超高效液相色谱-串联质谱法测定植物源性食品中环氧虫啶和哌虫啶残留

doi:10.3724/SP.J.1123.2024.04016

摘要/Abstract

摘要：

本研究建立了超高效液相色谱-串联质谱法同时检测植物源性食品中环氧虫啶和哌虫啶2个非对映异构体残留量的分析方法,优化了干制水果和茶叶等基质的提取方式,确定了净化填料C₁₈、PSA、GCB和无水硫酸镁的最佳用量。样品经乙腈提取,氯化钠盐析分层,采用基质分散固相萃取净化,经ACQUITY UPLC BEH C₁₈色谱柱(100 mm×2.1 mm, 1.7 μm)分离,外标法定量。结果表明:环氧虫啶和哌虫啶在各自范围内呈良好的线性关系,相关系数均大于0.99,该方法的定量限为0.01 mg/kg,满足GB 2763-2021和GB 2763.1-2022规定的限量要求。用建立的方法对植物源性食品(稻谷、糙米、小麦、大米、花生、葡萄干、甘蓝、生菜、四季豆、西红柿、土豆、香菇、苹果、柑橘和茶叶等)进行加标回收验证,结果表明:15种基质在定量限1倍、2倍、10倍或GB 2763限量水平的加标平均回收率为78%~110%, RSD为0~12.8%。用本方法对100批果蔬样品进行分析检测,结果显示,环氧虫啶和哌虫啶均未检出。该方法前处理简单,普适性强,可作为植物源性食品中环氧虫啶和哌虫啶的确证定量检测方法。

关键词: 超高效液相色谱-串联质谱法, 环氧虫啶, 哌虫啶, 植物源性食品

Abstract:

Neonicotinoid insecticides play an important role in the prevention and control of pests in crops, such as rice, wheat, corn, and vegetables, because of their broad spectrum, high efficiency, low toxicity, and low residue formation. However, their widespread use poses potential threats to the environment and human health. Cycloxaprid and paichongding are two new classes of neonicotinoid insecticides. The National Food Safety Standard Maximum Residue Limits for Pesticides in Foods (GB 2763) specifies the maximum residue limits for paichongding and cycloxaprid in rice, brown rice, wheat, and cabbage. However, the established limits are only temporary. In addition, no detection standards have yet been specified, and no relevant standards have been established in China. Therefore, establishing a method for analyzing cycloxaprid and paichongding residues in food is of particular importance. In this study, an optimized method was established to determine the residues of cycloxaprid and two noncorresponding isomers of paichongding in plant foods using ultra performance liquid chromatography-tandem mass spectrometry. The chromatographic conditions, matrix extraction methods for dried fruits and tea, and amounts of the purification materials C₁₈, PSA, GCB, and anhydrous magnesium sulfate were optimized. The pesticides were extracted using an acetonitrile solution and separated from water with the addition of sodium chloride. The samples were centrifuged at 5000 r/min for 5 min, after which 1.00 mL of the supernatant was purified using 150 mg of anhydrous magnesium sulfate, 25 mg of C₁₈, 25 mg of PSA, and 10 mg of GCB. Cycloxaprid and paichongding were separated on a ACQUITY UPLC BEH C₁₈ chromatographic column (100 mm×2.1 mm, 1.7 μm) via gradient elution with 0.1% formic acid aqueous solution containing 5 mmol/L ammonium formate-acetonitrile as the mobile phase, and detected in electrospray positive ionization mode coupled with multiple-reaction monitoring (MRM) mode. Quantitative analysis was performed using an external standard method. Cycloxaprid and paichongding demonstrated good linear relationships within their respective concentration ranges, and the corresponding correlation coefficients were all above 0.99. The limits of detection (S/N=3) and quantification were 0.05 μg/kg and 0.01 mg/kg, respectively, which meet the requirements specified in GB 2763-2021 and GB 2763.1-2022. The established method was used to validate the recoveries of cycloxaprid and paichongding spiked in foods of plant origin, such as paddy, brown rice, wheat, rice, peanut, raisin, cabbage, lettuce, green bean, tomato, potato, shiitake mushroom, apple, citrus, and tea substrates, at three levels. The spiked levels covered the limit levels specified in GB 2763-2021 and GB 2763.1-2022. The mean recoveries of the target substances added to the 15 substrates at concentrations of 1, 2, and 10 times the LOQ or the limit values specified in GB 2763-2021 and GB 2763.1-2022 were distributed between 78% and 110%, and the RSDs were within the range of 0-12.8%. One hundred batches of fruit and vegetable samples were analyzed using the developed method, and the results showed that the selected samples were not contaminated with either cycloxaprid or paichongding. The proposed method is simple, sensitive, and universal, and has wide coverage. Thus, it can be used as a confirmatory and quantitative detection method for epoxidine and piperidine in foods of plant origin.

