氟啶虫酰胺和螺虫乙酯在猕猴桃园中的降解及膳食风险评估

doi:10.16420/j.issn.0513-353x.2023-0416

园艺学报 ›› 2024, Vol. 51 ›› Issue (6): 1386-1402.doi: 10.16420/j.issn.0513-353x.2023-0416

氟啶虫酰胺和螺虫乙酯在猕猴桃园中的降解及膳食风险评估

乔成奎¹, 庄明², 田发军¹, 王彩霞¹, 庞涛¹, 陈如霞¹, 李晓光¹, 成昕³, 谢汉忠¹^,^*()

¹ 中国农业科学院郑州果树研究所，农业农村部果品质量安全风险评估实验室（郑州），郑州 450009
² 中国农业大学理学院，北京 100193
³ 农业农村部农产品质量安全中心，北京 100081

收稿日期:2024-01-27 修回日期:2024-04-28 出版日期:2024-12-18 发布日期:2024-06-22
通讯作者:
* E-mail：xiehanzhong@caas.cn
基金资助:
中国农业科学院科技创新工程专项(CAAS-ASTIP-2023-ZFRI-09); 2022年国家农产品质量安全风险评估专项(GJFP20220202); 中央级公益性科研院所基本科研业务费专项(1610192023312)

Degradation Behaviors and Dietary Risk Assessment of Flonicamid and Spirotetramat in Kiwifruit Plantations

QIAO Chengkui¹, ZHUANG Ming², TIAN Fajun¹, WANG Caixia¹, PANG Tao¹, CHEN Ruxia¹, LI Xiaoguang¹, CHENG Xin³, XIE Hanzhong¹^,^*()

¹ Laboratory of Quality and Safety Risk Assessment for Fruit（Zhengzhou），Ministry of Agriculture and Rural Affairs；Zhengzhou Fruit Research Institute，Chinese Academy of Agricultural Sciences，Zhengzhou 450009，China
² College of Science，China Agricultural University，Beijing 100193，China
³ The Center for Agri-Food Quality & Safety，Ministry of Agriculture and Rural Affairs，Beijing 100081，China

Received:2024-01-27 Revised:2024-04-28 Published:2024-12-18 Online:2024-06-22

摘要/Abstract

摘要：

建立了高效液相色谱—三重四极杆串联质谱对猕猴桃果实和果园土壤中氟啶虫酰胺及其3种代谢物，螺虫乙酯及其4种代谢物的残留同时检测的方法，优化了净化条件。样品经1%乙酸乙腈涡旋提取，十八烷基键合相硅胶（C18）净化，多反应监测模式检测。氟啶虫酰胺及其3种代谢物和螺虫乙酯及其4种代谢物在0.005 ~ 1.000 mg · L^-1质量浓度范围内线性关系良好，决定系数为0.9921 ~ 0.9999；在猕猴桃和土壤中的基质效应为0.04 ~ 1.04，采用基质标准曲线进行定量分析；在0.005 ~ 0.500 mg · kg^-1的添加水平下，各化合物的平均回收率为71% ~ 117%，相对标准偏差为0.3% ~ 10.5%；适用于猕猴桃和土壤中氟啶虫酰胺及其3种代谢物，螺虫乙酯及其4种代谢物残留的快速检测。残留试验结果显示，氟啶虫酰胺和螺虫乙酯在猕猴桃和土壤中的消解动态符合一级动力学方程；相比单独施用，混合施用对氟啶虫酰胺在猕猴桃和土壤中的半衰期均有影响，而对螺虫乙酯无显著影响。混合施用时，土壤中螺虫乙酯的代谢物残留量显著增加甚至高于螺虫乙酯母体，尤其是代谢物S-enol。最终残留检测结果显示，在果实中检出了氟啶虫酰胺及其代谢物TFNG，螺虫乙酯及其代谢物S-mono、S-keto和S-enol，残留量在0.005 ~ 3.445 mg · kg^-1之间；在土壤中只检出了螺虫乙酯代谢物S-keto和S-enol残留。相关性分析表明，氟啶虫酰胺和螺虫乙酯及其代谢物在猕猴桃果实中的，螺虫乙酯代谢物在土壤中的残留量均与施药剂量、施药次数呈正相关，与采收间隔期呈负相关。膳食风险评估结果表明，氟啶虫酰胺和螺虫乙酯的短期膳食摄入风险可接受；螺虫乙酯对普通人群没有长期膳食摄入风险，而氟啶虫酰胺可能对普通人群存在长期膳食摄入风险。

