QuEChERS-liquid chromatography-tandem mass spectrometry for determination of 22 triazole pesticide residues in Chinese herbal medicines

doi:10.3724/SP.J.1123.2022.08005

Abstract

Abstract:

Eight well-known herbals in Zhejiang Province, Zhebawei, are commonly used as traditional Chinese herbal medicines owing to their rich active ingredients. However, the unavoidable use of pesticides during agricultural production has led to pesticide residue problems in these herbs. In this study, a simple, rapid, and accurate method was established to determine 22 triazole pesticide residues in Zhebawei. An improved QuEChERS method was used for sample pretreatment, and Rhizoma Atractylodis Macrocephalae was used as a representative sample. The sample was extracted with acetonitrile to eliminate some polar and nonpolar compounds, pigments, and other impurities, and the purification effects of multiwalled carbon nanotubes (MWCNTs), amino-modified multiwalled carbon nanotubes (MWCNTs-NH₂), carboxylated multiwalled carbon nanotubes (MWCNTs-COOH), crosslinked polyvinylpyrrolidone (PVPP), zirconium dioxide (ZrO₂), 3-(N,N-diethylamino)-propyltrimethoxysilane (PSA), octadecyl (C18), and graphitized carbon black (GCB) were compared. MWCNTs-COOH and C18 were selected as the purification adsorbents, and their dosages were systematically optimized. The combination of 10 mg of MWCNTs-COOH and 20 mg of C18 was eventually selected as the purification adsorbents. Liquid chromatography-tandem mass spectrometry (LC-MS/MS) was used for analysis, and box graphs were plotted to present the dispersion of each group of recoveries, thus enabling the identification of the data outliers, dispersion distribution, and data symmetry. The established method was systematically verified and showed good linearity over the concentration range of 1-200 μg/L (except for bromuconazole, epoxiconazole, and etaconazole) with correlation coefficients >0.99. The average recoveries of the 22 pesticides at spiked levels of 10, 20, 100, and 200 μg/kg were in the range of 77.0%-115% with relative standard deviations (RSDs) <9.4%. The limits of detection and quantification were 1-2.5 μg/kg and 10-20 μg/kg, respectively. The applicability of the developed method to other herbals was investigated at 100 μg/kg, and the average recoveries of the target pesticides in different matrices ranged from 76.4% to 123% with RSDs <12.2%. Finally, the method established was used to detect triazole pesticide residues in 30 actual Zhebawei samples. The results showed that triazole pesticides were present in Bulbus Fritillariae Thunbergii and Dendranthema Morifolium. Difenoconazole was detected in Bulbus Fritillariae Thunbergii at contents ranging from 41.4 μg/kg to 110 μg/kg, while difenoconazole, myclobutanil, triadimenol and propiconazole were detected in Dendranthema Morifolium at contents ranging from 16.1 μg/kg to 250 μg/kg. The established method can meet the requirements for the accurate quantitative analysis of triazole fungicides in Zhebawei.

Key words: liquid chromatography-tandem mass spectrometry (LC-MS/MS), triazole pesticide residues, Zhebawei, Chinese herbal medicines, carboxylated multi-wall carbon nanotubes

CLC Number:

O658

WANG Jiao, WU Tong, WANG Xinquan, LIU Zhenzhen, XU Hao, WANG Zhiwei, DI Shanshan, ZHAO Huiyu, QI Peipei. QuEChERS-liquid chromatography-tandem mass spectrometry for determination of 22 triazole pesticide residues in Chinese herbal medicines[J]. Chinese Journal of Chromatography, 2023, 41(4): 330-338.

