高效液相色谱法测定香蕉中的多菌灵、噻菌灵、甲基硫菌灵

采用高效液相色谱法测定香蕉中的多菌灵、噻菌灵、甲基硫菌灵。样品经乙腈提取、硅胶柱净化后用HPLC法测定,外标法定量。对样品前处理和色谱分析条件进行了研究和优化。3种杀菌剂在确定的浓度范围内线性良好,相关系数r≥0．999。添加3个浓度水平标准品的回收率分别为：多菌灵80．5％～91．2％,噻菌灵81．2％～86．9％．68．9％～72．6％。该法对多菌灵、噻菌灵、甲基硫菌灵3种杀菌剂的检出限较低,分别为0．008,0．009,0．015mg／kg。该方法可满足香蕉中多菌灵、噻菌灵、甲基硫菌灵的残留限量检测要求。     

固相萃取-HPLC法同时测定浓缩柑橘汁中噻菌灵、多菌灵的残留量

建立了一种可同时测定浓缩柑橘汁中噻菌灵和多菌灵残留量的反相HPLC分析法。浓缩柑橘汁样品用水适当稀释后,经过调节pH值、离心、过滤,用混合相固相萃取小柱(m ixed-mode SPE)进行提取、净化,用配有二级管阵列检测器(DAD)的液相色谱仪检测,外标法定量。使用噻菌灵和多菌灵对照品进行添加回收试验,噻菌灵、多菌灵的回收率分别为80.8%~87.1%、82.9%~87.7%,二者的测定下限均为0.020 mg/kg,测定结果的相对标准偏差均不大于7.38%(n=10)。     

高效液相色谱法测定柑橘和土壤中残留的多菌灵

建立了柑橘和土壤中多菌灵残留量的高效液相色谱(HPLC)分析方法。柑橘果肉、果皮、全果和土壤样品中残留的多菌灵用碱性乙腈溶液提取,经NH2固相萃取(SPE)柱净化,HPLC分离,紫外检测器检测,外标法定量。在0.02～5.0 mg/L范围内,多菌灵的峰面积与其质量浓度呈良好的线性关系,相关系数为0.9997。柑橘果肉、果皮、全果和土壤中添加0.05～0.5 mg/kg多菌灵标准品的平均回收率为89.2%～102%,相对标准偏差为1.8%～9.1%;柑橘果肉和土壤中多菌灵的最低检测浓度为0.05 mg/kg,柑橘果皮和全果中多菌灵的最低检测浓度为0.1 mg/kg。该方法的灵敏度、准确度和精密度均符合农药残留测定的技术要求。     

固相萃取-高效液相色谱法测定浓缩苹果汁中的多菌灵残留量

报道了固相萃取-高效液相色谱法测定浓缩苹果汁中多菌灵残留量的方法.样品经适量水稀释后,C18固相萃取柱提取净化,用V(甲醇)∶V(二氯甲烷)=1∶1淋洗,HPLC法测定.在添加水平为0.10,0.50,2.0 mg/kg时,多菌灵的回收率在92.6%～108.3%之间;RSD＜3% (n=6),检出限为0.02 mg/kg,该方法的测定结果满足农药残留量的检测要求.     

固相萃取-HPLC法测定浓缩梨汁中噻菌灵、多菌灵的残留量

研究了一种可同时测定浓缩梨汁中噻菌灵和多菌灵残留量的固相萃取-高效液相色谱分析方法.浓缩梨汁样品与水按一定比例稀释后,经过调pH、离心、过滤,用混合相固相萃取小柱(Mixed-mode SPE)进行提取、净化,用配有二级管阵列检测器(DAD)的液相色谱仪检测,外标法定量.使用噻菌灵和多菌灵对照品进行添加回收率测定,结果显示本方法对噻菌灵的最低检出限为0.020 mg/kg,回收率为80.5%~84.3%;对多菌灵的最低检出限为0.020 mg/kg,回收率为83.2%~92.5%;测定的相对标准偏差均不大于5%.本方法简单、快速、准确,能满足常规噻菌灵和多菌灵残留量检测的需要.     

