Next Article in Journal
Modified Polyethersulfone Ultrafiltration Membrane for Enhanced Antifouling Capacity and Dye Catalytic Degradation Efficiency
Next Article in Special Issue
Development of a High-Throughput Screening Analysis for 195 Pesticides in Raw Milk by Modified QuEChERS Sample Preparation and Liquid Chromatography Quadrupole Time-of-Flight Mass Spectrometry
Previous Article in Journal
Chemical Profiling and Characterization of Different Cultivars of Cannabis sativa L. Inflorescences by SPME-GC-MS and UPLC-MS
Previous Article in Special Issue
Determination of Antibiotic Residues in Aquaculture Products by Liquid Chromatography Tandem Mass Spectrometry: Recent Trends and Developments from 2010 to 2020
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Separations
Volume 9
Issue 4
10.3390/separations9040091
separations-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

QuEChERS Method Combined with Gas- and Liquid-Chromatography High Resolution Mass Spectrometry to Screen and Confirm 237 Pesticides and Metabolites in Cottonseed Hull

by
Kaixuan Tong
1,
Yujie Xie
1,
Siqi Huang
2,
Yongcheng Liu
2,
Xingqiang Wu
1,
Chunlin Fan
1,
Hui Chen
1,*,
Meiling Lu
3 and
Wenwen Wang
3
1
Key Laboratory of Food Quality and Safety for State Market Regulation, Chinese Academy of Inspection and Quarantine, Beijing 100176, China
2
Laboratory of Heilongjiang Feihe Dairy Co., Ltd., Qiqihar 164800, China
3
Agilent Technologies (China) Limited, Beijing 100102, China
*
Author to whom correspondence should be addressed.
Separations 2022, 9(4), 91; https://doi.org/10.3390/separations9040091
Submission received: 8 March 2022 / Revised: 29 March 2022 / Accepted: 31 March 2022 / Published: 2 April 2022
(This article belongs to the Special Issue Advances of Accurate Quantification Methods in Food Analysis)
Browse Figures
Versions Notes

Abstract

:
Cottonseed hull is a livestock feed with large daily consumption. If pesticide residues exceed the standard, it is easy for them to be introduced into the human body through the food chain, with potential harm to consumer health. A method for multi-residue analysis of 237 pesticides and their metabolites in cottonseed hull was developed by gas-chromatography and liquid-chromatography time-of-flight mass spectrometry (GC-QTOF/MS and LC-QTOF/MS). After being hydrated, a sample was extracted with 1% acetic acid in acetonitrile, then purified in a clean-up tube containing 400 mg MgSO4, 100 mg PSA, and 100 mg C18. The results showed that this method has a significant effect in removing co-extracts from the oily matrix. The screening detection limit (SDL) was in the range of 0.2–20 μg/kg, and the limit of quantification (LOQ) was in the range of 0.2–20 μg/kg. The recovery was verified at the spiked levels of 1-, 2-, and 10-times LOQ (n = 6), and the 237 pesticides were successfully verified. The percentages of pesticides with recovery in the range of 70–120% were 91.6%, 92.8%, and 94.5%, respectively, and the relative standard deviations (RSDs) of all pesticides were less than 20%. This method was successfully applied to the detection of real samples. Finally, this study effectively reduced the matrix effect of cottonseed hull, which provided necessary data support for the analysis of pesticide residues in oil crops.

1. Introduction

The composition of cottonseed hull is similar to that of soybean concentrate, with a high content of cellulose that can enhance the digestive systems of ruminants. Cottonseed hull has been widely used as an alternative feed for ruminants, due to its low price, easy availability, and excellent mixing performance [1,2,3]. The excessive and illegal use of pesticides during forage planting makes it easy for pesticides to enter the food chain and accumulate in animal adipose tissue [4], and human consumers may indirectly experience food safety problems through contact with livestock products. The composition of the oily matrix is complex: in addition to fat, it contains polysaccharides, proteins, pigments, and other substances. In the process of residue analysis, problems such as matrix enhancement, matrix inhibition, and retention-time shifts may occur in the detection of pesticides, which will hinder the detection of target compounds [5,6]. Therefore, it is urgent to develop a detection technique for the oily matrix to solve these problems.
The analysis of pesticide residue usually includes the following steps: (1) extraction of the target compound; (2) removal of interference from the extract; and (3) qualitative and quantitative detection of the target compound [4]. Lipophilic pesticides tend to be concentrated in fat. Improper pretreatment will affect the detection sensitivity, recovery, and sample throughput [7]. The current pretreatment methods for plant-derived oil substrates mainly include dispersion liquid-liquid micro-extraction (DLLME) [8], matrix solid phase dispersion (MSPD) [9,10], low temperature fat precipitation (LTFP) [11], solid phase extraction (SPE) [5], and QuEChERS [12,13,14,15,16]. The QuEChERS method requires fewer reagent consumables and short pretreatment time, so it is accepted by more and more experimenters [17]. Theurillat et al. established the QuEChERS method to determine the residues of various pesticides and verified the method for 176 pesticides in six oily matrices [12]. Rutkowska et al. investigated the matrix effect and recovery of four seed samples of cress, fennel, flax, and hemp. The final method verified 248 pesticides, and the LOQs reached 0.005 mg/kg [14]. Banerjee et al. used the QuEChERS method to analyze more than 220 pesticide residues in sesame seeds. This method can effectively reduce the interference of the matrix effect by freezing and degreasing at −80 °C and then purifying the oil.
The current trend of separation science is to develop new chromatographic mass spectrometry methods that can detect multiple compounds at the same time after a single injection, thereby reducing analysis time and cost [18]. The current detection technology for the detection of pesticide residues in oily matrices is mainly triple quadrupole mass spectrometry (MS/MS) [13,19,20,21]. The data was collected according to the specific nucleo-cytoplasmic ratio of the specified compound, but other compounds that were not in the list could not be identified. When analyzing a large number of compounds, the sensitivity and selectivity are limited. Due to their high resolution, precise mass accuracy, outstanding full-scan sensitivity, and complete mass spectrometry information, high-resolution mass spectrometry (HRMS), such as time-of-flight mass spectrometry (TOF/MS) and quadrupole Orbitrap mass spectrometry (Obitrap/MS), can be used without additional sample injection. Under retrospective analysis, with these advantages, HRMS has been widely used in the field of food analysis [22,23]. Lehotay et al. used GC-TOF to analyze 34 pesticides in flaxseed, dough, and peanuts [15]. Amadeo et al. used GC-QTOF to verify 166 pesticide residues in avocados and almonds [24].
To ensure the safety of livestock feed and to prevent pesticide residues from being introduced into the human body through the food chain, this work established a QuEChERS multi-residue analysis method, and used GC- and LC-QTOF/MS techniques to verify 237 pesticides in cottonseed hull. By optimizing the hydration volume, extraction solvent, salting-out agent, and clean-up sorbents, the influence of the matrix effect was reduced and the pesticide recovery was optimized. Finally, this method was successfully applied to the analysis of actual samples, providing data support for the risk of pesticide residues in oily substrate monitoring.

2. Materials and Methods

2.1. Chemicals and Reagents

Pesticide standards (purity ≥ 98%) were obtained from Tianjin Alta Scientific (Tianjin, China). Sodium chloride, magnesium sulfate, and sodium sulfate (analytical purity) were obtained from Tianjin Fuchen Chemical Reagent Ltd. (Tianjin, China). Primary secondary amine (PSA) and C18 were purchased from Agilent Technologies (Santa Clara, CA, USA). Methanol, acetonitrile, and toluene (chromatographic purity) were obtained from Anpel Laboratory Technology (Shanghai, China). Formic acid and ammonium acetate (mass spectrometry grade) were obtained from Honeywell (Muskegon, MI, USA).

2.2. Apparatus

HPLC-QTOF/MS Agilent 1290 and Agilent 6550 equipped with Agilent Dual Jet Stream ESI and GC-QTOF/MS Agilent 7890B and Agilent 7200 were obtained from Agilent Technologies (Santa Clara, CA, USA). A Milli-QTM Ultrapure Water System was obtained from Millipore (Milford, MA, USA). An N-EVAP112 Nitrogen Blowing Concentrator was obtained from Organomation Associates (Worcester, MA, USA). An AH-30 Automatic homogenizer was obtained from RayKol Group Corp., Ltd. (Xiamen, China). An MS204S Electronic Analytical Balance was obtained from Mettler Toledo (Shanghai, China).

2.3. Standard Solution

Ten mg of the standard substance was accurately weighed into a 10 mL brown volumetric flask. a suitable reagent was selected according to the solubility of the compound in the organic reagent. It was dissolved by ultrasound and diluted to the mark to a standard solution of 1 mg/L. The standard solution was stored at −18 °C in the dark. As needed, a pipette with an appropriate amount of the standard stock solution was diluted with methanol to prepare a working solution of appropriate concentration, and stored at 4 °C in the dark.