Figures/Tables 9

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Compound	Retention time/min	Parent ion (m/z)	Product ions (m/z)	Q¹ pre bias/V	Collision energy/eV	Q³ pre bias/V
Azaconazole (氧环唑)	4.143	300.00	159.00^*, 231.00	-15, -15	-27, -17	-29, -23
Bitertanol (联苯三唑醇)	4.995	338.20	269.15^*, 99.10	-17, -17	-9, -15	-29, -18
Bromuconazole (糠菌唑)	4.491	377.90	158.90^*, 70.00	-19, -19	-28, -23	-30, -30
Cyproconazole (环丙唑醇)	4.464	292.10	70.05^*, 125.05	-30, -30	-20, -30	-27, -22
Difenoconazole (苯醚甲环唑)	5.167	406.10	251.00^*, 337.05	-30, -30	-25, -17	-27, -24
Epoxiconazole (氟环唑)	4.567	330.10	121.20^*, 141.10	-17, -17	-21, -18	-22, -25
Etaconazole (乙环唑)	4.615	327.90	159.20^*, 123.15	-16, -16	-28, -55	-18, -14
Fenbuconazole (腈苯唑)	4.601	336.90	125.05^*, 70.00	-26, -26	-27, -20	-25, -28
Flusilazole (腈苯唑)	4.647	316.10	165.10^*, 247.10	-30, -30	-29, -18	-30, -27
Flutriafol (粉唑醇)	3.992	302.10	123.00^*, 109.00	-15, -15	-28, -31	-22, -19
Hexaconazole (己唑醇)	5.031	314.10	70.20^*, 159.15	-15, -15	-21, -29	-28, -30
Ipconazole (种菌唑)	5.321	334.00	70.30^*, 125.20	-23, -23	-23, -47	-14, -14
Metconazole (叶菌唑)	5.015	320.00	70.10^*, 125.05	-23, -23	-40, -37	-28, -23
Myclobutanil (腈菌唑)	4.415	289.10	70.05^*, 125.05	-30, -30	-21, -30	-28, -22
Penconazole (戊菌唑)	4.876	284.10	70.00^*, 159.00	-14, -14	-17, -27	-27, -30
Propiconazole (丙环唑)	4.942	342.05	159.10^*, 205.10	-17, -17	-30, -18	-29, -21
Simeconazole (硅氟唑)	4.534	294.10	70.05^*, 135.05	-15, -15	-21, -21	-28, -24
Tebuconazole (戊唑醇)	4.835	308.10	70.10^*, 125.00	-22, -22	-22, -38	-27, -23
Tetraconazole (四氟醚唑)	4.495	372.00	159.05^*, 70.20	-27, -27	-31, -24	-29, -27
Triadimefon (三唑酮)	4.408	294.10	69.15^*, 197.05	-21, -21	-22, -15	-26, -21
Triadimenol (三唑醇)	4.487	296.10	70.05^*, 99.15	-15, -15	-11, -15	-29, -17
Uniconazole (烯效唑)	4.689	292.10	70.10^*, 125.00	-21, -21	-24, -28	-27, -23