关键词: 氟啶虫酰胺, 螺虫乙酯, 农药残留, 猕猴桃, 代谢物, 联合使用, 风险评估

Abstract:

A high performance liquid chromatography-triple quadrupole tandem mass spectrometry （HPLC-MS/MS）method was established for the simultaneous determination of residues of flonicamid and its three metabolites，as well as spirotetramat and its four metabolites in kiwifruits and soil. The cleanup sorbents was optimized. The samples were extracted by acetonitrile with 1% acetic acid，cleaned-up by octadecyl bonded silica gel（C18），and detected in multiple reaction monitoring（MRM）mode. The good linear relationships were obtained for the nine target compounds within the mass concentration range of 0.005-1.000 mg · L^-1，and the determination coefficients were 0.9921 to 0.9999. The matrix effects in kiwifruits and soil were 0.04-1.04，and the matrix-matched calibration curves were used for quantification. At the spiking levels of 0.005-0.500 mg · kg^-1，the average recoveries were 71%-117%，and the relative standard deviations were 0.3%-10.5%. The method was suitable for rapid detection of flonicamid and its three metabolites，as well as spirotetramat and its four metabolites residues in kiwifruits and soil. The results of the residue tests showed that the degradation dynamics of flonicamid and spirotetramat in kiwifruits and soil followed the first-order kinetic equations. Compared to individual applications，mixed applications had an impact on the half-lives of flonicamid in both kiwifruits and soil，while it had no significant effect on spirotetramat. The residual amount of the metabolites of spirotetramat，especially the metabolite S-enol，significantly increased or even exceeded that of the parent in the soil under the mixed application condition. The final residue results showed that the residues of flonicamid and its metabolite TFNG，as well as spirotetramat and its metabolites S-mono，S-keto and S-enol were detected in kiwifruit samples，and the residues ranged from 0.005 to 3.445 mg · kg^-1. However，only residues of two metabolites of spirotetramat，S-keto and S-enol，were detected in the soil，and no other compounds were detected. Correlation analysis showed that the residual amounts of flonicamid，spirotetramat and their metabolites in kiwifruits and soil were positively correlated with the dosage and frequency of application，and were negatively correlated with the harvest interval. The results of dietary risk assessment indicated that the short-term dietary intake risk of flonicamid and spirotetramat was acceptable. The residues of spirotetramat had no long-term dietary risk to the general population，while flonicamid might pose a long-term dietary risk to the general population.

Key words: flonicamid, spirotetramat, pesticide residue, kiwifruit, metabolites, joint application, risk assessment

乔成奎, 庄明, 田发军, 王彩霞, 庞涛, 陈如霞, 李晓光, 成昕, 谢汉忠. 氟啶虫酰胺和螺虫乙酯在猕猴桃园中的降解及膳食风险评估[J]. 园艺学报, 2024, 51(6): 1386-1402.

QIAO Chengkui, ZHUANG Ming, TIAN Fajun, WANG Caixia, PANG Tao, CHEN Ruxia, LI Xiaoguang, CHENG Xin, XIE Hanzhong. Degradation Behaviors and Dietary Risk Assessment of Flonicamid and Spirotetramat in Kiwifruit Plantations[J]. Acta Horticulturae Sinica, 2024, 51(6): 1386-1402.

图/表 9

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分析物 Analyte	母离子/（m/z） Precursor ion	子离子/（m/z） Product ion	碎裂电压/V Fragmentor	碰撞电压/eV Collision energy
氟啶虫酰胺 Flonicamid	230.1	203^* 148	100 100	10 30
TFNG	249.1	203.1^* 148.1	100 100	20 30
TFNA	192.1	148^* 98.1	100 100	20 30
TFNA-AM	191.2	148.1^* 98.2	100 100	15 30
螺虫乙酯 Spirotetramat	374.3	330.2^* 302.1	120 120	10 10
S-mono	304.3	254.1^* 211	80 80	15 15
S-keto	318.2	300.2^* 214.2	80 80	10 20
S-enol	302.3	270.1^* 216.1	120 120	15 20
S-glu	464.3	302.2^* 216	100 100	10 40

