固相萃取/气相色谱-质谱分析大米中氟草烟残留

试样采用NaOH-甲醇溶液提取,经EASY柱固相萃取净化后,以甲醇为衍生剂,浓硫酸为催化剂,在93~98℃水浴条件下酯化后,以DB-5 MS柱为分离柱,气相色谱-质谱联用测定。试验结果表明,氟草烟质量浓度为0.05~2 mg/L时,与相应的峰面积或丰度成良好的线性关系,相关系数为0.999 6;添加质量浓度为0.050 0~0.200 mg/kg时,回收率为81%~98%,该法检出限为0.01 mg/kg。     

金银花不同部位中绿原酸和木犀草苷含量的测定

利用HPLC法测定金银花不同部位中绿原酸和木犀草苷。采用ODS-C18色谱柱(250 mm×4.6 mm,5μm),以甲醇-水(0.03 mol/L磷酸)为流动相进行梯度洗脱,流速:1.0 mL/min,检测波长:350 nm,柱温:室温。绿原酸浓度在0~0.4 mg/mL内与峰面积呈良好线性关系(r2=0.999 6),回收率为101.9%~105.2%,相对标准偏差为3.18%(n=6)。木犀草苷浓度在0~0.1 mg/mL内与峰面积呈良好线性关系(r2=0.999 1),平均回收率为100.5%~104.0%,相对标准偏差为3.42%(n=6)。结果表明:金银花、芽等部位绿原酸和木犀草苷的含量较高。     

HPLC法同时测定白花蛇舌草中对香豆酸和熊果酸的含量

建立高效液相色谱法同时测定白花蛇舌草药材中对香豆酸和熊果酸含量的方法。采用Eclipse SB–C18色谱柱(250 mm×4.6 mm,5μm),以甲醇–0.05%甲酸梯度洗脱,流量1 m L/min,对香豆酸和熊果酸的检测波长分别为310 nm和210 nm,柱温30℃。对香豆酸和熊果酸含量分别在0.001 79~0.028 64 mg/m L和0.021 3~0.340 8 mg/m L范围内与色谱峰面积呈良好的线性关系,线性相关系数r分别为0.999 8,0.999 6。对香豆酸和熊果酸的平均加标回收率分别为98.59%,98.23%,测定结果的相对标准偏差分别为0.81%,0.94%(n=6)。样品溶液在24 h内稳定。该方法适用于白花蛇舌草药材中对香豆酸和熊果酸的含量测定。     

大鼠尿液与粪便中氟噻草胺的UPLC-MS/MS法测定

建立了一种测定大鼠尿液和粪便中氟噻草胺含量的超高效液相色谱-串联质谱(UPLC-MS/MS)分析方法。粪便与尿液样品采用乙腈提取;液相色谱分离采用Phenomenex反向C18色谱柱(50 mm×4. 6 mm,5μm),以0. 1%甲酸水和乙腈为流动相,流速0. 6 m L/min;质谱检测采用电喷雾离子源,正离子模式和多反应监测(MRM)方式进行扫描。结果表明:氟噻草胺在尿液(0. 10～10. 0 mg/L)和粪便(0. 25～50. 0 mg/L)中线性关系良好,相关系数r 0. 99,尿液和粪便中氟噻草胺的定量下限分别为0. 10 mg/L和0. 25 mg/L;质控样品的日内与日间相对标准偏差不大于9. 9%。样品稳定性为93. 7%～108%,尿中平均提取回收率为97. 0%～98. 8%,基质效应为98. 8%～107%,均符合生物分析方法验证的要求。考察了大鼠单次灌胃给予氟噻草胺400 mg/kg后的排泄动力学,144 h内尿液与粪便的总累积排泄率为12. 62%,其中尿中的累积排泄率为1. 12%,粪便中的累积排泄率为10. 13%,表明氟噻草胺主要经粪便排泄。该法灵敏、专属、准确,可用于大鼠尿液、粪便中氟噻草胺浓度的测定。     