QuEChERS-高效液相色谱-串联质谱法测定黄瓜和土壤中甲基硫菌灵和多菌灵

建立了黄瓜和土壤样品中甲基硫菌灵和多菌灵的QuEChERS-高效液相色谱-电喷雾串联质谱(HPLC-ESI-MS/MS)检测方法。样品用乙腈溶液提取,经QuEChERS方法净化,以Agilent ZORBAX SB-C18色谱柱(30 mm×2.1 mm, 5 μm)进行HPLC分离,以电喷雾电离串联质谱正离子多反应监测(MRM)模式进行测定。对甲基硫菌灵和多菌灵在黄瓜和土壤中4个添加水平(0.01、0.05、0.1和1.0 mg/kg)下的回收率进行了测定,甲基硫菌灵在黄瓜中的添加回收率为87.3%～96.0%(相对标准偏差(RSD)为8.0%～9.3%),在土壤中的添加回收率为88.8%～93.4%(RSD为5.3%～9.9%);多菌灵在黄瓜中的添加回收率为87.1%～92.3%(RSD为5.2%～7.5%),在土壤中的添加回收率为85.8%～90.9%(RSD为5.3%～13.2%)。该方法样品前处理简单、快速,分析时间短,灵敏度、准确度和精密度均符合农药残留检测要求,适用于黄瓜和土壤中甲基硫菌灵和多菌灵残留的检测。     

PSA分散固相萃取和离子对液相色谱测定蔬菜中苯并咪唑类残留的研究

建立了蔬菜中多菌灵、甲基硫菌灵、噻菌灵3种苯并眯唑类杀菌剂及其有毒代谢物2-氨基苯并咪唑残留的离子对液相色谱测定方法.样品用乙腈提取和无水硫酸镁盐析后,上层乙腈经PSA和无水硫酸镁混合振荡离心除去杂质和乙腈层中残余水分,再加入离子对试剂,用反相离子对高效液相色谱分离测定.多菌灵、甲基硫菌灵、噻菌灵的添标回收率在80%～110%之间,2.氨基苯并咪唑的回收率在70%～85%之间.多菌灵、甲基硫菌灵、噻菌灵和2-氨基苯并咪唑在实际样品中的检出限分别为0.07、0.09、0.05、0.10 mg/kg.     

固相萃取-高效液相色谱法同时测定噻菌灵和多菌灵在浓缩菠萝汁中的残留量

建立了一种可同时测定浓缩菠萝汁中噻菌灵和多菌灵残留量的反相高效液相色谱分析法。浓缩菠萝汁样品与水按一定比例稀释后,经过调节溶液的pH值、离心、过滤,用混合相固相萃取小柱(Mixed-mode SPE)进行提取、净化,并用配有二极管阵列检测器(DAD)的液相色谱仪检测,外标法定量。使用噻菌灵和多菌灵对照品进行添加回收率测定,结果显示,本方法对噻菌灵的检出限为0.020 mg/kg,回收率为75.7%~93.3%;对多菌灵的检出限为0.020 mg/kg,回收率为80.8%~99.2%;测定的相对标准偏差均不大于5.7%。本方法简单、快速、准确,能满足常规噻菌灵和多菌灵残留量检测的需要。     

高效液相色谱法对环境样品中甲基托布津与甲霜灵残留的测定

建立了自动固相萃取/高效液相色谱法测定地表水和土壤中甲基托布津和甲霜灵残留的方法。地表水采用C18固相萃取小柱进行富集、净化及浓缩;土壤采用丙酮-二氯甲烷(体积比3∶7)溶液振荡萃取,弗罗里硅土小柱净化和浓缩;以乙腈和水为流动相,于230 nm波长处对样品进行高效液相色谱检测。甲基托布津和甲霜灵在水中的检出限分别为0.36、3.49μg/L,在土壤中的检出限分别为0.03、0.18 mg/kg;在优化实验条件下,甲基托布津和甲霜灵在水样和土壤样品中的添加回收率为77%~105%,精密度为1.2%~8.5%。方法可用于环境样品中甲霜灵和甲基托布津残留量的测定。     

液相色谱-串联质谱法测定果蔬中喹啉铜的残留量

通过优化液-液萃取(LLE)作为前处理手段,依托液相色谱-串联质谱仪器,建立了适用于蔬菜、水果中喹啉铜残留量的检测方法。样品以1%乙酸在超声条件下提取,提取液经PSA和C18净化后,以液相色谱-串联质谱法测定。本方法在0.01～2.0 mg/L范围内,不同基质中线性关系良好(R~20.99),进行了定量限(LOQ)、0.5倍最大允许残留限量(MRL)、1倍MRL和2倍MRL共4个水平的添加回收实验,回收率均介于82.7%～99.7%之间,相对标准偏差(RSD)在1.73%～11.8%之间,LOQ为0.1 mg/kg。本方法稳定、简便、灵敏,能够满足农药残留检测需求。     