分析物 Analyte	母离子/（m/z） Precursor ion	子离子/（m/z） Product ion	碎裂电压/V Fragmentor	碰撞电压/eV Collision energy
氟啶虫酰胺 Flonicamid	230.1	203^* 148	100 100	10 30
TFNG	249.1	203.1^* 148.1	100 100	20 30
TFNA	192.1	148^* 98.1	100 100	20 30
TFNA-AM	191.2	148.1^* 98.2	100 100	15 30
螺虫乙酯 Spirotetramat	374.3	330.2^* 302.1	120 120	10 10
S-mono	304.3	254.1^* 211	80 80	15 15
S-keto	318.2	300.2^* 214.2	80 80	10 20
S-enol	302.3	270.1^* 216.1	120 120	15 20
S-glu	464.3	302.2^* 216	100 100	10 40

化合物 Compound	纯试剂 Pure reagent		猕猴桃提取液 Kiwifruit extract			土壤提取液 Soil extract
化合物 Compound	线性方程 Linear equation	R²	线性方程 Linear equation	R²	基质效应 ME	线性方程 Linear equation	R²	基质效应 ME
氟啶虫酰胺 Flonicamid	y = 892 031x + 6 186	0.9993	y = 300 635x + 917	0.9987	0.34	y = 696 014x + 2 090	0.9985	0.78
TFNG	y = 963 611x-9 401	0.9995	y = 156 714x + 851	0.9998	0.16	y = 692 249x-2 885	0.9998	0.72
TFNA	y = 609 987x-2 096	0.9999	y = 192 566x + 885	0.9980	0.32	y = 544 490x + 280	0.9974	0.89
TFNA-AM	y = 1 967 266x + 14 694	0.9986	y = 158 843x + 95	0.9999	0.08	y = 1 098 002x-569	0.9996	0.56
螺虫乙酯 Spirotetramat	y = 10 848 142x + 8 629	0.9986	y = 11 317 266x + 190 306	0.9948	1.04	y = 10 850 126x + 32 902	0.9998	1.00
S-mono	y = 3 370 128x + 65 269	0.9948	y = 2 794 685x + 39 195	0.9958	0.83	y = 2 852 474x + 23 808	0.9975	0.85
S-keto	y = 8 136 706x-48 279	0.9999	y = 5 988 633x + 68 312	0.9999	0.74	y = 7 364 950x-65 268	0.9995	0.91
S-enol	y = 2 700 996x + 73 673	0.9921	y = 597 521x + 8 260	0.9963	0.22	y = 496 361x-136	0.9987	0.18
S-glu	y = 7 469 927x + 198 991	0.9924	y = 279 669x-202	0.9998	0.04	y = 2 476 679x-32 100	0.9979	0.33

化合物 Compound	纯试剂 Pure reagent		猕猴桃提取液 Kiwifruit extract			土壤提取液 Soil extract
化合物 Compound	线性方程 Linear equation	R²	线性方程 Linear equation	R²	基质效应 ME	线性方程 Linear equation	R²	基质效应 ME
氟啶虫酰胺 Flonicamid	y = 892 031x + 6 186	0.9993	y = 300 635x + 917	0.9987	0.34	y = 696 014x + 2 090	0.9985	0.78
TFNG	y = 963 611x-9 401	0.9995	y = 156 714x + 851	0.9998	0.16	y = 692 249x-2 885	0.9998	0.72
TFNA	y = 609 987x-2 096	0.9999	y = 192 566x + 885	0.9980	0.32	y = 544 490x + 280	0.9974	0.89
TFNA-AM	y = 1 967 266x + 14 694	0.9986	y = 158 843x + 95	0.9999	0.08	y = 1 098 002x-569	0.9996	0.56
螺虫乙酯 Spirotetramat	y = 10 848 142x + 8 629	0.9986	y = 11 317 266x + 190 306	0.9948	1.04	y = 10 850 126x + 32 902	0.9998	1.00
S-mono	y = 3 370 128x + 65 269	0.9948	y = 2 794 685x + 39 195	0.9958	0.83	y = 2 852 474x + 23 808	0.9975	0.85
S-keto	y = 8 136 706x-48 279	0.9999	y = 5 988 633x + 68 312	0.9999	0.74	y = 7 364 950x-65 268	0.9995	0.91
S-enol	y = 2 700 996x + 73 673	0.9921	y = 597 521x + 8 260	0.9963	0.22	y = 496 361x-136	0.9987	0.18
S-glu	y = 7 469 927x + 198 991	0.9924	y = 279 669x-202	0.9998	0.04	y = 2 476 679x-32 100	0.9979	0.33