Compound	Retention time/min	Parent ion (m/z)	Product ions (m/z)	Q¹ pre bias/V	Collision energy/eV	Q³ pre bias/V
Azaconazole (氧环唑)	4.143	300.00	159.00^*, 231.00	-15, -15	-27, -17	-29, -23
Bitertanol (联苯三唑醇)	4.995	338.20	269.15^*, 99.10	-17, -17	-9, -15	-29, -18
Bromuconazole (糠菌唑)	4.491	377.90	158.90^*, 70.00	-19, -19	-28, -23	-30, -30
Cyproconazole (环丙唑醇)	4.464	292.10	70.05^*, 125.05	-30, -30	-20, -30	-27, -22
Difenoconazole (苯醚甲环唑)	5.167	406.10	251.00^*, 337.05	-30, -30	-25, -17	-27, -24
Epoxiconazole (氟环唑)	4.567	330.10	121.20^*, 141.10	-17, -17	-21, -18	-22, -25
Etaconazole (乙环唑)	4.615	327.90	159.20^*, 123.15	-16, -16	-28, -55	-18, -14
Fenbuconazole (腈苯唑)	4.601	336.90	125.05^*, 70.00	-26, -26	-27, -20	-25, -28
Flusilazole (腈苯唑)	4.647	316.10	165.10^*, 247.10	-30, -30	-29, -18	-30, -27
Flutriafol (粉唑醇)	3.992	302.10	123.00^*, 109.00	-15, -15	-28, -31	-22, -19
Hexaconazole (己唑醇)	5.031	314.10	70.20^*, 159.15	-15, -15	-21, -29	-28, -30
Ipconazole (种菌唑)	5.321	334.00	70.30^*, 125.20	-23, -23	-23, -47	-14, -14
Metconazole (叶菌唑)	5.015	320.00	70.10^*, 125.05	-23, -23	-40, -37	-28, -23
Myclobutanil (腈菌唑)	4.415	289.10	70.05^*, 125.05	-30, -30	-21, -30	-28, -22
Penconazole (戊菌唑)	4.876	284.10	70.00^*, 159.00	-14, -14	-17, -27	-27, -30
Propiconazole (丙环唑)	4.942	342.05	159.10^*, 205.10	-17, -17	-30, -18	-29, -21
Simeconazole (硅氟唑)	4.534	294.10	70.05^*, 135.05	-15, -15	-21, -21	-28, -24
Tebuconazole (戊唑醇)	4.835	308.10	70.10^*, 125.00	-22, -22	-22, -38	-27, -23
Tetraconazole (四氟醚唑)	4.495	372.00	159.05^*, 70.20	-27, -27	-31, -24	-29, -27
Triadimefon (三唑酮)	4.408	294.10	69.15^*, 197.05	-21, -21	-22, -15	-26, -21
Triadimenol (三唑醇)	4.487	296.10	70.05^*, 99.15	-15, -15	-11, -15	-29, -17
Uniconazole (烯效唑)	4.689	292.10	70.10^*, 125.00	-21, -21	-24, -28	-27, -23

Analyte	Matrix effect	Recoveries (RSDs)/%								LOQ/ (μg/kg)	LOD/ (μg/kg)
Analyte	Matrix effect	10 μg/kg		20 μg/kg		100 μg/kg		200 μg/kg		LOQ/ (μg/kg)	LOD/ (μg/kg)
Azaconazole	0.2	115	(3.8)	103	(4.1)	105	(2.0)	101	(5.6)	10	2.0
Bitertanol	0.6	98.3	(3.3)	108	(4.4)	109	(2.4)	109	(3.5)	10	2.0
Bromuconazole	0.3	-		104	(9.2)	109	(2.2)	96.9	(4.1)	20	2.5
Cyproconazole	0.2	109	(4.2)	108	(2.5)	106	(1.5)	105	(5.4)	10	2.0
Difenoconazole	0.3	102	(4.0)	101	(4.7)	109	(3.0)	107	(3.2)	10	2.0
Epoxiconazole	0.2	-		99.0	(2.8)	105	(1.7)	103	(9.4)	20	2.5
Etaconazole	0.2	-		111	(3.4)	103	(2.1)	108	(4.8)	20	2.5
Fenbuconazole	0.3	109	(5.8)	107	(6.6)	107	(3.5)	103	(5.4)	10	1.0
Flusilazole	0.2	111	(7.4)	112	(4.6)	107	(1.6)	106	(3.6)	10	2.0
Flutriafol	0.4	115	(4.1)	110	(3.4)	108	(2.4)	109	(4.1)	10	2.0
Hexaconazole	0.4	110	(2.4)	103	(6.8)	108	(2.6)	111	(3.3)	10	1.5
Ipconazole	0.2	92.6	(8.9)	93.9	(0.9)	108	(3.4)	104	(7.2)	10	2.0
Metconazole	0.3	97.7	(2.2)	93.0	(6.8)	103	(1.9)	92.7	(2.4)	10	2.0
Myclobutanil	0.4	104	(2.9)	101	(2.6)	99.1	(1.5)	104	(5.1)	10	1.0
Penconazole	0.1	107	(3.8)	98.9	(8.1)	110	(2.2)	107	(9.2)	10	1.0
Propiconazole	0.3	102	(2.7)	94.0	(5.8)	111	(2.0)	106	(1.6)	10	2.0
Simeconazole	0.1	111	(4.0)	110	(2.2)	109	(4.4)	101	(8.0)	10	2.0
Tebuconazole	0.2	101	(3.4)	98.7	(2.6)	104	(4.0)	104	(3.7)	10	2.0
Tetraconazole	0.3	114	(8.2)	112	(7.6)	104	(1.7)	107	(5.9)	10	2.0
Triadimefon	0.3	77.0	(5.0)	98.0	(4.7)	102	(1.9)	103	(7.2)	10	1.5
Triadimenol	0.5	108	(6.6)	113	(4.5)	111	(1.6)	107	(6.0)	10	1.0
Uniconazole	0.2	95.9	(6.1)	99.0	(4.2)	98.7	(1.1)	98.0	(2.1)	10	2.0