固相萃取/液相色谱-串联质谱法测定果蔬中草铵膦的残留量

建立了果蔬中草铵膦残留量的液相色谱-串联质谱(LC-MS/MS)分析方法。样品经水提取、二氯甲烷除去脂溶性杂质,强阳离子固相萃取小柱净化,9-芴甲基氯甲酸酯(FMOC-Cl)衍生后,以C18色谱柱(4.6 mm×50 mm,1.8μm)进行分离,5 mmol/L乙酸铵水溶液(含0.1%甲酸)-乙腈(含0.1%甲酸)作为流动相梯度洗脱,电喷雾正离子模式电离(ESI+),多反应监测模式(MRM)检测,内标法定量。方法在0~200μg/L浓度范围内线性关系良好,相关系数(r2)大于0.995。方法检出限为10μg/kg,定量下限为20μg/kg。在不同食品基质中,草铵膦在20,200,500μg/kg加标水平下的平均回收率为80.8%~102.2%,相对标准偏差(RSD)为1.8%~7.9%。该法采用同位素内标定量,有效地消除了样品基质效应,灵敏度高、准确度好,适用于果蔬中草铵膦残留量的监控测定。     

QuEChERS/高效液相色谱法测定棉花田中吡草醚及其代谢物的残留量

建立了棉花植株、棉籽和土壤样品中吡草醚及其主要代谢物E-1的Qu ECh ERS/高效液相色谱-可变波长紫外检测器(HPLC/VWD)检测方法。样品用乙腈-水混合溶液提取,Qu ECh ERS方法净化,以Ultimate XB-C18色谱柱(250 mm×4.6 mm,5μm)进行HPLC分离,检测波长为246 nm,基质匹配标准品外标法定量。结果表明:吡草醚和E-1在0.01~1.0 mg/L质量浓度范围内呈良好线性关系(r20.999)。在棉花植株、棉籽和土壤中分别进行3个浓度的加标回收实验,吡草醚和E-1在样品中的平均回收率分别为83.5%~106.3%和74.9%~102.3%,相对标准偏差(RSD,n=5)分别为0.5%~5.2%和1.6%~19.2%。吡草醚和E-1的检出限(LOD,S/N3)均为0.1 ng,在棉花植株和棉籽中的定量下限(LOQ)均为0.04 mg/kg,在土壤中的LOQ均为0.02 mg/kg。该方法前处理快速、简单、经济,可用于常规实验室棉花植株、棉籽和土壤样品中吡草醚及其代谢物E-1的残留检测。     

RP-HPLC/二极管阵列检测器同时测定飞机草中3种黄酮

应用高效液相色谱法/二极管阵列检测器同时测定了飞机草中木犀草素、槲皮素和山柰酚的含量。色谱柱HiQ sil C18W柱(4.6 mm×25 cm,5μm),流动相V(甲醇)∶V(水)∶V(磷酸)=50∶49.8∶0.2,检测波长槲皮素254 nm,木犀草素和山柰酚360 nm,温度30℃,流速1 mL/min,进样量10μL。确定了以超声波提取法制备飞机草分析样品的方法:溶剂为体积分数85%的乙醇,液固比为10∶1(mL/g),提取时间为1 h。结果表明,3种黄酮在0.01×10-3~0.10×10-3g/mL范围内呈现良好线性关系(R2>0.999 0),平均加样回收率分别为99.601 7%、99.032 6%和99.450 8%,RSD<2%。该方法操作简便、准确度高,可快速测定飞机草中木犀草素、槲皮素和山柰酚3种物质的含量。     

高效液相色谱-串联质谱法测定多种农产品中杀草强的残留量

建立了采用高效液相色谱-串联质谱法(HPLC-MS/MS)检测多种农产品中杀草强残留量的方法。根据样品基质不同,分别采用25%丙酮水溶液(针对小麦、鱼、肉和肝脏样品)、1%乙酸酸化的25%丙酮水溶液(针对玉米和花生样品)、1%乙酸水溶液(针对金银花、姜粉、花椒粉和茶叶样品)及1%乙酸水溶液和二氯甲烷(针对苹果、菠萝、菠菜、胡萝卜和紫苏叶）进行提取,然后依次采用二氯甲烷萃取、PCX或ENVI-Carb固相萃取柱净化后,进行HPLC-MS/MS测定,外标法定量。在0.005～0.1 mg/kg范围内,杀草强的峰面积与其质量浓度有良好的线性关系,相关系数为0.9997。对上述15种不同种类的农产品进行添加回收,回收率为67.5%~98.1%,相对标准偏差为1.0%~9.8%。苹果、菠菜、紫苏叶、玉米、姜、鱼和肉等样品的定量限为0.01 mg/kg,茶叶、金银花、花椒粉的定量限为0.02 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。     