2.4. Sample Preparation Method

Based on other oily matrix sample preparation methods [12,16], a modified QuEChERS method was used for the detection of cottonseed hull. Two g (accurate to ±0.01 g) of sample were transferred into a 50 mL centrifuge tube; 2 mL of ultrapure water were added for hydration and then extracted with 10 mL of 1% acetic acid in acetonitrile. The homogenizer was used to homogenize the sample for 1 min at 13,500× g; then, 4 g MgSO4, 1 g NaCl and a ceramic homoproton were added. The mixture was shaken for 10 min and centrifuged at 3155× g for 5 min; then, 3 mL of supernatant was transferred to a clean-up tube containing 400 mg MgSO4, 100 mg PSA, and 100 mg C18. After shaking for 10 min and being centrifuged at 3155× g for 5 min, 1 mL of supernatant was dried under nitrogen, then ultrasonically redissolved with ethyl acetate containing internal heptachlor-exo-epoxide for GC-QTOF/MS analysis, and ultrasonically redissolved with acetonitrile aqueous solution (2:3, v/v) containing internal standard atrazine D5 for LC-QTOF/MS analysis.

2.5. Instrument Parameters

The instrument parameters of LC-QTOF/MS and GC-QTOF/MS were configurated according to a previous paper published by our laboratory [25].
An LC-QTOF/MS: ZORBAX SB-C18 column (100 mm × 2.1 mm, 3.5 μm, Agilent Technologies) was used for separation at 40 °C; 5 mmol/L ammonium acetate with 0.1% (v/v) formic acid aqueous solution and acetonitrile were applied as phase A and phase B. The flow rate was set at 0.4 mL/min. The gradient program was set as follows: 0 min, 1% B; 3 min, 30% B; 6 min, 40% B; 9 min, 40% B; 15 min, 60% B; 19 min, 90% B; 23 min, 90% B; 23.01 min, 1% B. The equilibrium time was 4 min. The injection volume was 5 μL.
The Agilent Dual Jet Stream (AJS) ESI source (Agilent Technologies) was set in positive full scan (m/z 50–1000) mode; the capillary voltage was 4 kV; nitrogen was used as the nebulizer gas at 0.14 MPa; the sheath gas temperature was set at 375 °C with 11.0 L/min; the drying gas flow rate was 12.0 L/min; the drying gas temperature was 225 °C; the fragmentation voltage was 345 V. In all ions Mass/Mass mode, the collision energy was 0 V at 0 min, and 0, 15, and 35 V at 0.5 min, respectively. The total program duration was 27.01 min.
GC-QTOF/MS: HP-5 MS UI (30 m × 0.25 mm, 0.25 μm, Agilent Technologies) was used for separation at 40 °C. The oven temperature gradient was started at 40 °C for 1 min, increased at 30 °C/min to 130 °C, heated at 5 °C/min to 250 °C, ramped to 300 °C at 10 °C/min, and maintained for 7 min. Helium (purity > 99.999%) was used as the carrier gas with a constant flow rate of 1.2 mL/min. The injection temperature was set to 270 °C and the injection volume was 1 µL. The injection mode was not split injection, and the purge valve was opened after 1 min.
The ion source was an electronic ionization source (70 eV, 280 °C), and the temperatures of the transfer line and the quadrupole were 250 °C and 180 °C, respectively. Solvent delay was set to 3 min; the ion monitoring mode was full scan; scanning ranged (m/z) from 45 to 550; the scan rate was 5 Hz. The total program duration was 42 min.
Mass calibration was required before sample acquisition, and the instrument was tuned at intervals to ensure stability.

2.6. Method Validation

The screening method of high-resolution mass spectrometry can be validated through screening detection limits (SDL), and the quantitative method can be validated through limit of quantitation (LOQ). The SDL, LOQ, linearity, recovery, and precision of this experiment were verified by SANTE/12682/2019 guidelines. SDL is the minimum concentration at which more than 95% of a series of concentration levels meets the detection requirements (20 additional experiments were conducted in parallel for each concentration). When the SDL and recovery were validated, all the target pesticides were spiked to the sample and the spiked samples were placed at room temperature for 30 min, then treated according to the above method. After the 10-point matrix matching calibration was constructed, its linearity was evaluated with the coefficient of determination (R2). The recovery and precision were investigated in three different levels of spiked blank samples with 1-, 2-, and 10-times LOQ.
The matrix effect (ME) is the interference of other components in the matrix with the target compounds. The formula is:
ME (%) = (bm − bs)/bs × 100%
where bm is the slope of the matrix standard curve and bs is the slope of the solvent standard curve.
Based on previous studies, we established several hundred kinds of pesticide databases on gas and liquid high resolution mass spectrometry, respectively [25]. According to the recovery and precision, 237 pesticides were divided into pesticides suitable for GC or LC detection.

3. Results

3.1. Optimization of Hydration Volume

For the oily matrix, adding an appropriate amount of water for hydration during sample pretreatment was conducive to the softening of the matrix epidermis, making it easier for residual pesticides in the matrix to be extracted. This experiment explored the effect of different hydration volumes on the recovery of multiple pesticides. The experiment results show that the proportion of pesticides that met the recovery requirements (70–120%) under a non-hydration condition was 74.9%, which was less than under the conditions with water additions of 2 mL and 5 mL. Under the condition of a 2 mL water addition, the number of pesticides meeting the recovery requirements was the most numerous, accounting for 83.5%. As shown in Figure 1, the average recovery under the 2 mL condition was 88.3%, which was higher than that under the other two conditions. The results were in line with our expectations. The oil-water partition coefficient (logP) is an important parameter for the solubility of compounds, which is a simulated value based on the soil sorption coefficient normalized to organic carbon content (log Koc) [26]. The smaller the logP value, the better the water solubility of the compound. The effect of hydration volume on recovery with different logP was investigated, showing that hydration had a great impact on recovery with a low logP. The overall recovery of 54 pesticides with hydrophilic compounds (logP < 2.0) was low under a non-hydration condition, with the pesticides meeting the requirements accounting for 42.6%. When the hydration volume was 5 mL, the pores were opened due to the increase in the hydration volume, and multiple interferents in the matrix could be extracted together. The matrix promotion effect was enhanced, so that the overall recovery of pesticides with logP < 2.0 was higher than the recovery under the other two conditions. When the hydration volume was 2 mL, the pesticides that met the requirements of recovery were most numerous, accounting for 70.4%; therefore, 2 mL was finally selected as the optimal hydration volume.

3.2. Optimization of Extraction Solvent Volume

The extraction of target compounds is a critical step in pesticide residue analysis. Mol et al. [27] tested a series of solvents for extraction and found that methanol usually extracts too many compounds in the matrix, and further matrix removal steps were required. Acetonitrile has low solubility in fat and a low matrix effect when extracting from complex matrices. Therefore, acetonitrile was selected as the extraction solvent of cottonseed hull in this experiment. Three different extraction volumes of 10 mL, 16 mL, and 20 mL (i.e., a hydration volume and extraction volume ratio of 1:5, 1:8, and 1:10) were compared to explore the effect of different extraction volumes on the recovery of pesticide residues. The results are shown in Figure 2. It was found that when the extract volume was 10 mL, 16 mL, and 20 mL, the proportion of pesticides meeting the recovery requirements was similar, at 81.0%, 80.7% and 81.3% respectively. However, at the spiked level, the volume of the extraction solution decreased, the pesticide concentration per unit volume increased, and more pesticide compounds had better peak shapes. In addition, a lower organic reagent amount was recommended from the perspective of green environmental protection, so the final extraction volume was 10 mL.

3.3. Optimization of Salting-Out Agent

The salting-out agents commonly used in pesticide residue screening were EN buffer salt (4 g MgSO4, 1 g NaCl, 0.5 g disodium hydrogen citrate, and 1 g sodium citrate), the QuEChERS method for fruits and vegetables (4 g MgSO4 and 1 g NaCl), and AOAC buffer salt (6 g MgSO4 and 1.5 g NaAc). In this work, the effects of the above three salting-out agents on the recovery of pesticides were compared. As shown in Figure 3, although EN or AOAC salt forms a buffer system in the solution state, the results showed that the recovery using an MgSO4 + NaCl combination best met the requirements, accounting for 78%. The reason for this result was that the volume of the extract from the QuEChERS method was relatively small. If the amount of extraction salt was too large, the heat emitted during water absorption destroys the structure of thermally unstable pesticides and affects their recovery. Therefore, 4 g MgSO4 and 1 g NaCl with less salt consumption were finally selected as the salting-out agents.