Key words: ultra performance liquid chromatography-tandem mass spectrometry, cycloxaprid, paichongding, foods of plant origin

中图分类号:

O658

刘俊俊, 李菊, 余弯弯, 韩颖, 马欣欣, 占春瑞, 李仕祥, 伍华雯, 胡魁, 万建春. 超高效液相色谱-串联质谱法测定植物源性食品中环氧虫啶和哌虫啶残留[J]. 色谱, 2025, 43(3): 261-268.

LIU Junjun, LI Ju, YU Wanwan, HAN Ying, MA Xinxin, ZHAN Chunrui, LI Shixiang, WU Huawen, HU Kui, WAN Jianchun. Determination of cycloxaprid and paichongding residues in foods of plant origin by ultra performance liquid chromatography-tandem mass spectrometry[J]. Chinese Journal of Chromatography, 2025, 43(3): 261-268.

图/表 5

参考文献

[1]	Nie H Y, Yang R B, Zhao Y L, et al. Chinese Journal of Pesticide Science, 2016, 18(3): 352
[1]	聂红英, 杨仁斌, 赵运林, 等. 农药学学报, 2016, 18(3): 352
[2]	Xu X Y, Shao X S, Wu C Y, et al. World Pestcides, 2009, 31(4): 52
[2]	徐晓勇, 邵旭升, 吴重言, 等. 世界农药, 2009, 31(4): 52
[3]	Zhang J B. [MS Dissertation]. Hangzhou: Zhejiang University, 2014
[3]	张键波.[硕士学位论文]. 杭州: 浙江大学, 2014
[4]	GB 2763-2021
[5]	GB 2763.1-2022
[6]	Li J Y. [MS Dissertation]. Hangzhou: Zhejiang University, 2014
[6]	李菊英.[硕士学位论文]. 杭州: 浙江大学, 2014
[7]	Xie H, Zhu L S, Tan M Y. Acta Pedologica Sinica, 2016, 53(1): 232
[7]	谢慧, 朱鲁生, 谭梅英. 土壤学报, 2016, 53(1): 232
[8]	Zhang Y L, An G S, Liu B S, et al. Jiangsu Agricultural Sciences, 2021, 49(4): 66
[8]	张月亮, 安国顺, 刘宝生, 等. 江苏农业科学, 2021, 49(4): 66
[9]	Huang Q C, Dai C C, Zhang J P, et al. Xinjiang Agricultural Sciences, 2020, 57(11): 2050
[9]	黄庆超, 戴长春, 张建萍, 等. 新疆农业科学, 2020, 57(11): 2050
[10]	Zhang Y, Qu L J, Ling L, et al. Modern Preventive Medicine, 2024, 51(4): 722
[10]	张艳, 曲良娇, 凌莉, 等. 现代预防医学, 2024, 51(4): 722
[11]	Wang X, Zhang W Y, Wang M, et al. Chinese Journal of Analysis Laboratory, 2023, 42(7): 897
[11]	王霞, 张维谊, 王敏, 等. 分析试验室, 2023, 42(7): 897
[12]	Cong L J, Liu J S, Wang M Y, et al. Journal of Food Safety and Quality, 2014, 5(3): 912
[12]	丛路静, 刘纪松, 王美云, 等. 食品安全质量检测学报, 2014, 5(3): 912
[13]	Zhuang P, Ji S F, Xie H Y, et al. China Port Science and Technology, 2023, 5(3): 66
[13]	庄鹏, 纪少凡, 谢宏洋, 等. 中国口岸科学技术, 2023, 5(3): 66