Liquid chromatographic-mass spectrometric determination of post-harvest fungicides in citrus fruits

Liquid chromatography (LC)-atmospheric pressure ionisation (API)-mass spectrometry (MS) has been used to determine residues of five fungicides in oranges with a minimum sample cleanup. Atmospheric pressure chemical ionisation (APCI) and electrospray (ES) were compared and both gave similar results in terms of sensitivity and structural information. The main ions were [M+H]+ for carbendazim, imazalil, thiophanate methyl and thiabendazole, and [M+H-C4H9NHCO]+ for benomyl. Samples were extracted with sodium sulphate and ethyl acetate. Although benomyl and thiophanate methyl were transformed through the extraction procedure to carbendazim, the method showed good precision (<13%) and recovery (>70%), except for thiophanate methyl (50%), whilst also yielding limits of detection (<0.03 mg kg(-1)) that are adequate for the determination of the studied fungicides in oranges.     

Application of a mixed-mode solid-phase extraction and cleanup procedure for LC/MS determination of thiabendazole and carbendazim in apple juice

Recently, a mixed-mode solid-phase extraction (SPE) procedure was developed for rapid extraction and cleanup for determination of the fungicides thiabendazole and carbendazim in various fruit juices. This paper reports the application of that sample preparation procedure to the liquid chromatographic/mass spectrometric determination of these fungicides in apple juice with detection by positive electrospray ionization mass spectrometry (ESI/MS). Response was linear for sample concentrations from 2 to 500 microg/L (ppb). Recoveries averaged 74% (9% RSD) for carbendazim and 93% (9% RSD) for thiabendazole. After SPE cleanup, no matrix supression was observed for the ESI+ response for either compound studied. The method was applied to the analysis of incurred residues in 4 store-bought apple juices; carbendazim levels ranged from 10 to 70 microg/L and thiabendazole levels ranged from less than 2 to 130 microg/L.     

固相萃取-离子交换色谱法测定浓缩苹果汁中残留的苯菌灵、多菌灵、噻菌灵

建立固相萃取-离子交换色谱法测定浓缩苹果汁中苯菌灵、多菌灵和噻菌灵的残留量。样品直接用水稀释后,于80 ℃下将苯菌灵完全转化为多菌灵,再经SCX固相萃取柱富集,采用LC-SCX离子交换色谱柱(25 cm×4.6 mm,5 μm)分离,二极管阵列检测器检测,以0.1 mol/L KH2PO4溶液(pH 2.5)-乙腈(体积比为70 ∶30)为流动相,在1.0 mL/min下等度洗脱,于282 nm波长下检测。在0.02～2.0 mg/L范围内,多菌灵和噻菌灵的峰面积与其浓度呈良好的线性关系,最低检出限均可达到0.004 mg/kg,回收率为94.2%～100.4%,相对标准偏差低于4.2%。该方法简便、快速、灵敏、准确,可用于浓缩苹果汁中苯菌灵、多菌灵和噻菌灵残留量的检测。     

Determination of carbendazim,thiabendazole, and<Emphasis Type="Italic"> o-</Emphasis>phenylphenol residues in lemons by HPLC following sample clean-up by ion-pairing

An efficient analytical method is presented involving effective sample clean-up with solid-phase extraction and HPLC-UV analysis for the simultaneous determination of carbendazim, thiabendazole, and o-phenylphenol residues in lemons. Sample preparation involves extraction with acetonitrile acidified with trifluoroacetic acid and an ethyl acetate/petroleum ether mixture. Purification of the crude extract was carried out with liquid–liquid partitioning after addition of an aqueous ammonia solution. Final clean-up was performed on polymeric reversed-phase cartridges pretreated with sodium dodecyl sulfate. Chromatographic analysis was performed on a reversed-phase HPLC column isocratically eluted with an acetonitrile/water/ammonia mixture and UV detection at 254 nm. The chromatographic method is repeatable, reproducible, and sensitive. Fungicide recoveries from lemon samples fortified at levels of 5 and 1 mg kg^–1 were 81–85% for carbendazim, 96–98% for thiabendazole, and 81–106% for o-phenylphenol with coefficients of variation of 2.5–7.4%. Detection limits for carbendazim, thiabendazole, and o-phenylphenol in lemons were 0.21, 0.27, and 0.51 mg kg^–1, respectively.     