高效液相色谱法对水果中多菌灵与福美双残留的同时测定

建立了高效液相色谱同时测定水果中多菌灵和福美双残留量的方法。样品经二氯甲烷提取,OasisHLB固相萃取柱净化后,经C18色谱柱分离,甲醇-0.05 mol/L甲酸铵溶液(60∶40,体积比)洗脱,紫外检测器进行检测。结果表明,多菌灵、福美双的的线性范围分别为0.01~10.0、0.05~10.0 mg/kg,相关系数分别为1.0、0.9999,检出限分别为0.005、0.03 mg/kg,平均加标回收率为80%~109%。该方法成功用于市售水果样品的测定。     

高效液相色谱法测定化妆品中4种禁用醛酮化合物

建立了同时测定化妆品中4种禁用醛酮化合物(巴豆醛、苯乙酮、2,4-二羟基-3-甲基苯甲醛和2-亚戊基环己酮)的高效液相色谱(HPLC)分析方法。样品使用50%乙腈(体积比)溶液提取,经AQ-C18(4.6 mm×150 mm,5μm)色谱柱分离后,高效液相色谱/二极管阵列检测器检测,以保留时间和紫外吸收光谱定性,外标法定量,高效液相色谱-质谱/质谱法确证。结果表明,4种醛酮化合物在0.05~2.0 mg/L质量浓度范围内呈良好的线性关系,相关系数均不小于0.999 9;方法检出限和定量下限分别为0.5~1.0 mg/kg和1.5~3.0 mg/kg。样品加标回收率为89.0%~106.7%,相对标准偏差(RSDs,n=6)为2.0%~6.9%。该方法准确可靠,适用于化妆品中4种禁用醛酮化合物的测定。     

Reliable peak-finding for MS/MS

A fast, reliable routine has been developed for dynamically reducing the peak-shaped sequential intensity data, normally obtained in a scanning mass spectrometer, to a mass/intensity pair for each peak in the scan. The algorithm is specifically designed for applications such as MS/MS having large dynamic range as well as overlapping and irregular peak shapes. A method of testing the accuracy of real-time peak-finding algorithms is also described and applied to this algorithm.     

红景天苷及其酯化产物的ESI MS和MS/MS裂解途径

糖苷广泛存在于自然界中,常以糖苷酯形式存在,这有效地提高了它们的酯溶性,增加它们在肠内和胞内的吸收[1-3]。红景天苷是一种具有抗疲劳、抗辐射、抗缺氧、提高记忆、延缓衰老等药理活性的天然糖苷[4-8],在此先导化合物的基础上合成了各种红景天苷酯。本文对这类红景天苷酯的E     

MS/MS: Cloned mass spectrometers

Coupling mass spectrometers in tandem (MS/MS) can greatly increase the specificity of MS analysis without significantly decreasing its unusual sensitivity and speed, particularly for trace levels of preselected compounds in complex organic mixtures. MS/MS also gives more detailed structural information for larger organic molecules in submicrogram quantities.     

Analytical performance of the various acquisition modes in Orbitrap MS and MS/MS

Quadrupole Orbitrap instruments (Q Orbitrap) permit high‐resolution mass spectrometry‐based full scan acquisitions and have a number of acquisition modes where the quadrupole isolates a particular mass range prior to a possible fragmentation and high‐resolution mass spectrometry‐based acquisition. Selecting the proper acquisition mode(s) is essential if trace analytes are to be quantified in complex matrix extracts. Depending on the particular requirements, such as sensitivity, selectivity of detection, linear dynamic range, and speed of analysis, different acquisition modes may have to be chosen. This is particularly important in the field of multi‐residue analysis (eg, pesticides or veterinary drugs in food samples) where a large number of analytes within a complex matrix have to be detected and reliably quantified. Meeting the specific detection and quantification performance criteria for every targeted compound may be challenging. It is the aim of this paper to describe the strengths and the limitations of the currently available Q Orbitrap acquisition modes. In addition, the incorporation of targeted acquisitions between full scan experiments is discussed. This approach is intended to integrate compounds that require an additional degree of sensitivity or selectivity into multi‐residue methods.     

Selective detection and identification of phosphopeptides by dansyl MS/MS/MS fragmentation

Protein phosphorylation regulates many cellular processes and pathways, such as cell cycle progression, signal transduction cascades and gene expression. Selective detection of phosphopeptides from proteolytic digests is a challenging and highly relevant task in many proteomics applications. Often phosphopeptides are present in small amounts and need selective isolation or enrichment before identification. Here we report a novel approach to label selectively phospho-Ser/-Thr residues by exploiting the features of a novel linear ion trap mass spectrometer. Using dansyl labelling and MS3 fragmentation, we developed a method useful for the large-scale proteomic profiling of phosphorylation sites. The new residues in the sequence were stable and easily identifiable under general conditions for tandem mass spectrometric sequencing.     