3.4. Optimization of Types and Amounts of Clean-Up Sorbents

A clean-up procedure was a key step in the pretreatment of the oily matrix. Its purpose was to effectively purify the analyzed matrix, and most of target pesticides had acceptable recovery, precision, and matrix effect [14]. Although acetonitrile had low liposolubility, which can slightly reduce the interference of a fat-soluble matrix on target compounds [15], in order to effectively reduce the influence of high-fat matrix co-extraction on the detection sensitivity of pesticides, as well as instrument loss, the clean-up procedure was necessary. Theurillat established a d-SPE clean-up method containing 150 mg C18 and 150 mg PSA to determine 176 pesticide residues in fatty foods [12]. Therefore, this study was optimized on this basis.
In this work, the ability of MgSO4 + PSA + C18 + Z-sep and MgSO4 + PSA + C18 sorbents were compared. The structure of PSA had -NH2, which can form a strong hydrogen bond with -COOH, so it was often used to adsorb polar compounds, such as fatty acids, lipids, and carbohydrates. C18 was often used to adsorb non-polar compounds, such as long-chain aliphatic compounds and sterols [8,25]. Z-sep was a new adsorbent, based on zirconia, which can be used for the adsorption of hydrophobic compounds in the fat matrix [28]. It was seen that the bottom of the purification tube after Z-sep purification was dark yellow, while the sample without Z-sep purification was light yellow, indicating that Z-sep had an obvious effect on degreasing.
In order to further verify the ability of sorbents, the spiked experiments were carried out. As shown in Figure 4, A was the sorbent combination of MgSO4 + PSA + C18 + Z-sep, and B was the sorbent combination of MgSO4 + PSA + C18. As a result, the sorbent combination without Z-sep accounted for more pesticides that meet the requirements, reaching 81.04%. The reason for this result was that Z-sep adsorbs some target pesticides while removing lipids. According to the Lewis theory, the affinities of Z-sep on the analyte containing different substituent characteristics can be sorted in the following order: chloride < formate < acetate < sulphate< citrate < fluoride < phosphate < hydroxide [25]. In this work, a variety of pesticides, such as trinexapac-ethyl, abamectin containing -OH, fenamiphos sulfoxide containing phosphate, and sulfoxaflor containing sulphate, had substituents with a strong affinity to Z-sep. Therefore, the recovery of sorbent combinations with Z-sep was significantly lower than that without Z-sep. Although Z-sep was more efficient in removing lipid compounds, the sorbent combination of MgSO4 + PSA + C18 was finally selected as the purification filler in this work, from the perspective of method versatility.
The amount of PSA and C18 was also optimized. The effects of PSA (50–150 mg) and C18 (100–300 mg) on the recovery of various pesticides were optimized by controlling other variables. The results showed that when the amount of PSA was 100 mg, the greatest number of pesticides with satisfactory recovery was obtained, accounting for 73.7%. With the increase in PSA amount, the recovery of organic nitrogen pesticides, such as propanil and fenbuconazole, and carbamate pesticides, such as aldicarb-sulfone and thiophanate-methyl, gradually decreased. When the amount of C18 was 100 mg, the proportion of pesticides that met satisfactory recovery was 82.0%. With an increase in the C18 amount, the recovery of various organic nitrogen pesticides obviously decreased, especially the chlorides with a benzene ring structure, such as monolinuron, novaluron, propanil, and pretilachlor. Therefore, 100 mg PSA and 100 mg C18 were finally selected as the optimal amounts of clean-up sorbents.

3.5. Evaluation of Matrix Effect

Analysis of pesticide residues in the oil matrix may be adversely affected by the matrix effect. The main result of the matrix effect is to increase or decrease the analyte signal when the same analyte exists in the solvent [29]. The methods for eliminating or reducing the matrix effect include: (1) optimizing the sample preparation method and reducing co-extraction; (2) changing the chromatographic mass spectrometry conditions; (3) diluting the samples; and (4) using matrix-matched standards or an additional standard method [30]. In this work, the purifying agent was optimized, and the matrix-matched standard was used to reduce the interference of the matrix effect on target compounds. The matrix effect distribution of 237 pesticides is shown in Figure 5. Among the 237 pesticides investigated in cottonseed hull samples, the proportion of pesticides with a negative matrix effect accounted for 81.4%, indicating that the substrate had a suppression effect on the tested pesticides as a whole. The matrix effect can be divided into three categories: no matrix effect (|ME| ≤ 20%); a weak matrix effect (20% < |ME| < 50%); and a strong matrix effect (|ME| ≥ 50%). In this work, only 8% of the pesticides in the cottonseed hull matrix showed a strong matrix effect; the weak matrix effect and no matrix effect accounted for 13.1% and 78.9%, respectively, indicating that this research method had a strong anti-matrix interference ability.

3.6. Method Validation and Method Performance

3.6.1. SDL, LOQ, and Standard Curve

The method validation was carried out under the optimal sample preparation procedure, and the results are shown in Table 1. The typical extraction ion chromatograms of GC-Q TOF/MS and LC-Q TOF/MS are shown in Figure 6 and Figure 7, respectively. The SDLs were in the range of 0.2–20 μg/kg, of which 224 pesticides (accounting for 94.5%) were in the range of 0.2–5 μg/kg. The LOQs were in the range of 0.2–20 μg/kg; 215 pesticides (accounting for 90.7%) had an LOQ range of 0.2–5 μg/kg. Shinde developed and verified 222 and 220 multi-pesticides residue analysis methods in sesame seeds, using LC-MS/MS and GC-MS/MS, respectively, and most pesticides offered an LOQ of 10 μg/kg for most compounds [16]. Kuzukiran et al. developed an SPE sample preparation method, combined with GC-MS, GC-MS/MS and LC-MS/MS, to analyze the residues of 322 organic pollutants in bats [31]. The LOQ of the method was in the range of 0.27–19.26 μg/kg, which was similar to that in our work; however, they paid more attention to environmental pollutants. This indicated that this method had high sensitivity in the detection of pesticide residues in cottonseed hull matrix. It is noteworthy that due to the large number of pesticides spiked, the retention time of some pesticides may overlap or be very close; for example, the RTs of Chloridazon and Mevinphos were 3.62 min. However, the excellent resolution of high-resolution mass spectrometry was sufficient to separate compounds that had a similar RT but a different mass (the quantitative ion mass of Chloridazon and that of Mevinphos were 222.04287 and 225.05230, respectively).
The calibration curve was plotted using the matrix matching calibration method and the target analytes at 10 spiked levels (0.2, 0.5, 1, 2, 5, 10, 20, 50, 100, and 200 μg/kg) were spiked to the blank cottonseed hull sample. The linear ranges of 237 pesticide analytes were 1–200 μg/L. All target pesticides showed good linearity in the concentration range, and R2 was greater than 0.99, indicating that this method could meet the requirements of quantitative analysis.

3.6.2. Recovery and Precision

The recovery and precision of the method was evaluated by spiked standard solutions at the levels of 1-, 2-, and 10-times LOQ for the cottonseed hull samples with six parallels at each spiked level. The results are shown in Figure 8. At the levels of 1-, 2-, and 10-times LOQ, the recoveries of the 237 pesticides in the range of 70–120% were 91.6%, 92.8%, and 94.5%, respectively, and the RSD of all the pesticides was less than 20%, indicating that the method had satisfactory recovery and precision.
Among the 237 pesticides, 60 pesticides were detected by two detection techniques, and most of them showed similar performance; however, individual pesticides were different in the two techniques. For example, the average recovery (81.2%) of clodinafop-propargyl detected by GC-QTOF/MS was lower than that (95.7%) detected by LC-QTOF/MS. In terms of precision, the RSD (10.8%) of the compound detected by GC-QTOF/MS was higher than that (4.8%) detected by LC-QTOF/MS. For Propiconazole, the average recovery and RSD of GC-QTOF/MS (89.0%, 5.5%) were better than those of LC-QTOF/MS (80.0%, 6.4%). Therefore, appropriate detection techniques should be selected in pesticide residue analysis, especially when compounds are suitable for these two detection techniques.

3.7. Analysis of Real Samples

The established method was applied to the analysis of 11 real cottonseed hull samples collected from several domestic pastures. The results showed that three pesticide residues were found in 11 cottonseed hull samples (butylate (three times), fenbuconazole (three times), and Diuron (two times)), with concentrations ranging from 10 to 28 μg/kg and above the LOQ. The determined three pesticides were slightly hazardous, according to WHO [32]. This method can be used for high-throughput trace detection of pesticide residues in cottonseed hull samples and improve the ability of risk-screening.

4. Conclusions

In this work, GC-QTOF/MS and LC-QTOF/MS were used to develop a high throughput method for qualitative screening and quantitative analysis of 237 pesticides in the cottonseed hull matrix. The modified QuEChERS extraction process seems to effectively eliminate the interference caused by the oily matrix, and the SDL, LOQ, recovery, and precision of the analysis method were verified under optimal conditions. In addition, compared with other methods for the oily matrix, this method has the advantages of being fast and simple, with high throughput and low solvent consumption. The results showed that the developed method could be applied to the screening of pesticide residues in the cottonseed hull matrix, effectively and generally.

Author Contributions

Conceptualization, H.C. and C.F.; methodology, H.C.; validation, K.T., Y.X. and X.W.; investigation, S.H. and Y.L.; resources, K.T.; data curation, Y.X.; writing—original draft preparation, K.T.; writing—review and editing, H.C., X.W. and C.F.; supervision, M.L. and W.W.; project administration, H.C. All authors have read and agreed to the published version of the manuscript.