Analysis of the dissipation kinetics of thiophanate‐methyl and its metabolite carbendazim in apple leaves using a modified QuEChERS–UPLC–MS/MS method

As one of the main fungicides for the apple leaf disease control, thiophanate‐methyl (TM) mainly exerts its fungicidal activity in the form of its metabolite carbendazim (MBC), whose dissipation kinetics is very distinct from that of its parent but has been paid little attention. The aim of this work was to investigate the dissipation kinetics of TM and its active metabolite MBC in apple leaves using a modified QuEChERS–UPLC–MS/MS method. The results showed that TM and MBC could be quickly extracted by this modified QuEChERS procedure with recoveries of 81.7–96.5%. The method linearity was in the range of 0.01–50.0 mg kg^?1 with the quantification limit of 0.01 mg kg^?1. Then this method was applied to the analysis of fungicide dissipation kinetics in apple leaves. The results showed that the dissipation kinetics of TM for the test in 3 months can be described by a first‐order kinetics model with a DT₅₀ (dissipation half‐life) range of 5.23–6.03 days and the kinetics for MBC can be described by a first‐order absorption–dissipation model with the T_max (time needed to reach peak concentration) range of 4.78–7.09 days. These models can scientifically describe the behavior of TM and MBC in apple leaves, which provides necessary data for scientific application.     

Determination of thiophanate methyl and carbendazim residues in vegetable samples using microwave-assisted extraction

Microwave-assisted extraction (MAE) was carried out for the determination of the fungicides thiophanate methyl [1.2-alpha-(3-methoxycarbonyl-2-thioureido)benzene] and carbendazim (methyl benzimidazol-2-ylcarbamate) in vegetable samples. Two vegetable samples, cabbage and tomatoes, were fortified with the two pesticides and subjected to MAE followed by cleanup to remove co-extractives prior to analysis by high-performance liquid chromatography (HPLC). Using the selected microwave exposure time and power setting, the recoveries of carbendazim ranged from 69 to 75%. But thiophanate methyl could not be recovered as the parent compound. It was converted and recovered as carbendazim. The conversion was quantitative as confirmed by high-performance liquid chromatography-mass spectrometry (HPLC-MS).     

Mixed-mode solid-phase extraction and cleanup procedures for the liquid chromatographic determination of thiabendazole and carbendazim in fruit juices

Solid-phase extraction (SPE) procedures were developed for rapid cleanup and determination of thiabendazole and carbendazim in orange, apple, and grape juices. Samples were prepared by using an SPE cartridge containing a mixed-mode sorbent with both reversed-phase and strong cation-exchange chemistries. Analysis was by liquid chromatography with photodiode-array UV detection. Orange juice was analyzed by mixed-mode cation-exchange extraction with reversed-phase cleanup; the other juices were analyzed by reversed-phase extraction with cation-exchange cleanup. Recoveries >80% for carbendazim and >90% for thiabendazole. Quantitation limits were 20 microg/L for both analytes.     

分散微固相萃取-超高效液相色谱-高分辨质谱法测定葡萄酒和啤酒中多菌灵和噻菌灵

基于强阳离子交换填料（PCX）,采用分散微固相萃取前处理技术,结合超高效液相色谱-四级杆-静电场轨道阱高分辨质谱联用技术,建立了一种快速测定葡萄酒和啤酒中多菌灵和噻菌灵的方法。通过对分散微固相萃取技术中PCX用量、洗脱溶剂中氨水的体积分数、乙腈的体积分数和洗脱体积的优化,实现了样品中多菌灵和噻菌灵的有效净化。经BEH C₁₈（50 mm×2.1 mm,1.7 μm）色谱柱分离后,通过静电场轨道阱质谱靶向单一离子监测（targeted single ion monitoring,tSIM）结合数据依赖的二级质谱扫描（data dependent tandem mass spectrometry,ddMS²）采集模式进行定性定量分析。待测物多菌灵和噻菌灵在一定浓度范围内均呈良好线性关系,相关系数R²≥0.9999。在葡萄酒和啤酒基质中,多菌灵和噻菌灵的检出限分别为0.02和0.01 μg/L,定量限分别为0.06和0.03 μg/L。在0.1、1.0、100 μg/L 3个添加水平下,多菌灵和噻菌灵的加标回收率分别为95.6%~110.2%和87.5%~102.8%,日内精密度（RSD_r）分别为1.8%~5.2%和1.3%~4.8%,日间精密度（RSD_R）分别为4.3%~8.7%和4.8%~9.4%。该方法快速、简便、灵敏,适用于葡萄酒和啤酒中多菌灵和噻菌灵的残留检测。