Analyte	Matrix effect	Recoveries (RSDs)/%								LOQ/ (μg/kg)	LOD/ (μg/kg)
Analyte	Matrix effect	10 μg/kg		20 μg/kg		100 μg/kg		200 μg/kg		LOQ/ (μg/kg)	LOD/ (μg/kg)
Azaconazole	0.2	115	(3.8)	103	(4.1)	105	(2.0)	101	(5.6)	10	2.0
Bitertanol	0.6	98.3	(3.3)	108	(4.4)	109	(2.4)	109	(3.5)	10	2.0
Bromuconazole	0.3	-		104	(9.2)	109	(2.2)	96.9	(4.1)	20	2.5
Cyproconazole	0.2	109	(4.2)	108	(2.5)	106	(1.5)	105	(5.4)	10	2.0
Difenoconazole	0.3	102	(4.0)	101	(4.7)	109	(3.0)	107	(3.2)	10	2.0
Epoxiconazole	0.2	-		99.0	(2.8)	105	(1.7)	103	(9.4)	20	2.5
Etaconazole	0.2	-		111	(3.4)	103	(2.1)	108	(4.8)	20	2.5
Fenbuconazole	0.3	109	(5.8)	107	(6.6)	107	(3.5)	103	(5.4)	10	1.0
Flusilazole	0.2	111	(7.4)	112	(4.6)	107	(1.6)	106	(3.6)	10	2.0
Flutriafol	0.4	115	(4.1)	110	(3.4)	108	(2.4)	109	(4.1)	10	2.0
Hexaconazole	0.4	110	(2.4)	103	(6.8)	108	(2.6)	111	(3.3)	10	1.5
Ipconazole	0.2	92.6	(8.9)	93.9	(0.9)	108	(3.4)	104	(7.2)	10	2.0
Metconazole	0.3	97.7	(2.2)	93.0	(6.8)	103	(1.9)	92.7	(2.4)	10	2.0
Myclobutanil	0.4	104	(2.9)	101	(2.6)	99.1	(1.5)	104	(5.1)	10	1.0
Penconazole	0.1	107	(3.8)	98.9	(8.1)	110	(2.2)	107	(9.2)	10	1.0
Propiconazole	0.3	102	(2.7)	94.0	(5.8)	111	(2.0)	106	(1.6)	10	2.0
Simeconazole	0.1	111	(4.0)	110	(2.2)	109	(4.4)	101	(8.0)	10	2.0
Tebuconazole	0.2	101	(3.4)	98.7	(2.6)	104	(4.0)	104	(3.7)	10	2.0
Tetraconazole	0.3	114	(8.2)	112	(7.6)	104	(1.7)	107	(5.9)	10	2.0
Triadimefon	0.3	77.0	(5.0)	98.0	(4.7)	102	(1.9)	103	(7.2)	10	1.5
Triadimenol	0.5	108	(6.6)	113	(4.5)	111	(1.6)	107	(6.0)	10	1.0
Uniconazole	0.2	95.9	(6.1)	99.0	(4.2)	98.7	(1.1)	98.0	(2.1)	10	2.0