Funding

This work was financially supported by the Science and Technology Project of the State Administration for Market Regulation (2021MK165).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Moretti, D.B.; Jimenez, C.R.; Trinca, H.M.; Machado-Neto, R.; Louvandini, H. Cottonseed feeding changes oxidative stress markers in ewes during the peripartum period and increases the quality of colostrum. Vet. J. 2019, 247, 32–37. [Google Scholar] [CrossRef] [PubMed]
  2. Eiras, C.E.; Guerrero, A.; Valero, M.V.; Pardo, J.A.; Ornaghi, M.G.; Rivaroli, D.C.; Sanudo, C.; Prado, I.N. Effects of cottonseed hull levels in the diet and ageing time on visual and sensory meat acceptability from young bulls finished in feedlot. Animal 2017, 11, 529–537. [Google Scholar] [CrossRef] [PubMed]
  3. Machado, P.A.S.; Valadares, S.D.; Valadares, R.F.D.; Paulino, M.F.; Pina, D.D.; Paixao, M.L. Nutritional and productive parameters of beef cattle on pasture fed different amounts of supplement Parâmetros nutricionais e produtivos em bovinos de corte a pasto alimentados com diferentes quantidades de suplemento. Rev. Bras. Zootec. 2011, 40, 1303–1312. [Google Scholar] [CrossRef] [Green Version]
  4. Buah-Kwofie, A.; Humphries, M.S. Validation of a modified QuEChERS method for the analysis of organochlorine pesticides in fatty biological tissues using two-dimensional gas chromatography. J. Chromatogr. B 2018, 1105, 85–92. [Google Scholar] [CrossRef]
  5. Shi, Z.H.; Zhang, S.L.; Huai, Q.R.; Xu, D.; Zhang, H.Y. Methylamine-modified graphene-based solid phase extraction combined with UPLC-MS/MS for the analysis of neonicotinoid insecticides in sunflower seeds. Talanta 2017, 162, 300–308. [Google Scholar] [CrossRef]
  6. Walorczyk, S.; Drozdzynski, D. Improvement and extension to new analytes of a multi-residue method for the determination of pesticides in cereals and dry animal feed using gas chromatography–tandem quadrupole mass spectrometry revisited. J. Chromatogr. A 2012, 1251, 219–231. [Google Scholar] [CrossRef]
  7. David, F.; Devos, C.; Dumont, E.; Yang, Z.; Sandra, P.; Huertas-Perez, J.F. Determination of pesticides in fatty matrices using gel permeation clean-up followed by GC-MS/MS and LC-MS/MS analysis: A comparison of low- and high-pressure gel permeation columns. Talanta 2017, 165, 201–210. [Google Scholar] [CrossRef]
  8. Xue, J.Y.; Li, H.C.; Liu, F.M.; Jiang, W.Q.; Chen, X.C. Determination of strobilurin fungicides in cotton seed by combination of acetonitrile extraction and dispersive liquidliquid microextraction coupled with gas chromatography. J. Sep. Sci. 2014, 37, 845–852. [Google Scholar] [CrossRef]
  9. Zhan, J.; Li, J.D.; Liu, D.H.; Liu, C.; Yang, G.G.; Zhou, Z.Q.; Wang, P. A simple method for the determination of organochlorine pollutants and the enantiomers in oil seeds based on matrix solid-phase dispersion. Food Chem. 2016, 194, 319–324. [Google Scholar] [CrossRef]
  10. Piao, H.L.; Jiang, Y.X.; Li, X.P.; Ma, P.Y.; Wang, X.H.; Song, D.Q.; Sun, Y. Matrix solid-phase dispersion coupled with hollow fiber liquid phase microextraction for determination of triazine herbicides in peanuts. J. Sep. Sci. 2019, 42, 2123–2130. [Google Scholar] [CrossRef]
  11. Jiang, Y.P.; Li, Y.J.; Jiang, Y.T.; Li, J.G.; Pan, C.P. Determination of multiresidues in rapeseed, rapeseed oil, and rapeseed meal by acetonitrile extraction, low-temperature cleanup, and detection by liquid chromatography with tandem mass spectrometry. J. Agric. Food Chem. 2012, 60, 5089–5098. [Google Scholar] [CrossRef] [PubMed]
  12. Theurillat, X.; Dubois, M.; Huertas-Pérez, J.F. A multi-residue pesticide determination in fatty food commodities by modified QuEChERS approach and gas chromatography-tandem mass spectrometry. Food Chem. 2021, 353, 129039. [Google Scholar] [CrossRef] [PubMed]
  13. Guan, W.B.; Li, Z.N.; Zhang, H.Y.; Hong, H.J.; Rebeyev, N.; Ye, Y.; Ma, Y.Q. Amine modified graphene as reversed-dispersive solid phase extraction materials combined with liquid chromatography–tandem mass spectrometry for pesticide multi-residue analysis in oil crops. J. Chromatogr. A 2013, 1286, 1–8. [Google Scholar] [CrossRef] [PubMed]
  14. Rutkowska, E.; Ozowicka, B.; Kaczyński, P. Compensation of matrix effects in seed matrices followed by gas chromatography-tandem mass spectrometry analysis of pesticide residues. J. Chromatogr. A 2020, 1614, 460738. [Google Scholar] [CrossRef]
  15. Koesukwiwat, U.; Lehotay, S.J.; Mastovska, K.; Dorweiler, K.J.; Leepipatpiboon, N. Extension of the QuEChERS Method for Pesticide Residues in Cereals to Flaxseeds, Peanuts, and Doughs. J. Agric. Food Chem. 2010, 58, 5950–5958. [Google Scholar] [CrossRef]
  16. Shinde, R.; Pardeshi, A.; Dhanshetty, M.; Anastassiades, M.; Banerjee, K. Development and validation of an analytical method for the multiresidue analysis of pesticides in sesame seeds using liquid- and gas chromatography with tandem mass spectrometry. J. Chromatogr. A 2021, 1652, 462346. [Google Scholar] [CrossRef]
  17. Gonzalez-Curbelo, M.A.; Socas-Rodriguez, B.; Herrera-Herrera, A.V.; Gonzalez-Salamo, J.; Hernandez-Borges, J.; Rodriguez-Delgado, M.A. Evolution and applications of the QuEChERS method. TrAC Trends Anal. Chem. 2015, 71, 169–185. [Google Scholar] [CrossRef]
  18. Farre, M.; Kantiani, L.; Petrovic, M.; Perez, S.; Barcelo, D. Achievements and future trends in the analysis of emerging organic contaminants in environmental samples by mass spectrometry and bioanalytical techniques. J. Chromatogr. A 2012, 1259, 86–99. [Google Scholar] [CrossRef]
  19. Dankyi, E.; Carboo, D.; Gordon, C.; Fomsgaard, I.S. Application of the QuEChERS Procedure and LC-MS/MS for the Assessment of Neonicotinoid Insecticide Residues in Cocoa Beans and Shells. J. Food Compos. Anal. 2016, 44, 149–157. [Google Scholar] [CrossRef]
  20. Chawla, S.; Patel, H.K.; Vaghela, K.M.; Pathan, F.K.; Gor, H.N.; Patel, A.R.; Shah, P.G. Development and validation of multiresidue analytical method in cotton and groundnut oil for 87 pesticides using low temperature and dispersive cleanup on gas chromatography and liquid chromatography-tandem mass spectrometry. Anal. Bioanal. Chem. 2016, 408, 983–997. [Google Scholar] [CrossRef]
  21. Naik, R.H.; Pallavi, M.S.; Bheemanna, M.; PavanKumar, K.; Reddy, V.C.S.; Nidoni, R.U.; Paramasivam, M.; Yadav, S. Simultaneous determination of 79 pesticides in pigeonpea grains using GC-MS/MS and LC-MS/MS. Food Chem. 2021, 347, 128986. [Google Scholar] [CrossRef]
  22. Elbashir, A.A.; Aboul-Enein, H.Y. Application of gas and liquid chromatography coupled to time-of-flight mass spectrometry in pesticides: Multiresidue analysis. Biomed. Chromatogr. 2018, 32, e4038. [Google Scholar] [CrossRef] [PubMed]