LC/MS and LC/MS/MS determination of protein tryptic digests

Tryptic digests were analyzed by means of online microbore liquid chromatography combined with mass spectrometry (LC/MS) for some common proteins. Following conventional enzymatic digestion with trypsin, the freeze-dried residues were dissolved in high-performance liquid chromatography (HPLC) eluent and subjected to gradient reversed-phase microbore HPLC separation with mass spectrometric detection. The latter was done in the full-scan single or tandem (MS/MS) mass spectrometry mode. The formation of gas-phase ions from dissolved analytes was accomplished at atmospheric pressure by pneumatically assisted electrospray (ion spray) ionization. This produced field-assisted ion evaporation of dissolved ions, which could then be mass-analyzed for molecular mass or structure. In the full-scan LC/MS mode, the masses for the peptide fragments in the tryptic digests can be determined as either their singly or multiply charged ions. When the molecular weights of the peptides lie outside the mass range of the mass spectrometer, the multiply charged feature of these experimental conditions still provides reliable molecular weight determinations. In addition, collision-activated dissociation (CAD) on selected peptide precursor ions provides online LC/MS/MS sequence information for the tryptic fragments. Results are shown for the tryptic digests of horse heart cytochrome c, bovine β-lactoglobulin A, and bovine β-lactoglobulin B.     

Analysis of MS/MS fragmentation of taxoids

The fragmentation pathways of seven types of taxoids were investigated by using a LC-MS/MS method, namely: (1) neutral taxoids with a C-4(20) double bond; (2) taxoids with a C-4(20) double bond and oxygenation at C-14; (3) 5-cinnamoyl taxoids with a C-4(20) double bond; (4) a basic taxoid with a C-4(20) double bond; (5) a taxoid with a C-4(20) epoxide; (6) taxoids with an oxetane ring; and (7) taxoids with an oxetane ring and a phenylisoserine C-13 side chain. Depending on the class of core structure and the substitution pattern, each taxoid gave either the molecular adduct ion [M+NH4]+ or [M+H]+. In the MS/MS, the molecular adduct ion gave characteristic product ions corresponding to the loss of water, acetic acid, benzoic acid, and cinnamic acid or the phenylisoserine group. These could reflect the difference of the substitutions and structural modifications and should be utilized for the structure elucidation oftaxoids by LC-MS.     

Dual parallel electrospray ionization and atmospheric pressure chemical ionization mass spectrometry (MS), MS/MS and MS/MS/MS for the analysis of triacylglycerols and triacylglycerol oxidation products

Two mass spectrometers, in parallel, were employed simultaneously for analysis of triacylglycerols in canola oil, for analysis of triolein oxidation products, and for analysis of triacylglycerol positional isomers separated using reversed-phase high-performance liquid chromatography. A triple quadrupole mass spectrometer was interfaced via an atmospheric pressure chemical ionization (APCI) interface to two reversed-phase liquid chromatographic columns in series. An ion trap mass spectrometer was coupled to the same two columns using an electrospray ionization (ESI) interface, with ammonium formate added as electrolyte. Electrospray ionization mass spectrometry (ESI-MS) under these conditions produced abundant ammonium adduct ions from triacylglycerols, which were then fragmented to produce MS/MS spectra and then fragmented further to produce MS/MS/MS spectra. ESI-MS/MS of the ammoniated adduct ions gave product ion mass spectra which were similar to mass spectra obtained by APCI-MS. ESI-MS/MS produced diacylglycerol fragment ions, and additional fragmentation (MS/MS/MS) produced [RCO](+) (acylium) ions, [RCOO+58](+) ions, and other related ions which allowed assignment of individual acyl chain identities. APCI-MS of triacylglycerol oxidation products produced spectra like those reported previously using APCI-MS. APCI-MS/MS produced ions related to individual fatty acid chains. ESI-MS of triacylglycerol oxidation products produced abundant ammonium adduct ions, even for those molecules which previously produced little or no intact molecular ions under APCI-MS conditions. Fragmentation (MS/MS) of the [M+NH(4)](+) ions produced results similar to those obtained by APCI-MS. Further fragmentation (MS/MS/MS) of the diacylglycerol fragments of oxidation products provided information on the oxidized individual fatty acyl chains. ESI-MS and APCI-MS were found to be complementary techniques, which together contributed to a better understanding of the identities of the products formed by oxidation of triacylglycerols.