基质 Matrix	化合物 Compound	0.005 mg · kg^-1		0.050 mg · kg^-1		0.500 mg · kg^-1
基质 Matrix	化合物 Compound	平均回收率/% Average recovery rate	RSD/%	平均回收率/% Average recovery rate	RSD/%	平均回收率/% Average recovery rate	RSD/%
猕猴桃果实Kiwifruit fruit	氟啶虫酰胺Flonicamid	105	6.5	117	0.6	101	2.0
	TFNG	99	10.0	110	2.5	87	1.7
	TFNA	95	8.7	93	4.4	79	0.4
	TFNA-AM	87	6.4	94	2.2	81	3.0
	螺虫乙酯Spirotetramat	113	3.4	106	3.1	107	5.6
	S-mono	117	1.4	113	1.6	100	1.1
	S-keto	104	1.8	103	1.5	116	0.6
	S-enol	114	2.4	109	2.1	110	3.0
	S-glu	81	5.1	72	2.0	80	0.8
土壤Soil	氟啶虫酰胺Flonicamid	99	6.4	96	1.1	90	0.9
	TFNG	75	2.4	86	0.8	80	0.3
	TFNA	75	1.7	79	1.3	96	0.6
	TFNA-AM	72	3.2	74	2.9	71	1.2
	螺虫乙酯Spirotetramat	97	3.7	111	9.8	92	2.3
	S-mono	84	0.9	106	10.4	80	1.8
	S-keto	111	3.2	108	1.4	105	3.9
	S-enol	90	3.3	112	10.5	93	4.5
	S-glu	78	1.3	77	1.7	82	1.1

氟啶虫酰胺和螺虫乙酯在猕猴桃园中的降解及膳食风险评估

Degradation Behaviors and Dietary Risk Assessment of Flonicamid and Spirotetramat in Kiwifruit Plantations

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农药 Pesticide	施用方式 Application method	猕猴桃Kiwifruit				土壤Soil
农药 Pesticide	施用方式 Application method	消解方程 Dissipation equation	R	原始沉积量/ （mg · kg^-1） Initial residues	半衰期/d Half-lives	消解方程 Dissipation equation	R	原始沉积量/ （mg · kg^-1） Initial residues	半衰期/d Half-lives
氟啶虫酰胺 Flonicamid	单施Individual	C = 0.5338e^-0.210^t	0.952	0.52 ± 0.00 a	3.30 ± 0.04 a	C = 0.1593e^-0.261^t	0.900	0.14 ± 0.02 a	2.65 ± 0.36 a
氟啶虫酰胺 Flonicamid	混施Joint	C = 0.1843e^-0.175^t	0.904	0.16 ± 0.00 b	3.95 ± 0.03 b	C = 0.1293e^-0.515^t	0.994	0.13 ± 0.02 a	1.37 ± 0.23 b
螺虫乙酯 Spirotetramat	单施Individual	C = 0.4519e^-0.090^t	0.829	0.54 ± 0.01 a	7.68 ± 0.13 a	C = 0.4982e^-0.579^t	0.959	0.47 ± 0.10 a	1.21 ± 0.12 a
螺虫乙酯 Spirotetramat	混施Joint	C = 0.2723e^-0.096^t	0.855	0.32 ± 0.01 b	7.20 ± 0.28 a	C = 0.1028e^-0.547^t	0.956	0.11 ± 0.01 b	1.30 ± 0.25 a