[14]	SANTE 11312/2021
[15]	Xuan X Y. [MS Dissertation]. Guangzhou: Guangdong Pharmaceutical University, 2015
[15]	禤学怡.[硕士学位论文]. 广州: 广东药学院, 2015
[16]	Toshio F, Junkichi I, Corwin H. J Am Chem Soc, 1964, 86(23): 5175
[17]	GB 23200.121-2021
[18]	GB 23200.113-2018
[19]	EN 15662: 2018
[20]	Kardani F, Jelyani A Z, Hashemi M, et al. J Food Compos Anal, 2023: 124
[21]	Song W, Liu K Y, Chen L J, et al. Chinese Journal of Chromatography, 2024, 42(1): 52
[21]	宋伟, 刘开永, 陈莉君, 等. 色谱, 2024, 42(1): 52
[22]	Li J, Ju X, Wang Y L, et al. Chinese Journal of Chromatography, 2023, 41(7): 610
[22]	李洁, 鞠香, 王艳丽, 等. 色谱, 2023, 41(7): 610
[23]	Xu R H, Xie Q W, Li X J, et al. Chinese Journal of Chromatography, 2022, 40(5): 469
[23]	许芮菡, 谢倩文, 李旭军, 等. 色谱, 2022, 40(5): 469
[24]	Yan X X, Tong K X, Zhu Z H, et al. Journal of Instrumental Analysis, 2024, 43(4): 590
[24]	严晓贤, 仝凯旋, 朱浙辉, 等. 分析测试学报, 2024, 43(4): 590
[25]	Peng J, Mu Y C, Yu Y L, et al. Food Science, 2024, 45(3): 185
[25]	彭婕, 穆迎春, 喻亚丽, 等. 食品科学, 2024, 45(3): 185
[26]	Zhang J W, Wang Y H, Liu J N, et al. Chinese Journal of Analytical Chemistry, 2023, 51(11): 1802
[26]	张婧文, 王禹衡, 刘俊宁, 等. 分析化学, 2023, 51(11): 1802
[27]	Zhang S P, Zhou J. Journal of Instrumental Analysis, 2023, 42(10): 1301
[27]	张申平, 周静. 分析测试学报, 2023, 42(10): 1301
[28]	Yuan H F, Song S W, Gao H W, et al. China Tea, 2023, 45(8): 39
[28]	袁荷芳, 宋淑文, 高蕙文, 等. 中国茶叶, 2023, 45(8): 39
[29]	Li J, Wang Y L, Li F F, et al. Chinese Journal of Analytical Chemistry, 2023, 51(10): 1693
[29]	李洁, 王艳丽, 李芳芳, 等. 分析化学, 2023, 51(10): 1693
[30]	Xue X H, Li T T, Liu P, et al. Science and Technology of Food Industry, 2023, 44(4): 337
[30]	薛新花, 李婷婷, 刘盼, 等. 食品工业科技, 2023, 44(4): 337
[31]	Liu J J, Wang L M. China Food Additives, 2023, 34(5): 274
[31]	刘进进, 王利民. 中国食品添加剂, 2023, 34(5): 274
[32]	Tong L Y, Xu B Z, Nie X M, et al. Chinese Journal of Chromatography, 2023, 41(11): 986
[32]	童兰艳, 许博舟, 聂雪梅, 等. 色谱, 2023, 41(11): 986
[33]	Sapozhnikova Y, Lehotay S J. Anal Chim Acta, 2013, 758: 80
[34]	GB/T 27404-2008

Compound	Precursor ion (m/z)	Product ion (m/z)	RF lens/V	Collision energy/eV
Cycloxaprid	323.1	126.0^*	80	46
		277.1		15
(5R,7S)-	367.2	263.1^*	79	17
Paichongding		321.2		12
(5R,7R)-	367.2	263.1^*	79	17
Paichongding		321.2		12

Compound	Precursor ion (m/z)	Product ion (m/z)	RF lens/V	Collision energy/eV
Cycloxaprid	323.1	126.0^*	80	46
		277.1		15
(5R,7S)-	367.2	263.1^*	79	17
Paichongding		321.2		12
(5R,7R)-	367.2	263.1^*	79	17
Paichongding		321.2		12

No.	Influence factors				Recoveries/%
No.	C₁₈/mg	PSA/mg	GCB/mg	MgSO₄/mg	Tomatoes	Peanuts	Tea
Test 1 (cycloxaprid)	0	0	0	150	128	121	61.4
Test 1 (paichongding)					110	147	90.6
Test 2 (cycloxaprid)	0	25	10	300	128	167	60.3
Test 2 (paichongding)					115	149	82.2
Test 3 (cycloxaprid)	0	50	25	600	124	163	57.6
Test 3 (paichongding)					111	144	71.4
Test 4 (cycloxaprid)	25	0	10	600	117	111	65.1
Test 4 (paichongding)					107	136	88.7
Test 5 (cycloxaprid)	25	25	25	150	137	161	56.3
Test 5 (paichongding)					109	146	79.7
Test 6 (cycloxaprid)	25	50	0	300	145	155	56.4
Test 6 (paichongding)					111	143	76.2
Test 7 (cycloxaprid)	50	0	25	300	133	109	58.8
Test 7 (paichongding)					104	137	82.2
Test 8 (cycloxaprid)	50	25	0	600	141	154	56.9
Test 8 (paichongding)					107	139	78.6
Test 9 (cycloxaprid)	50	50	10	150	143	143	56.2
Test 9 (paichongding)					110	142	74.6
(cycloxaprid)/%	127^a, 151^b, 59.8^c	126^a, 114^b, 61.8^c	138^a, 143^b, 58.2^c	136^a, 142^b, 58.0^c
(paichongding)/%	112^a, 146^b, 81.4^c	107^a, 140^b, 87.2^c	109^a, 143^b, 81.8^c	110^a, 145^b, 81.6^c
(cycloxaprid)/%	133^a, 142^b, 59.3^c	136^a, 161^b, 57.8^c	130^a, 141^b, 60.5^c	135^a, 144^b, 58.5^c
(paichongding)/%	109^a, 142^b, 81.5^c	111^a, 144^b, 80.2^c	111^a, 142^b, 81.8^c	110^a, 143^b, 80.2^c
(cycloxaprid)/%	139^a, 135^b, 57.3^c	138^a, 154^b, 56.7^c	132^a, 144^b, 57.6^c	128^a, 143^b, 59.9^c
(paichongding)/%	107^a, 139^b, 78.5^c	111^a, 143^b, 74.1^c	108^a, 142^b, 77.8^c	109^a, 140^b, 79.6^c
R (cycloxaprid)/%	12.4^a, 15.2^b, 2.47^c	11.3^a, 47.0^b, 5.03^c	8.50^a, 3.80^b, 3.00^c	8.60^a, 2.00^b, 1.90^c
R (paichongding)/%	4.63^a, 7.40^b, 3.07^c	3.83^a, 4.33^b, 13.1^c	2.77^a, 0.633^b, 4.07^c	1.70^a, 4.83^b, 2.07^c

No.	Influence factors				Recoveries/%
No.	C₁₈/mg	PSA/mg	GCB/mg	MgSO₄/mg	Tomatoes	Peanuts	Tea
Test 1 (cycloxaprid)	0	0	0	150	128	121	61.4
Test 1 (paichongding)					110	147	90.6
Test 2 (cycloxaprid)	0	25	10	300	128	167	60.3
Test 2 (paichongding)					115	149	82.2
Test 3 (cycloxaprid)	0	50	25	600	124	163	57.6
Test 3 (paichongding)					111	144	71.4
Test 4 (cycloxaprid)	25	0	10	600	117	111	65.1
Test 4 (paichongding)					107	136	88.7
Test 5 (cycloxaprid)	25	25	25	150	137	161	56.3
Test 5 (paichongding)					109	146	79.7
Test 6 (cycloxaprid)	25	50	0	300	145	155	56.4
Test 6 (paichongding)					111	143	76.2
Test 7 (cycloxaprid)	50	0	25	300	133	109	58.8
Test 7 (paichongding)					104	137	82.2
Test 8 (cycloxaprid)	50	25	0	600	141	154	56.9
Test 8 (paichongding)					107	139	78.6
Test 9 (cycloxaprid)	50	50	10	150	143	143	56.2
Test 9 (paichongding)					110	142	74.6
(cycloxaprid)/%	127^a, 151^b, 59.8^c	126^a, 114^b, 61.8^c	138^a, 143^b, 58.2^c	136^a, 142^b, 58.0^c
(paichongding)/%	112^a, 146^b, 81.4^c	107^a, 140^b, 87.2^c	109^a, 143^b, 81.8^c	110^a, 145^b, 81.6^c
(cycloxaprid)/%	133^a, 142^b, 59.3^c	136^a, 161^b, 57.8^c	130^a, 141^b, 60.5^c	135^a, 144^b, 58.5^c
(paichongding)/%	109^a, 142^b, 81.5^c	111^a, 144^b, 80.2^c	111^a, 142^b, 81.8^c	110^a, 143^b, 80.2^c
(cycloxaprid)/%	139^a, 135^b, 57.3^c	138^a, 154^b, 56.7^c	132^a, 144^b, 57.6^c	128^a, 143^b, 59.9^c
(paichongding)/%	107^a, 139^b, 78.5^c	111^a, 143^b, 74.1^c	108^a, 142^b, 77.8^c	109^a, 140^b, 79.6^c
R (cycloxaprid)/%	12.4^a, 15.2^b, 2.47^c	11.3^a, 47.0^b, 5.03^c	8.50^a, 3.80^b, 3.00^c	8.60^a, 2.00^b, 1.90^c
R (paichongding)/%	4.63^a, 7.40^b, 3.07^c	3.83^a, 4.33^b, 13.1^c	2.77^a, 0.633^b, 4.07^c	1.70^a, 4.83^b, 2.07^c

Compound	MEs/%
Compound	Paddy	Tea	Cabbage	Citrus
Cycloxaprid	758	90	86	65
(5R,7S)-Paichongding	819	89	92	81
(5R,7R)-Paichongding	893	90	113	92