  23. Wang, J.; Chow, W.; Leung, D. Applications of LC/ESI-MS/MS and UHPLC QqTOF MS for the determination of 148 pesticides in fruits and vegetables. J. AOAC Int. 2011, 396, 1513–1538. [Google Scholar] [CrossRef] [PubMed]
  24. Lozano, A.; Rajski, L.; Ucles, S. Evaluation of zirconium dioxide-based sorbents to decrease the matrix effect in avocado and almond multiresidue pesticide analysis followed by gas chromatography tandem mass spectrometry. Talanta 2014, 118, 68–83. [Google Scholar] [CrossRef]
  25. Pang, G.F.; Chang, Q.Y.; Bai, R.B.; Fan, C.L.; Zhang, Z.J.; Yan, H.Y.; Wu, X.Q. Simultaneous Screening of 733 Pesticide Residues in Fruits and Vegetables by a GC/LC-Q-TOFMS Combination Technique. Engineering 2020, 6, 432–441. [Google Scholar] [CrossRef]
  26. Dos-Reis, R.R.; Sampaio, S.C.; De Melo, E.B. The effect of different log P algorithms on the modeling of the soil sorption coefficient of nonionic pesticides. Water Res. 2013, 47, 5751–5759. [Google Scholar] [CrossRef]
  27. Mol, H.G.J.; Plaza-BolanOs, P.; Zomer, P.; De Rijk, T.C.; Stolker, A.A.M.; Mulder, P.P.J. Toward a generic extraction method for simultaneous determination of pesticides, mycotoxins, plant toxins, and veterinary drugs in feed and food matrixes. Anal. Chem. 2008, 80, 9450–9459. [Google Scholar] [CrossRef]
  28. Tuzimski, T.; Rejczak, T. Application of HPLC-DAD after SPE/QuEChERS with ZrO2-based sorbent in d-SPE clean-up step for pesticide analysis in edible oils. Food Chem. 2016, 190, 71–79. [Google Scholar] [CrossRef]
  29. Lagunas-Allue, L.; Sanz-Asensio, J.; Martínez-Soria, M.T. Comparison of four extraction methods for the determination of fungicide residues in grapes through gas chromatography-mass spectrometry. J. Chromatogr. A 2012, 1270, 62–71. [Google Scholar] [CrossRef]
  30. Ucles, S.; Lozano, A.; Sosa, A.; Vazquez, P.P.; Valverde, A.; Fernandez-Alba, A.R. Matrix interference evaluation employing GC and LC coupled to triple quadrupole tandem mass spectrometry. Talanta 2017, 174, 72–81. [Google Scholar] [CrossRef]
  31. Kuzukiran, O.; Simsek, I.; Yorulmaz, T.; Yurdakok-Dikmen, B.; Ozkan, O.; Filazi, A. Multiresidues of environmental contaminants in bats from Turkey. Chemosphere 2021, 282, 131022. [Google Scholar] [CrossRef] [PubMed]
  32. World Health Organization. The WHO Recommended Classification of Pesticides by Hazard and Guidelines to Classification 2019; World Health Organization: Geneva, Switzerland, 2020.
Separations 09 00091 g001 550
Figure 1. Effects of hydration volumes on pesticide recovery.
Figure 1. Effects of hydration volumes on pesticide recovery.
Separations 09 00091 g001
Separations 09 00091 g002 550
Figure 2. Effect of extraction solvent volume on pesticide recovery.
Figure 2. Effect of extraction solvent volume on pesticide recovery.
Separations 09 00091 g002
Separations 09 00091 g003 550
Figure 3. Effect of salting-out agents on pesticide recovery.
Figure 3. Effect of salting-out agents on pesticide recovery.
Separations 09 00091 g003
Separations 09 00091 g004 550
Figure 4. Effect of clean-up sorbents on pesticide recovery. (A) MgSO4 + PSA + C18 + Z-sep; (B) MgSO4 + PSA + C18.
Figure 4. Effect of clean-up sorbents on pesticide recovery. (A) MgSO4 + PSA + C18 + Z-sep; (B) MgSO4 + PSA + C18.
Separations 09 00091 g004
Separations 09 00091 g005 550
Figure 5. Matrix effect distribution of 237 pesticides.
Figure 5. Matrix effect distribution of 237 pesticides.
Separations 09 00091 g005
Separations 09 00091 g006 550
Figure 6. Overlay extraction ion chromatograms of GC-Q TOF/MS of cottonseed hull sample at spiking level of 200 μg/kg.
Figure 6. Overlay extraction ion chromatograms of GC-Q TOF/MS of cottonseed hull sample at spiking level of 200 μg/kg.
Separations 09 00091 g006
Separations 09 00091 g007 550
Figure 7. Overlay extraction ion chromatograms of LC-Q TOF/MS of cottonseed hull sample at spiking level of 200 μg/kg.
Figure 7. Overlay extraction ion chromatograms of LC-Q TOF/MS of cottonseed hull sample at spiking level of 200 μg/kg.
Separations 09 00091 g007
Separations 09 00091 g008 550
Figure 8. The recovery and RSD of the target pesticides at three spiked levels.
Figure 8. The recovery and RSD of the target pesticides at three spiked levels.
Separations 09 00091 g008
Table
Table 1. Compound information, screening detection limits (SDLs), limit of quantification (LOQ), linear range, R2, recovery, and RSD of 237 pesticides (n = 6).
Table 1. Compound information, screening detection limits (SDLs), limit of quantification (LOQ), linear range, R2, recovery, and RSD of 237 pesticides (n = 6).
NoCompoundFormulaRT
(Min)		Quantitative IonQualitative IonR2Linearity
(ng/g)		SDL
(ng/g)		LOQ
(ng/g)		1-LOQ2-LOQ10-LOQ
REC
(%)		RSD
(%)		REC
(%)		RSD
(%)		REC
(%)		RSD
(%)		Detecting Instrument
11-(2-chloro-4-(4-chlorophenoxy)phenyl)-2-(1H-1,2,4-triazol-1-yl)ethanolC16H13Cl2N3O210.16350.0458070.039970.999510–200101081.32.971.57.876.911.5LC
21-(2-Chloro-pyridin-5-yl-methyl)-2-imino-imidazolidine hydrochlorideC9H11ClN42.28211.0745090.033830.99921–2001171.41.458.74.754.41.1LC
31-methyl-3-(tetrahydro-3-furylmethyl) ureaC7H14N2O21.87159.1128058.028740.99862–2002284.117.278.211.887.37.9LC
42,4-D butylateC12H14O3Cl219.45185.00000276.031460.99921–2001171.714.390.85.377.64.6GC
53-(Trifluoromethyl)-1-methyl-1H-pyrazole-4-carboxamideC6H6F3N3O2.63194.05360134.034880.991120–200520104.78.7105.412.879.63.2LC
65-hydroxy ImidaclopridC9H10ClN5O33.05272.05450225.053770.997610–20051072.07.878.28.570.27.8LC
7AcetamipridC10H11ClN43.93223.07450126.010510.99381–2001193.511.7110.311.089.67.2LC
8Acetamiprid-N-desmethylC9H9ClN43.57209.05890126.010510.99501–20011113.29.4105.68.896.36.4LC
9AcetochlorC14H20ClNO212.57270.12553133.088610.99921–20011115.313.899.210.586.43.1LC
10AlachlorC14H20ClNO212.45270.12553238.099320.99951–2001199.215.170.17.984.84.1LC
11Aldicarb-sulfoneC7H14N2O4S2.63223.0747062.989910.998710–200101073.77.586.58.384.22.7LC
12AldrinC12H8Cl619.52262.85641264.853520.99941–2001179.74.580.87.466.33.5GC
13AllidochlorC8H12ClNO4.94174.0680098.096430.99950.2–2000.20.293.119.970.715.383.88.1LC
14Alpha-HCHC6H6Cl616.14182.93437180.937320.99041–2001199.610.471.68.287.78.2GC
15AmetrynC9H17N5S6.70228.12774186.080800.99971–2001182.62.591.21.179.31.9LC
16AtrazineC8H14ClN56.38216.10105174.054090.99991–2001182.73.993.13.178.11.5LC
17Atrazine D5 (Ethylamino D5)C8H9D5ClN56.47221.1331069.030600.99651–2001197.73.5100.00.998.61.4LC
18Avermectin B1aC48H72O1418.66895.48140751.405210.99832–2001290.911.683.73.3110.06.5LC
19AzoxystrobinC22H17N3O511.07404.12410329.079500.99961–2001194.88.193.92.882.21.3LC