Compound	Recoveries (RSDs)/%
Compound	Bulbus Fritillariae Thunbergii	Radix paeoniae alba	Curcumae radix	Scrophulariae radix	Ophiopogonis radix	Dendranthema morifolium	Rhizoma corydalis
Azaconazole	97.8 (1.6)	105 (1.7)	104 (2.7)	102 (0.9)	104 (1.5)	103 (2.3)	97.0 (5.8)
Bitertanol	101 (2.2)	97.0 (2.5)	103 (1.5)	106 (0.9)	108 (1.6)	111 (5.1)	108 (5.5)
Bromuconazole	103 (2.9)	106 (2.9)	95.3 (3.9)	105 (2.1)	102 (3.3)	97.1 (4.7)	99.4 (4.6)
Cyproconazole	102 (1.4)	108 (3.8)	111 (3.0)	109 (1.5)	104 (2.2)	86.6 (2.6)	102 (6.1)
Difenoconazole	99.8 (0.7)	93.6 (1.3)	86.1 (1.9)	107 (0.7)	100 (2.1)	103 (3.4)	105 (2.0)
Epoxiconazole	98.4 (2.2)	107 (3.9)	94.6 (1.2)	91.6 (1.8)	109 (4.2)	102 (4.0)	104 (3.0)
Etaconazole	98.3 (1.3)	108 (1.6)	102 (1.3)	102 (2.7)	105 (1.9)	114 (7.7)	102 (3.7)
Fenbuconazole	100 (1.6)	98.1 (2.9)	105 (2.1)	107 (1.9)	108 (2.8)	111 (6.7)	108 (3.0)
Flusilazole	99.9 (1.3)	110 (2.5)	108 (2.4)	106 (1.6)	107 (1.9)	92.5 (2.8)	108 (2.4)
Flutriafol	95.4 (2.9)	91.5 (5.9)	109 (2.2)	101 (2.8)	110 (3.1)	98.5 (1.4)	100 (2.2)
Hexaconazole	98.8 (1.9)	104 (1.4)	105 (2.0)	107 (1.3)	104 (2.0)	116 (12)	105 (3.5)
Ipconazole	97.1 (1.8)	107 (1.7)	90.2 (2.4)	106 (2.0)	101 (1.8)	110 (4.0)	104 (1.8)
Metconazole	96.0 (0.9)	106 (1.4)	91.2 (1.3)	105 (2.2)	97.1 (1.6)	107 (6.7)	107 (1.6)
Myclobutanil	102 (1.0)	108 (1.8)	108 (2.3)	106 (0.9)	109 (1.7)	76.4 (5.4)	110 (3.0)
Penconazole	100 (1.8)	107 (1.2)	106 (2.1)	105 (2.3)	103 (1.1)	115 (2.5)	107 (3.0)
Propiconazole	102 (1.8)	105 (0.9)	109 (1.7)	104 (1.8)	104 (1.0)	108 (10)	104 (3.2)
Simeconazole	100 (1.0)	111 (4.8)	117 (1.3)	106 (1.4)	88.5 (10)	118 (3.0)	105 (1.0)
Tebuconazole	98.1 (0.9)	110 (3.7)	98.4 (1.5)	103 (0.8)	101 (1.0)	104 (1.4)	104 (4.3)
Tetraconazole	100 (1.2)	108 (2.2)	113 (3.1)	107 (1.3)	110 (1.6)	108 (2.6)	103 (2.9)
Triadimefon	101 (1.3)	109 (1.5)	107 (2.1)	105 (1.5)	105 (1.2)	112 (1.7)	117 (2.5)
Triadimenol	98.7 (1.8)	108 (1.7)	109 (2.2)	106 (1.3)	110 (9.4)	108 (1.0)	105 (3.5)
Uniconazole	93.8 (2.1)	105 (3.3)	91.3 (5.6)	96.3 (4.4)	93.3 (4.5)	123 (4.2)	109 (4.0)