基质 Matrix	施药剂量Application dose	施药次数Application times	采样间隔/d Sampling interval	平均残留量/（mg · kg^-1）Average residue （n = 3）
基质 Matrix	施药剂量Application dose	施药次数Application times	采样间隔/d Sampling interval	氟啶虫酰胺 Flonicamid	TFNG	TFNA	TFNA-AM	螺虫乙酯 Spirotetramat	S-mono	S-keto	S-enol	S-glu
猕猴桃果实 Kiwifruit fruit	低剂量 Low dose	2	28	0.045	0.012	—	—	0.060	0.006	0.087	0.580	—
			21	0.059	0.012	—	—	0.060	0.006	0.113	0.778	—
			14	0.058	0.013	—	—	0.094	0.006	0.093	0.981	—
			7	0.086	0.008	—	—	0.167	—	0.099	1.236	—
		3	28	0.078	0.020	—	—	0.074	0.009	0.179	0.949	—
			21	0.141	0.025	—	—	0.149	0.012	0.235	1.632	—
			14	0.082	0.024	—	—	0.103	0.007	0.154	1.201	—
			7	0.084	0.017	—	—	0.124	—	0.118	1.309	—
	高剂量 High dose	2	28	0.194	0.020	—	—	0.210	0.010	0.273	1.859	—
			21	0.179	0.019	—	—	0.262	0.007	0.254	2.089	—
			14	0.171	0.019	—	—	0.265	0.005	0.206	2.034	—
			7	0.166	0.008	—	—	0.335	—	0.133	1.971	—
		3	28	0.167	0.038	—	—	0.202	0.020	0.348	2.161	—
			21	0.206	0.018	—	—	0.290	0.009	0.325	2.134	—
			14	0.229	0.022	—	—	0.274	0.005	0.268	1.910	—
			7	0.302	0.028	—	—	0.517	—	0.338	3.445	—
土壤 Soil	低剂量 Low dose	2	28	—	—	—	—	—	—	—	—	—
			14	—	—	—	—	—	—	—	—	—
			7	—	—	—	—	—	—	0.005	—	—
		3	28	—	—	—	—	—	—	0.006	—	—
			14	—	—	—	—	—	—	—	0.011	—
			7	—	—	—	—	—	—	0.018	0.013	—
	高剂量 High dose	2	28	—	—	—	—	—	—	—	—	—
			14	—	—	—	—	—	—	—	0.006	—
			7	—	—	—	—	—	—	0.008	—	—
		3	28	—	—	—	—	—	—	0.005	—	—
			14	—	—	—	—	—	—	0.005	0.013	—
			7	—	—	—	—	—	—	—	0.039	—

施药剂量Application dose	施药次数Application times	采样间隔Sampling interval	氟啶虫酰胺 Flonicamid				螺虫乙酯 Spirotetramat
施药剂量Application dose	施药次数Application times	采样间隔Sampling interval	NEDI/ （mg · kg^-1bw）	%ADI/%	NESTI/ （mg · kg^-1 bw）	%ARfD/%	NED/ （mg · kg^-1bw）	%ADI/%	NESTI/ （mg · kg^-1bw）	%ARfD/%
低剂量 Low dose	2	28	0.0902	128.87	0.0006	/	0.0338	67.67	0.0120	1.20
		21	0.0902	128.88	0.0008	/	0.0340	68.07	0.0157	1.57
		14	0.0902	128.88	0.0008	/	0.0342	68.45	0.0192	1.92
		7	0.0902	128.91	0.0012	/	0.0345	69.02	0.0245	2.45
	3	28	0.0902	128.90	0.0011	/	0.0343	68.52	0.0199	1.99
		21	0.0903	128.96	0.0019	/	0.0350	69.96	0.0332	3.32
		14	0.0902	128.90	0.0011	/	0.0345	68.96	0.0240	2.40
		7	0.0836	119.43	0.0011	/	0.0346	69.12	0.0255	2.55
高剂量 High dose	2	28	0.0903	129.02	0.0026	/	0.0353	70.51	0.0384	3.84
		21	0.0903	129.00	0.0024	/	0.0355	70.96	0.0426	4.26
		14	0.0903	129.00	0.0023	/	0.0354	70.78	0.0409	4.09
		7	0.0903	128.99	0.0022	/	0.0353	70.64	0.0396	3.96
	3	28	0.0903	128.99	0.0023	/	0.0356	71.19	0.0447	4.47
		21	0.0903	129.03	0.0028	/	0.0356	71.21	0.0449	4.49
		14	0.0903	129.06	0.0031	/	0.0353	70.68	0.0400	4.00
		7	0.0904	129.13	0.0041	/	0.0370	73.91	0.0699	6.99

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氟啶虫酰胺和螺虫乙酯在猕猴桃园中的降解及膳食风险评估

Degradation Behaviors and Dietary Risk Assessment of Flonicamid and Spirotetramat in Kiwifruit Plantations

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