20BenalaxylC20H23NO314.04326.1750791.054230.99991–2001191.65.696.93.283.22.2LC
21BendiocarbC11H13NO45.74224.0917381.033491.00002–2001285.98.284.517.1120.08.7LC
22BenfluralinC13H16F3N3O415.37292.05396264.022671.000050–20022096.75.273.72.473.77.9GC
23BenfuracarbC20H30N2O5S17.27411.19482102.000810.99991–2001164.25.071.99.444.32.6LC
24BenzovindiflupyrC18H15Cl2F2N3O14.33398.06400159.036440.99991–2001195.95.098.12.283.01.8LC
25beta-EndosulfanC9H6Cl6O3S27.04236.84077242.901350.99501–20011103.914.091.75.770.39.0GC
26Beta-HCHC6H6Cl620.76182.93437180.937320.99641–2001172.317.270.515.674.27.7GC
27BifenazateC17H20N2O312.18301.15467198.091340.99991–2001189.518.783.412.288.06.3LC
28BifenthrinC23H22ClF3O228.81181.10118166.077700.993910–2001010106.616.245.72.682.82.0GC
29BioresmethrinC22H26O319.09339.19550143.085530.997820–200202084.917.671.66.677.76.0LC
30BitertanolC20H23N3O212.68338.1863070.039970.99285–2005577.110.679.210.275.814.2LC
31BoscalidC18H12Cl2N2O11.18343.03994271.086580.99972–20012100.99.991.110.588.07.9LC
32BromobutideC15H22BrNO13.75312.09575119.085530.99981–2001191.318.092.314.970.37.0LC
33Bromophos-methylC8H8BrCl2O3PS21.82330.87753328.879820.99411–2001175.415.681.210.878.414.3GC
34BromopropylateC17H16Br2O329.69340.89948342.897550.99891–2001187.110.590.66.976.67.2GC
35BupirimateC13H24N4O3S12.61317.1641944.049480.99981–2001195.08.295.32.682.31.0LC
36BuprofezinC16H23N3OS17.38306.1634657.069880.99751–20011101.43.6101.917.778.73.1LC
37ButachlorC17H26ClNO217.47312.1725057.069880.99871–20011115.319.995.019.980.46.5LC
38ButamifosC13H21N2O4PS16.45333.1035095.966750.99811–2001186.814.4110.69.574.76.5LC
39ButylateC11H23NOS16.60218.1573157.069880.999210–20051061.410.482.46.570.415.9LC
40CadusafosC10H23O2PS214.61271.0949896.950760.99981–2001173.39.486.19.177.31.8LC
41CarbarylC12H11NO26.21202.08626127.054230.992710–2001010102.317.1112.516.9107.117.2LC
42CarbendazimC9H9N3O22.67192.07675160.050540.99991–20011111.819.179.89.671.512.1LC
43CarbofuranC12H15NO35.80222.11247123.044060.99441–20011107.53.691.36.1112.52.4LC
44Carbofuran-3-HydroxyC12H15NO43.55238.10738107.049140.99970.2–2000.20.282.717.670.611.086.99.3LC
45CarbosulfanC20H32N2O3S19.82381.2206476.021550.99942–2002279.818.934.211.051.712.0LC
46Carfentrazone-ethylC15H14Cl2F3N3O314.18412.04350345.995610.99981–20011115.914.385.87.584.74.0LC
47ChlorantraniliproleC18H14BrCl2N5O28.23481.97807283.921601.00001–2001193.016.999.810.381.14.9LC
48ChlorfenapyrC15H11BrClF3N2O27.57363.94073361.942780.99131–2001185.16.6109.817.5112.413.6GC
49ChlorfenvinphosC12H14Cl3O4P13.67358.9768198.984340.99991–2001189.810.9103.89.886.54.2LC
50ChloridazonC10H8ClN3O3.62222.0428777.038570.99771–2001177.76.284.44.179.23.4LC
51ChlormequatC5H12ClN0.70122.0731058.065120.99831–2001190.814.793.64.7113.38.4LC
52ChloronebC8H8Cl2O211.81190.96611192.963240.99452–20022127.819.354.813.869.58.8GC
53ChlorotoluronC10H13ClN2O6.10213.0789272.044880.99981–2001196.16.1102.15.082.22.2LC
54ChlorprophamC10H12ClNO215.92127.01833213.055110.99895–20055138.219.788.115.884.08.3GC
55ChlorpyrifosC9H11Cl3NO3PS17.72349.9335696.950760.99985–20015100.919.384.98.985.15.3LC
56Chlorpyrifos-methylC7H7Cl3NO3PS19.32285.92557287.923160.99491–2001193.67.979.410.678.713.1GC
57Cis-Chlordane (alpha)C10H6Cl823.58372.82544374.822510.99961–2001185.77.483.56.970.56.5GC
58Clodinafop-propargylC17H13ClFNO415.05350.0589991.054230.99991–20011109.57.494.44.183.13.0LC
59ClofentezineC14H8Cl2N415.32303.01988102.033830.99975–2005581.217.472.212.4104.27.5LC
60ClomazoneC12H14ClNO27.91240.07858125.015250.99991–20011112.318.499.812.778.53.6LC
61ClothianidinC6H8ClN5O2S3.50250.01600131.966920.99952–20012101.919.4103.915.189.46.9LC
62CyanazineC9H13ClN65.16241.09630214.085400.99981–2001178.911.989.08.285.913.9LC
63CyanofenphosC15H14NO2PS29.06156.98715169.041290.99961–2001177.314.9100.813.981.26.1GC
64CycloateC11H21NOS15.35216.1416655.054230.99982–20022117.415.385.016.279.65.7LC
65CycloxydimC17H27NO3S16.22326.17844107.049140.99961–2001162.611.6100.45.774.14.2LC
66CyprodinilC14H15N322.15224.11823225.126050.99991–2001192.315.989.14.175.35.9GC
67CyromazineC6H10N60.75167.1040085.050870.99275–2001558.26.056.210.151.55.8LC
68Delta-HCHC6H6Cl621.60180.93732182.934370.99432–20022158.119.5162.419.8181.819.4GC
69DesmetrynC8H15N5S5.21214.11209172.065140.99941–2001184.73.793.50.778.61.9LC
70DiallateC10H17Cl2NOS16.66270.0481086.060040.999210–20051070.619.0107.59.785.919.9LC
71DiazinonC12H21N2O3PS14.97305.1083396.950760.99981–2001189.53.687.73.478.51.5LC
72DichlofenthionC10H13Cl2O3PS18.86279.00061222.938000.99381–2001176.617.782.010.573.07.0GC
73DichlorvosC4H7Cl2O4P7.85184.97650109.004910.995410–200110116.212.6108.917.678.116.0GC
74DicloranC6H4Cl2N2O218.20205.96443207.961560.99462–2002289.315.989.714.586.08.9GC
75DifenoconazoleC19H17Cl2N3O314.63406.07200251.002500.99981–2001177.34.894.02.879.62.2LC
76DiflubenzuronC14H9ClF2N2O212.11311.03934141.014650.993810–200101064.85.683.710.392.210.0LC
77DimethenamidC12H18ClNO2S9.58276.08195244.055740.99971–2001190.63.684.85.582.84.6LC
78DimethoateC5H12NO3PS23.78230.00690198.964690.99412–2001270.410.089.89.084.76.0LC
79Dimethylvinphos (Z)C10H10Cl3O4P10.47330.94550127.015470.99991–2001192.116.980.710.3108.77.9LC
80DiniconazoleC15H17Cl2N3O12.97326.0821070.039971.00002–2001289.14.084.27.185.55.5LC
81DinotefuranC7H14N4O32.31203.1138758.052550.999420–200202080.05.686.84.577.13.3LC
82DioxabenzofosC8H9O3PS10.47217.0083077.038571.00002–2001297.35.088.05.787.02.9LC
83DipropetrynC11H21N5S11.46256.15904102.012050.99991–2001174.35.094.64.276.33.1LC
84DiuronC9H10Cl2N2O6.63233.0242972.044880.99891–20011105.717.6124.811.170.65.3LC
85EdifenphosC14H15O2PS213.46311.03238109.010650.99981–2001192.64.693.33.681.50.8LC
86Emamectin B1aC49H75NO1316.88886.53112158.117550.99961–2001183.112.382.36.675.210.3LC
87Endosulfan-sulfateC9H6Cl6O4S29.05271.80963273.806670.99991–2001161.77.161.16.051.42.7GC
88EthalfluralinC13H14F3N3O414.96276.05905316.090360.99811–2001193.09.6106.116.473.99.5GC
89EthionC9H22O4P2S417.95384.99489199.001081.00001–20011119.98.389.116.078.13.3LC
90EthoprophosC8H19O2PS210.86243.0636896.950760.99981–2001190.311.887.36.678.71.5LC
91EtrimfosC10H17N2O4PS14.56293.07194124.982060.99991–2001176.94.592.34.681.63.0LC
92FenamidoneC17H17N3OS30.72268.09030238.110060.99941–2001177.711.789.617.087.16.1GC
93FenamiphosC13H22NO3PS10.46304.11308201.984800.99981–2001183.62.696.22.984.20.9LC
94Fenamiphos-sulfoneC13H22NO5PS5.59336.10291266.024660.99991–2001194.618.191.14.483.42.0LC
95Fenamiphos-sulfoxideC13H22NO4PS4.61320.10799108.057270.99991–2001190.35.0100.26.583.91.1LC
96FenarimolC17H12Cl2N2O10.59331.0399481.044720.99982–20012102.811.090.79.776.66.8LC
