x+1.39×10⁴	0.9997	0.04	88.6 (4.3)	90.2 (1.8)	99.2 (3.2)
	coffee bean	y=4.36×10⁴x+8.87×10⁴	0.9994	0.03	88.0 (2.8)	102.4 (1.5)	103.4 (3.3)
Demeton-S sulfone	pea	y=8.70×10⁴x-1.92×10⁵	0.9995	0.02	79.6 (6.6)	105.8 (7.3)	79.6 (6.7)
	asparagus	y=1.75×10⁴x-2.63×10⁴	0.9993	0.1	88.6 (9.3)	107.6 (7.4)	86.2 (3.1)
	wheat	y=7.86×10³x-1.19×10⁴	0.9994	0.3	83.2 (14.7)	76.2 (5.8)	79.8 (9.1)
	peanut	y=4.12×10⁴x-6.54×10⁴	0.9988	0.04	105.8 (5.2)	85.6 (6.0)	87.6 (2.5)
	coffee bean	y=5.16×10⁴x+8.34×10³	0.9999	0.04	96.0 (11.7)	96.2 (0.9)	93.0 (1.7)
Demeton-S sulfoxide	pea	y=7.47×10⁴x-5.29×10⁴	0.9999	0.03	96.6 (3.0)	104.0 (6.8)	94.2 (8.5)
	asparagus	y=2.97×10⁴x+5.01×10⁴	0.9997	0.06	95.4 (5.2)	105.8 (7.9)	105.8 (3.6)
	wheat	y=8.12×10³x-1.08×10⁴	0.9991	0.3	81.4 (14.0)	86.2 (3.0)	86.0 (6.8)
	peanut	y=5.78×10⁴x-6.57×10⁴	0.9995	0.03	84.8 (10.9)	87.0 (13.0)	87.0 (1.4)
	coffee bean	y=8.99×10⁴x+1.44×10⁵	0.9995	0.02	103.0 (7.3)	90.8 (1.4)	93.2 (3.3)