97FenbuconazoleC19H17ClN412.38337.1215070.039970.99991–20011116.411.774.019.375.17.0LC
98FenchlorphosC8H8Cl3O3PS19.80284.93033286.927490.99681–2001186.27.0102.36.675.39.4GC
99FenobucarbC12H17NO28.80208.1332177.038570.99825–2005587.912.4104.78.084.02.7LC
100FenpropimorphC20H33NO18.52128.10699129.110120.99485–2005566.619.470.716.376.93.2GC
101FensulfothionC11H17O4PS27.42309.03786140.029040.99961–2001187.92.994.51.584.01.2LC
102Fenthion-sulfoxideC10H15O4PS26.02295.02221109.004910.99981–2001187.33.793.53.784.11.1LC
103FipronilC12H4Cl2F6N4OS28.19366.94296368.940030.99701–2001180.119.175.711.472.07.6GC
104Fipronil DesulfinylC12H4Cl2F6N425.54332.99609387.971160.99512–20022107.412.367.218.7117.819.5GC
105Fipronil-sulfideC12H4Cl2F6N4S27.81350.94803352.945100.99991–2001175.52.975.53.071.22.0GC
106FluacrypyrimC20H21F3N2O516.67427.14753145.064790.99921–20011109.315.5111.56.577.66.8LC
107Fluazifop-butylC19H20F3NO417.62384.1417291.054230.99991–2001176.75.691.63.380.53.0LC
108FlubendiamideC23H22F7IN2O4S14.52705.01250530.979860.99991–2001188.53.193.23.483.21.7LC
109Flumiclorac-pentylC21H23ClFNO517.47441.15930308.048430.99732–2001226.419.575.019.579.018.1LC
110FluopicolideC14H8Cl3F3N2O11.85382.97271172.955550.99991–2001190.79.595.16.783.82.4LC
111FluquinconazoleC16H8Cl2FN5O11.40376.01630306.983580.99965–2005582.46.488.96.394.94.3LC
112FluridoneC19H14F3NO9.19330.11003309.095980.99891–2001192.38.594.21.484.32.0LC
113FlusilazoleC16H15F2N3Si12.36316.10761165.069670.99971–2001182.16.597.49.579.82.3LC
114FlutriafolC16H13F2N3O6.40302.1099470.039970.99961–2001189.39.196.25.376.03.2LC
115FluxapyroxadC18H12F5N3O11.39382.09730342.084871.00001–2001193.07.894.44.584.23.4LC
116FonofosC10H15OPS215.23247.0374780.955850.99765–2001572.01.5100.316.0105.84.3LC
117FosthiazateC9H18NO3PS26.37284.05385104.016460.99981–2001196.011.194.64.387.12.2LC
118FurathiocarbC18H26N2O5S17.26383.16352195.047420.99991–2001174.36.782.64.464.91.2LC
119HaloxyfopC15H11ClF3NO423.54316.03467375.047970.999720–20012096.04.877.06.373.36.9GC
120Haloxyfop-2-ethoxyethylC19H19ClF3NO517.06434.0976691.054230.99831–2001192.32.4110.33.583.73.2LC
121Haloxyfop-methylC16H13ClF3NO416.23376.05460272.008450.99851–2001191.711.590.25.983.02.6LC
122HeptachlorC10H5Cl718.48271.80963273.806670.99791–20011106.418.976.36.174.910.0GC
123HexachlorobenzeneC6Cl614.03283.80963285.806700.99181–2001161.62.160.14.154.36.4GC
124HexaconazoleC14H17Cl2N3O12.19314.0825070.039970.99962–2001298.411.485.79.597.210.8LC
125HexythiazoxC17H21ClN2O2S17.70353.10850168.056960.99922–2001270.610.4120.09.382.04.1LC
126ImazalilC14H14Cl2N2O25.76172.95555215.002500.99981–2001192.16.873.27.684.13.9GC
127ImazapyrC13H15N3O33.07262.1186269.069880.99985–2005524.82.023.111.025.36.7LC
128ImidaclopridC9H10ClN5O23.68256.05958209.058850.99671–20011117.50.2181.66.687.112.1LC
129Imidacloprid-OlefinC9H8ClN5O23.07254.04390171.066530.999710–20051094.813.791.17.378.19.6LC
130IprobenfosC13H21O3PS12.36289.1021891.054230.99942–20012104.114.5100.115.0101.65.7LC
131IprovalicarbC18H28N2O310.44321.21727119.085530.99991–20011111.813.5106.49.289.12.3LC
132IsazofosC9H17ClN3O3PS13.62314.04895119.995740.99981–2001186.04.691.23.483.42.0LC
133IsofenphosC15H24NO4PS16.48346.12364121.028720.99965–2002576.415.680.417.8108.116.7LC
134IsoproturonC12H18N2O6.66207.1491972.044390.99900.5–2000.50.596.27.989.21.784.02.2LC
135IsopyrazamC20H23F2N3O15.58360.18950320.175750.99981–2001186.95.896.84.179.91.2LC
136Kresoxim-methylC18H19NO414.26314.13868116.049480.99985–2002572.015.179.312.389.84.7LC
137LactofenC19H15ClF3NO717.70479.08210343.993190.997220–200202090.55.1111.617.177.712.5LC
138LindaneC6H6Cl617.74180.93732182.934370.99891–2001162.916.7116.518.3110.87.9GC
139LinuronC9H10Cl2N2O29.10249.01921132.960630.99905–2002573.110.384.48.994.23.2LC
140MalaoxonC10H19O7PS5.72315.0661999.007670.99981–2001174.417.493.912.389.410.2LC
141MalathionC10H19O6PS212.53331.0433499.007670.99831–2001182.911.083.710.377.83.4LC
142MepanipyrimC14H13N324.48222.10257223.110400.99985–2001584.59.977.68.779.44.8GC
143MetaflumizoneC24H16F6N4O217.39507.12502178.046280.997310–20021080.34.686.716.982.88.0LC
144MetalaxylC15H21NO46.70280.1543345.033490.99931–2001195.08.698.42.281.81.1LC
145MetconazoleC17H22ClN3O12.66320.1524270.039970.99982–2001280.58.786.55.886.16.8LC
146MethiocarbC11H15NO2S8.73226.08960121.064790.993920–20052084.115.486.116.285.35.1LC
147Methiocarb-sulfoxideC11H15NO3S3.42242.08454122.072620.99801–20011101.114.887.66.884.04.0LC
148MetolachlorC15H22ClNO212.32284.14118252.114970.99991–2001197.19.1105.63.284.01.4LC
149MetrafenoneC19H21BrO516.24409.06451209.080840.99981–2001191.04.692.73.679.11.9LC
150MetribuzinC8H14N4OS5.26215.0961149.010650.99995–2002587.513.980.63.093.61.2LC
151MevinphosC7H13O6P3.62225.05230127.015470.99922–2001270.311.8118.810.590.07.6LC
152MirexC10Cl1229.05271.80963273.806670.99991–2001164.62.162.66.057.12.9GC
153MonocrotophosC7H14NO5P2.77224.0682458.028740.99951–2001199.317.3110.112.781.73.4LC
154MyclobutanilC15H17ClN410.56289.1214570.039970.99965–20015110.715.393.86.383.15.2LC
155NapropamideC17H21NO211.63272.16451171.080440.99991–2001184.62.794.72.183.91.6LC
156NorflurazonC12H9ClF3N3O7.06304.04590140.030620.99981–2001187.72.895.02.782.41.0LC
157OmethoateC5H12NO4PS2.08214.02974182.987550.99881–2001185.58.592.25.680.22.7LC
158OxadiazonC15H18Cl2N2O325.39174.95862258.032140.99992–2002298.215.381.317.484.22.1GC
159OxadixylC14H18N2O44.99279.13393132.080780.99991–2001184.819.7117.311.093.93.3LC
160PaclobutrazolC15H20ClN3O25.79236.05852125.015250.99962–2001286.42.782.09.381.82.6GC
161PentachloroanilineC6H2Cl5N18.83264.85950266.856570.99751–2001172.16.970.95.671.51.6GC
162PentachloroanisoleC7H3Cl5O14.82264.83569279.859190.99451–2001172.69.271.02.671.21.5GC
163PenthiopyradC16H20F3N3OS14.47360.13620256.035060.99981–2001197.18.391.14.183.41.1LC
164PhenthoateC12H17O4PS214.95321.0378679.054230.99992–2002284.711.074.618.2100.67.8LC
165Phorate-SulfoneC7H17O4PS38.56293.0097096.950760.99335–2005576.40.570.511.270.311.8LC
166Phorate-SulfoxideC7H17O3PS36.30277.0150296.950760.99981–2001199.77.297.65.585.61.2LC
167PhosaloneC12H15ClNO4PS215.96367.99414110.999600.992920–2002020118.312.9116.011.788.82.4LC
168PhosphamidonC10H19ClNO5P4.68300.07621127.015470.99971–2001188.27.191.83.184.71.2LC
169PhoximC12H15N2O3PS15.98299.0613877.038890.991710–20051071.110.974.217.6110.914.9LC
170PicoxystrobinC18H16F3NO414.65368.11042145.064790.99931–20011101.016.694.68.884.05.2LC
171Piperonyl butoxideC19H30O517.06356.24230119.085530.99941–2001193.510.482.47.778.21.6LC
172PirimicarbC11H18N4O24.41239.1502572.044390.99751–2001178.314.495.34.378.03.7LC
173Pirimiphos-methylC11H20N3O3PS15.87306.1035867.029080.99991–2001186.04.291.71.180.50.8LC
174PretilachlorC17H26ClNO216.17312.17248252.114970.99991–20011116.74.888.79.482.83.9LC
175ProchlorazC15H16Cl3N3O213.20376.0380970.028740.99981–2001182.46.797.27.679.02.6LC
176ProfenofosC11H15BrClO3PS16.14372.9424296.950940.99842–2002294.515.692.56.598.63.3LC
177PrometrynC10H19N5S8.73242.1433968.024320.99971–2001182.12.789.71.979.72.0LC
178PropamocarbC9H20N2O22.18189.1597574.023660.99831–2001169.317.290.313.779.98.3LC
179PropanilC9H9Cl2NO7.97218.01340127.017840.99965–2002571.16.870.47.088.11.7LC
180PropaphosC13H21O4PS13.10305.0970944.979350.99981–2001183.35.483.72.881.41.5LC
181PropargiteC19H26O4S18.28368.1886057.069880.99105–2005584.815.896.312.5116.219.9LC
182PropazineC9H16ClN58.11230.11670146.022800.99921–2001182.01.899.64.180.82.7LC
183PropiconazoleC15H17Cl2N3O213.23342.0770669.069880.99991–2001185.55.287.05.877.63.4LC
184PropyzamideC12H11Cl2NO11.01256.02905189.982100.99895–2001582.84.282.310.992.24.1LC
185ProthioconazoleC14H15Cl2N3OS12.48344.03860102.012050.99425–2005570.20.8117.918.970.410.6LC
186Prothioconazole-desthioC14H15Cl2N3O10.35312.0664070.039970.99991–2001187.06.689.65.080.21.7LC
187PymetrozineC10H11N5O2.04218.10364105.044720.99431–20011113.09.881.78.771.311.5LC
188PyraclostrobinC19H18ClN3O415.40388.10586194.081180.99990.2–2000.20.2105.818.2104.813.284.52.4LC
189PyridabenC19H25ClN2OS18.83365.14489147.116820.99881–20011114.419.280.59.170.22.5LC
190PyridaphenthionC14H17N2O4PS11.59341.0719492.049790.99981–2001172.59.592.76.885.61.5LC
191PyrimethanilC12H13N37.56200.1182277.038570.99955–2001584.96.676.32.290.83.4LC
192PyriproxyfenC20H19NO317.50322.1437796.044390.99981–2001187.715.886.43.476.53.5LC
193QuinalphosC12H15N2O3PS14.00299.0613896.950760.99991–2001190.310.2100.02.979.92.4LC
194QuinoxyfenC15H8Cl2FNO16.79308.00397196.978870.99981–2001172.81.879.13.870.24.3LC
195QuintozeneC6Cl5NO216.21236.84077294.833710.99721–2001182.318.073.610.082.516.0GC
196Quizalofop-ethylC19H17ClN2O416.62373.0949691.054230.99971–20011105.515.8103.89.976.00.9LC
197SaflufenacilC17H17ClF4N4O5S10.90501.06170348.999760.99941–20011112.617.783.817.382.76.0LC
198SimazineC7H12ClN55.00202.0854068.024320.99971–2001193.11.796.55.284.22.3LC
199Spinosyn DC42H67NO1015.36746.48377142.122630.99981–2001188.08.698.99.180.15.2LC
200SpirodiclofenC21H24Cl2O418.97411.1124471.085530.99920.5–2000.50.573.919.9119.812.3103.113.8LC
201SpirotetramatC21H27NO510.10374.19620302.175080.99965–2002581.012.270.57.677.35.3LC
202Spirotetramat-enolC18H23NO35.29302.17580216.101900.99961–2001184.67.083.22.875.53.0LC
203Spirotetramat-enol-glucosideC24H33NO82.86464.22790216.101900.99261–20011120.88.5134.32.0185.911.2LC
204SpiroxamineC18H35NO28.76298.27406100.112080.99901–2001191.312.480.93.178.23.5LC
205SulfentrazoneC11H10Cl2F2N4O3S6.34386.98915306.994350.99885–2005576.75.383.64.994.04.3LC
206SulfotepC8H20O5P2S215.67322.02219237.928281.00001–2001195.416.191.29.379.19.5GC
207SulfoxaflorC10H10F3N3OS4.48278.05690154.046280.99832–2002291.08.972.75.3100.75.8LC
208SulprofosC12H19O2PS317.99323.03575218.969790.99972–2001272.414.089.110.986.65.5LC
209TebuconazoleC16H22ClN3O11.75308.1524070.039970.99992–2001295.85.980.86.787.36.0LC
210TebufenozideC22H28N2O213.92353.22235133.064790.99842–20012113.19.458.518.185.017.5LC
211TerbufosC9H21O2PS317.05289.0514157.069880.998110–20021088.516.190.97.585.015.4LC
212Terbufos-SulfoneC9H21O4PS311.57321.04120275.053530.99822–20022114.016.792.99.698.13.4LC
213Terbufos-SulfoxideC9H21O3PS38.23305.04650130.938480.99991–20011114.913.2106.312.679.75.2LC
214TerbumetonC10H19N5O17.40210.13493169.095810.99861–20011111.818.679.26.985.42.4GC
215TerbuthylazineC9H16ClN58.82230.11670174.054090.99981–2001189.318.998.28.479.83.4LC
216TerbutrynC10H19N5S9.10242.14339186.080800.99921–2001182.33.690.02.376.24.4LC
217TetramethrinC19H25NO417.04332.18560164.070600.99885–2002597.813.092.44.498.65.5LC
218ThiabendazoleC10H7N3S2.90202.04334131.060380.99991–2001174.33.982.45.173.11.8LC
219ThiaclopridC10H9ClN4S4.51253.03092126.008670.99931–2001187.35.198.51.782.02.0LC
220ThiamethoxamC8H10ClN5O3S3.13292.02656131.966430.99501–2001179.411.681.35.674.76.9LC
221ThiobencarbC12H16ClNOS15.15258.07139125.015250.99852–2002284.618.689.513.290.61.3LC
222Thiophanate-methylC12H14N4O4S25.43343.05292151.032440.99921–20011102.45.682.92.073.93.0LC
223TolfenpyradC21H22ClN3O216.91384.14770197.096080.99981–2001182.013.279.03.676.38.1LC
224Trans-ChlordaneC10H6Cl823.38372.82544374.822510.99971–2001178.66.271.26.470.64.5GC
225TriadimefonC14H16ClN3O211.17294.1003857.069880.99961–2001190.910.085.98.283.13.9LC
226TriadimenolC14H18ClN3O28.54296.1158070.039970.99985–2005590.614.074.511.084.34.3LC
227TriazophosC12H16N3O3PS12.72314.07228119.060370.99801–2001184.12.261.22.383.31.9LC
228TrichlorfonC4H8Cl3O4P3.33256.9298578.994520.999210–20051077.313.491.68.584.27.1LC
229TrifloxystrobinC20H19F3N2O416.67409.13697145.025960.99921–2001188.23.889.03.781.41.3LC
230TriflumizoleC15H15ClF3N3O14.98346.0929069.044721.00001–2001188.56.590.94.680.52.0LC
231TrifluralinC13H16F3N3O415.26264.02267306.069610.99812–2002279.17.071.311.180.36.4GC
232Trinexapac-ethylC13H16O57.54253.1070569.033490.99965–2005575.49.560.112.473.43.4LC
233UniconazoleC15H18ClN3O10.58292.1213070.039970.99991–2001160.916.484.68.379.71.7LC
234VinclozolinC12H9Cl2NO320.63212.00284186.958620.99622–2002267.712.780.44.483.74.9GC
235WarfarinC19H16O48.91309.11214163.038970.99970.5–2000.50.598.715.099.56.091.06.7LC
236ZoxamideC14H16Cl3NO214.92336.03194186.971190.99971–2001192.87.196.04.283.02.0LC
237EndrinC12H8Cl6O25.22316.90341262.856410.99625–2005563.719.876.55.578.24.5GC
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Tong, K.; Xie, Y.; Huang, S.; Liu, Y.; Wu, X.; Fan, C.; Chen, H.; Lu, M.; Wang, W. QuEChERS Method Combined with Gas- and Liquid-Chromatography High Resolution Mass Spectrometry to Screen and Confirm 237 Pesticides and Metabolites in Cottonseed Hull. Separations 2022, 9, 91. https://doi.org/10.3390/separations9040091

AMA Style

Tong K, Xie Y, Huang S, Liu Y, Wu X, Fan C, Chen H, Lu M, Wang W. QuEChERS Method Combined with Gas- and Liquid-Chromatography High Resolution Mass Spectrometry to Screen and Confirm 237 Pesticides and Metabolites in Cottonseed Hull. Separations. 2022; 9(4):91. https://doi.org/10.3390/separations9040091

Chicago/Turabian Style

Tong, Kaixuan, Yujie Xie, Siqi Huang, Yongcheng Liu, Xingqiang Wu, Chunlin Fan, Hui Chen, Meiling Lu, and Wenwen Wang. 2022. "QuEChERS Method Combined with Gas- and Liquid-Chromatography High Resolution Mass Spectrometry to Screen and Confirm 237 Pesticides and Metabolites in Cottonseed Hull" Separations 9, no. 4: 91. https://doi.org/10.3390/separations9040091

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop