分子印迹柱-高效液相色谱法测定猪肉中磺胺嘧啶(英文)

建立了分子印迹柱-高效液相色谱法检测猪肉中磺胺嘧啶残留方法。制备了磺胺嘧啶的分子印迹柱,并优化了分子印迹柱的萃取条件。研究结果表明,在最佳萃取条件下,分子印迹柱-高效液相色谱法的加标回收率≥75.6%,相对标准偏差≤6.1%。分子印迹柱为固相萃取柱可以预浓缩与纯化猪肉样品中磺胺嘧啶。与氧化铝萃取柱比,分子印迹柱具有较好的重复性和萃取效率。本方法已成功用于实际猪肉样品中磺胺嘧啶含量的检测,结果满意。     

固相萃取–高效液相色谱法测定地表水中4种磺胺类抗生素

建立固相萃取–高效液相色谱法测定地表水中磺胺嘧啶、磺胺二甲嘧啶、磺胺氯哒嗪、醋磺胺甲恶唑4种磺胺类抗生素。样品采用HLB柱进行萃取富集,流动相为甲醇–水(体积比为20∶80),流量为0.5 m L/min,用SPD检测器检测,检测波长为270 nm;采用外标法定量。4种磺胺类抗生素质量浓度在4~160 ng/L范围内与色谱峰面积的线性关系良好,相关系数不低于0.998 2,方法检出限为1.0~1.7 ng/L,样品加标回收率为75.2%~97.4%,测定结果的相对标准偏差为2.8%~6.1%(n=7)。该方法操作简便,灵敏度高,可用于地表水中磺胺类抗生素的检测。     

高效液相色谱-串联质谱法测定兽药粉剂中18种磺胺类违禁添加药物

建立了非磺胺类兽药粉剂中磺胺二甲嘧啶、磺胺醋酰、磺胺甲噻二唑、磺胺氯哒嗪、磺胺甲基异唑、磺胺噻唑、磺胺-6-甲氧嘧啶、磺胺甲基嘧啶、磺胺邻二甲氧嘧啶、磺胺吡啶、磺胺对甲氧嘧啶、磺胺甲氧哒嗪、磺胺苯吡唑、磺胺间二甲氧嘧啶、磺胺二甲异唑、磺胺喹啉、磺胺嘧啶、甲氧苄氨嘧啶18种磺胺及其增效剂等违禁添加药物的超高效液相色谱-串联质谱分析方法。样品经甲醇-水(90∶10)萃取后,以乙腈(含0.1%甲酸)和水(含0.1%甲酸)为流动相,C18(2.1 mm×150 mm,5μm)色谱柱分离后,在正离子模式下以电喷雾串联质谱仪进行测定。方法的线性范围为50~2 000μg/kg,18种磺胺类药物残留的检出限为10μg/kg。在50,200,1 000μg/kg 3个浓度水平下进行加标回收实验,平均回收率为86.8%~115%,相对标准偏差为1.0%~9.7%。     

污泥和沉积物中微量大环内酯类、磺胺类抗生素、甲氧苄胺嘧啶和氯霉素的测定

利用超声波辅助萃取(USE)技术,联合固相萃取(SPE)净化浓缩以及液相色谱-电喷雾串联质谱(LC-ESI-MS/MS)技术,建立了城市污泥和河流底泥中微量-痕量大环内酯类、磺胺类抗生素、甲氧苄胺嘧啶和氯霉素的多目标定量分析方法.样品经USE提取,SPE净化后,用LC-ESI-MS/MS检测.选择C18为分析柱,甲醇、5 mmol/L醋酸铵和0.1%甲酸混合溶液为流动相,选择在ESI正电离源下多反应监测(MRM)模式检测.对比了USE和加速溶剂萃取(ASE)对抗生素的萃取效率,优化了萃取条件.结果表明: USE和ASE对所选抗生素的萃取效率相当; 而50%甲醇溶液在酸性条件下(pH 2)萃取效率最好.抗生素的方法检出限为2.2～66.9 ng/g(干重,下同); 回收率介于74.7%～111.8%之间; 相对标准偏差小于10.6%.应用此方法在广州某污水处理厂脱水污泥及某河涌底泥中检测到磺胺二甲基嘧啶、克拉霉素、脱水红霉素及罗红霉素等多种抗生素,含量为6.8～125.6 ng/g.     

快速溶剂萃取–高效液相色谱法测定禽蛋中磺胺嘧啶

建立快速溶剂萃取–高效液相色谱法测定禽蛋中磺胺嘧啶残留的方法。用单因素和正交试验对禽蛋中磺胺嘧啶的萃取条件进行优化,确定了最佳萃取条件:以甲醇为萃取剂,在130℃循环萃取4次,冲洗体积分数为80%,萃取时间为25 min。色谱柱为Hypersil ODS2柱(4.6 mm×250 mm,5μm),流动相为甲醇–0.5%冰乙酸(25∶75),流量为1.0 m L/min,检测波长为265 nm。磺胺嘧啶的质量浓度在0.025~0.500 mg/m L范围内与色谱峰面积呈良好的线性关系,相关系数r=0.999 5,检出限为0.5μg/kg。加标回收率在83.0%~88.2%之间,测定结果的相对标准偏差为2.2%(n=9)。方法的精密度、准确度和基质效应均符合禽蛋样品检测要求,可用于禽蛋中磺胺嘧啶含量的测定。     

超高效液相色谱法检测化妆品中的12种磺胺抗生素

建立了采用超高效液相色谱(UPLC)-二极管阵列检测器（PDA）测定化妆品中12种常见的磺胺抗生素(磺胺、磺胺间甲氧嘧啶、磺胺醋酰、磺胺甲基异唑、磺胺嘧啶、磺胺二甲异唑、磺胺噻唑、磺胺二甲氧嘧啶、磺胺甲基嘧啶、磺胺喹啉、磺胺二甲嘧啶、磺胺硝苯)的方法。采用Acquity UPLCTM BEHC C18 色谱柱(50 mm×2.1 mm, 1.7 μm),流动相为乙腈/0.1%的甲酸水溶液,梯度洗脱。样品经提取、反萃取后,用UPLC-PDA进行分析检测,结合保留时间和紫外光谱进行定性分析,定量检测波长268 nm。12种磺胺的检出限(S/N=3)均为1 μg/g,定量下限(S/N=10)为2～3 μg/g,在1～25 mg/L(磺胺硝苯为0.5～12.5 mg/L)范围内,峰面积和质量浓度的线性关系良好(r>0.9997)。添加水平为40, 8 μg(磺胺硝苯为20, 4 μg)时,12种磺胺的平均回收率分别为86.8%～98.1%和80.1%～96.9%,相对标准偏差小于10%(n=6)。结果表明该方法简单,分离效果好,速度快,能够满足检测化妆品中12种常见的磺胺抗生素的需要。     

液相微萃取-反萃取在磺胺药物残留测定中的应用

利用液相微萃取-反萃取技术,建立测定动物组织中磺胺药物残留量的新方法.将动物组织中磺胺药物经液相微萃取-反萃取后进行高效液相色谱紫外检测.磺胺、磺胺嘧啶、磺胺二甲嘧啶、磺胺喹口恶啉4种磺胺类药物的线性范围均在0.05～10.0 μg/mL,磺胺甲口恶唑的线性范围在0.5～10.0 μg/mL之间,方法的平均回收率不低于80.2%,RSD＜6.8%,检出限为0.1 mg/kg.     

牛奶中12种磺胺类药物残留的高效液相色谱测定方法

建立了高效液相色谱(HPLC)检测牛奶中12种磺胺类药物(磺胺二甲基嘧啶、磺胺间甲氧嘧啶、磺胺甲噁唑、磺胺对甲氧嘧啶、磺胺喹噁啉、磺胺氯哒嗪、磺胺氯吡嗪、磺胺嘧啶、磺胺噻唑、磺胺甲基嘧啶、磺胺甲噻二唑、磺胺地索辛)残留的方法,考察了样品的提取、净化及色谱分析条件。牛奶样经乙酸乙酯提取、固相萃取净化后上机分析,11种磺胺药物标准曲线在10~800μg/L,SM2在5~200μg/L质量浓度范围内相关系数r>0.999,回收率为76%~106%,相对标准偏差小于15.9%。检出限为5~8μg/L,定量下限为14~27μg/L。     

固相萃取–高效液相色谱法同时测定饲料中4种磺胺类药物残留

建立固相萃取–高效液相色谱法同时测定饲料中的磺胺嘧啶、磺胺二甲嘧啶、磺胺甲恶唑、磺胺喹恶啉4种磺胺类药物残留的方法。样品用乙腈提取,然后用碱性氧化铝固相萃取柱净化,色谱柱为C_(18)柱(250 mm×4.6mm,5μm),以水–乙腈(体积比为75∶25,含0.3%乙酸)为流动相,流量为1.0 mL/min,检测波长为270 nm。4种磺胺类药物的质量浓度在1~10μg/mL范围内与其色谱峰面积呈良好的线性,相关系数均大于0.999,检出限为0.025~0.133μg/g。磺胺类药物测定结果的相对标准偏差为0.22%~0.30%(n=6),样品加标回收率为93.6%~106.7%。实际饲料样品中均未检出这4种磺胺组分。该方法具有干扰少,灵敏度高,重复性好的优点,可以作为饲料中的磺胺类药物残留的一种检测方法。     

基质固相分散-超快速液相色谱法测定牛肉中磺胺类兽药

采用基质固相分散-超快速液相色谱测定了牛肉组织中磺胺噻唑、磺胺甲基嘧啶、磺胺甲基异恶唑和磺胺间二甲氧嘧啶。基质固相分散萃取的最佳条件为:硅藻土为分散剂,6 mL甲醇为洗脱剂,样品与分散剂的质量比为1∶4。方法的检出限为4.39～7.82 ng/g,定量限为14.62～26.08 ng/g,4种磺胺化合物回收率为71.73%～113.13%,测定的相对标准偏差为1.9%～12.7%。     

Multiresidue determination of sulfonamides in chicken meat by polymer monolith microextraction and capillary zone electrophoresis with field-amplified sample stacking

A method based on poly(methacrylic acid-co-ethylene glycol dimethacrylate) (MAA-EGDMA) monolith microextraction (PMME) and online preconcentration technique of field-amplified sample stacking (FASS) was proposed for sensitive capillary electrophoresis-ultraviolet (CE-UV) analysis of 12 sulfonamides (sulfamethazine, sulfamethoxypyridazine, sulfathiazole, sulfamerazine, sulfameter, sulfadoxine, sulfadimethoxine, sulfamonomethoxine sodium, sulfachlorpyridazine, sulfamethoxazole, sulfamethizole, and sulfisoxazole) in chicken samples. The conditions of PMME were optimized for the improvement of extraction efficiency and reduction of the matrix interferences from chicken sample. The best separation was achieved within 15min using a buffer of 100mM phosphate electrolyte (pH 7.3) with temperature and voltage of 20 degrees C and 25kV, respectively. By applying FASS, detection limits of 3.49-16.7ng/g were achieved with satisfactory precision (RSD<==13%) and recovery (96.3-104%) over a linear range of 50-1000ng/g for most analytes.     

Preparation, evaluation and application of molecularly imprinted solid-phase microextraction monolith for selective extraction of pirimicarb in tomato and pear

A simple, rapid and sensitive method for the determination of pirimicarb in tomato and pear using polymer monolith microextraction (PMME) based on the molecularly imprinted polymer (MIP) monolith combined with high-performance liquid chromatography-photodiodes array detector (HPLC-PAD) was developed. By optimizing the polymerization conditions, such as the nature of porogenic solvent and functional monomer, the molar ratio of the monomer and cross-linker, an pirimicarb MIP monolith was synthesized in a micropipette tip using methacrylic acid (MAA) as the functional monomer, ethylene dimethacrylate (EGDMA) as the cross-linker and the mixture of toluene-dodecanol as the porogenic solvent. The MIP monolith showed highly specific recognition for the template pirimicarb. The monolith was applied for the selective extraction of pirimicarb in tomato and pear. Several parameters affecting MIP-PMME were investigated, including the nature and volume of extraction solvent, sample volume, flow rate and sample pH. Under the optimum PMME and HPLC conditions, the linear ranges were 2.0-1400 μg/kg for pirimicarb in tomato and pear with the correlation coefficient of above 0.999. The detection limits (s/n=3) were both 0.6 μg/kg. The proposed method was successfully applied for the selective extraction and determination of pirimicarb in tomato and pear.     

新型强阳离子交换聚合物整体柱的制备及其在奶制品中三聚氰胺测定中的应用

在内径为530 μm的石英毛细管中原位聚合得到一种新的强阳离子交换聚合物整体柱2-丙烯酰胺-2-甲基-1-丙磺酸-乙二醇二甲基丙烯酸酯聚合物(poly(AMPS-co-EDMA))整体柱,并将其作为聚合物整体柱微萃取(PMME)的萃取介质。优化N,N-二甲基甲酰胺(DMF)和聚乙二醇(PEG)致孔体系的比例,制备得到的poly(AMPS-co-EDMA)整体柱渗透性好、机械强度高且在水溶液中具有良好的稳定性。通过考察样品溶液的pH值、盐浓度和有机溶剂含量对萃取效率的影响,证明该整体柱主要通过强阳离子交换和疏水相互作用对三聚氰胺进行萃取富集。在PMME与高效液相色谱联用技术的基础上,建立了检测奶制品中三聚氰胺含量的分析方法。奶制品中三聚氰胺的检出限和定量限分别为0.09 mg/kg和0.3 mg/kg,在0.5~80 mg/kg的含量范围内具有良好的线性关系,日内、日间测定的相对标准偏差不高于7.5%。结果表明,该方法简便、快速、灵敏度高且成本低,适合于奶制品中微量三聚氰胺的检测。     

Multiresidue analysis of beta-agonists in pork by coupling polymer monolith microextraction to electrospray quadrupole time-of-flight mass spectrometry

A novel method of polymer monolith microextraction (PMME) using poly(methacrylic acid-co-ethylene glycol dimethacrylate) monolith combined with electrospray ionization quadrupole time-of-flight mass spectrometry (ESI-QTOF MS) was developed for the rapid and sensitive determination of beta-agonists in pork samples. The conditions of PMME were optimized for the improvement of extraction efficiency and reduction of the matrix interferences from pork. Under the optimal condition, the eluate solution allowed direct analysis by mass spectrometry. In the positive ion mode and in the multiple reaction monitoring (MRM) mode, the limits of detection (LODs) for beta-agonists were found to be 0.08 ng/g (clenbuterol, CLB), 0.18 ng/g (salbutamol, SBTM) and 0.26 ng/g (terbutaline, TBTL) in pork, respectively, with good inter- and intra-day precisions (2-10% for CLB, 11-23% for SBTM and 4-16% for TBTL). The proposed PMME/ESI-QTOF MS method was successfully applied to the determination of beta-agonist residues in thirteen real samples, and the positive samples were confirmed according to the identification points (IPs) system defined by Commission Decision 2002/657/EC. To investigate the matrix effect, the proposed method was compared with PMME-HPLC/ESI-QTOF MS and the slight decrease in sensitivity of PMME/ESI-QTOF MS was ascribed to the inter-analyte ion suppression.     

Polymer Monolith Microextraction Coupled with HPLC for Determination of Jasmonates in Wintersweet Flowers

A simple, fast, and effective method has been presented for the determination of jasmonates in plant samples by polymer monolith microextraction (PMME). A poly (methacrylic acid-ethylene glycol dimethacrylate) (MAA-EGDMA) monolith-based device was developed for extraction, purification, and concentration; HPLC-UV was used for evaluation. To realize the best microextraction efficiency, parameters such as sample pH value, flow rate, and sample volume were systematically examined and optimized. Aqueous solution (5 mL) of jasmonates at pH 3.0 was selected as sample solution, and loaded onto the monolith at flow rate of 0.15 mL/min; finally, 50 μL of acetonitrile was used for elution. The proposed method exhibited impressive enrichment efficiency (almost 100-fold) and the limits of detection for jasmonic acid and methyl jasmonate obtained 0.5 and 2 ng/mL by using UV detection. Wide linear ranges were also observed (2–2000 and 5–2000 ng/mL) for both jasmonic acid and methyl jasmonate, with R² > 0.999. The developed PMME-HPLC method was successfully applied to the determination of jasmonates in fresh wintersweet flowers with recoveries in the range of 91.9–97.2%. The result was confirmed by an HPLC-MS method. The PMME method was also compared with a conventional C18-SPE method and exhibited better clean-up efficiency.     

Rapid determination of Δ-Tetrahydrocannabinol in saliva by polymer monolith microextraction combined with gas chromatography-mass spectrometry

A method was developed for the determination of Δ⁹-Tetrahydrocannabinol (THC) in saliva by polymer monolith microextraction (PMME) combined with gas chromatography-mass spectrometry. The poly(methacrylic acid-co-ethylene glycol dimethacrylate) (p(MAA-co-EGDMA)) monolithic capillary column was selected as the extraction medium of PMME, which showed high extraction capacity towards THC in saliva. To reach optimum PMME extraction performance, several PMME parameters were investigated, including matrix pH, flow rate for extraction, sampling volume and elution solvent. Under the optimal conditions, good extraction efficiency was obtained with no matrix interference in the process of extraction and the subsequent GC-MS analysis. In the selected-ion monitoring (SIM) mode, the limit of detection (LOD) for THC was 0.68 ng/mL. The linearity range of the method was 3-300 ng/mL. Excellent reproducibility of the method was exhibited by intra- and inter-day precisions, yielding the relative standard deviations (R.S.D.s) less than 12%; recoveries higher than 89%. The proposed method was proved to be rapid, sensitive, and competently applied to the determination of THC in saliva samples.     

聚合物整体柱固相微萃取-高效液相色谱法测定中成药和保健食品中枸橼酸西地那非

采用聚(甲基丙烯酸-乙二醇二甲基丙烯酸酯)聚合物整体柱固相微萃取(PMME),并与高效液相色谱联用,建立了中成药中枸橼酸西地那非的检测方法。实验优化了影响萃取效率的因素,包括萃取流速、萃取体积、样品基质pH值等参数。中成药样品经溶解和过滤后可直接进行分离分析。结果表明,枸橼酸西地那非在0.5～50μg/mL的浓度范围内具有良好的线性关系,检出限为0.05μg/mL,日内、日间测定的相对标准偏差不高于9.7%。方法已成功地应用到实际样品检测中,其加标回收率大于83.40%。该方法简单、快速、灵敏度高,适用于中成药及保健品中西地那非的分析检测。     

溶胶-凝胶杂化整体柱修饰及在多环芳烃检测中的应用

利用点击反应对含叠氮基的溶胶-凝胶整体柱进行了表面修饰,制备了C₆-硅胶杂化整体萃取柱。实验以多环芳烃为分析对象,考察了制备和修饰条件对萃取效率的影响,在优化的条件下,新制备的整体柱对萘、菲、芘和苯并[a]芘的萃取富集倍数分别达到95.9、114.2、103.2和57.8。萃取实验的日内和日间精密度(RSD)分别小于5.5%(n=8)和7.3%(n=10)。建立的管内固相微萃取-高效液相色谱检测16种常见多环芳烃方法的检出限(S/N=3)达到0.08~3.72 μg/L,定量限(S/N=10)达到0.26~12.40 μg/L。土壤中多环芳烃分析的加标回收率为82.4%~110.6%, RSD为2.6%~7.9%(n=3)。与美国国家环境保护局检测土壤中多环芳烃的方法比较,结果一致,准确性高。实验表明,该方法萃取效率高,灵敏可靠,操作简便,重现性好,可满足土壤等样品中痕量多环芳烃检测的要求。     

Multiresidue determination of (fluoro)quinolone antibiotics in chicken by polymer monolith microextraction and field-amplified sample stacking procedures coupled to CE-UV

Simultaneous determination of 9 (fluoro)quinolone antibiotics (FQs) was accomplished by capillary electrophoresis-ultraviolet (CE-UV) based on poly(methacrylic acid-co-ethylene glycol dimethacrylate) (MAA-EGDMA) monolith microextraction (PMME) coupled with on-line preconcentration technique of field-amplified sample stacking (FASS). The effects of composition of the acid and organic solvent in the sample solution, sampling time, and voltage on the efficiency of the sample stacking have been systematically investigated. Several parameters that influence extraction efficiency for PMME such as pH of sample solution, extraction volume, and wash and desorption conditions were optimized. In the proposed method, a substantial increase in sensitivity for all the FQs tested was achieved by the combination of PMME procedure with on-line preconcentration of FASS prior to CE analysis. Good linearities were obtained for the 9 tested FQs with the correlation coefficients (R) above 0.9954. The limits of detection (S/N = 3) were found to be 2.4-34.0 ng g⁻¹ and the recoveries ranged from 81.2 to 100% with relative standard deviations less than 11.3%. The proposed PMME-FASS-CE method was applied to the determination of FQs residues in chicken samples.     

Polymer monolith microextraction online coupled to hydrophilic interaction chromatography/mass spectrometry for analysis of β2‐agonist in human urine

An analytical method based on online combination of polymer monolith microextraction (PMME) technique with hydrophilic interaction LC (HILIC)/MS is presented. The extraction was performed with a poly(methacrylic acid‐co‐ethylene glycol dimethacrylate) monolithic column while the subsequent separation was carried out on a Luna silica column by HILIC. After 1:1 v/v dilution with 20 mM phosphate solution at pH 7.0 and centrifugation, urine sample was directly used for extraction. After optimization, 85% ACN (containing 0.3% formic acid v/v) was used for rapid online elution, which was also the mobile phase in HILIC to avoid band broadening during separation or carry‐over that was usually observed in PMME‐RP LC system. Online automation of extraction and separation procedures was realized under the control of a program in this study. The developed method was applied to rapid and sensitive monitoring of three β₂‐agonist traces in human urine. The LODs (S/N = 3) of the method were found to be 0.05–0.09 ng/mL of β₂‐agonists in urine. The recoveries of three β₂‐agonists spiked in five different urine samples ranged from 79.8 to 119.8%, with RSDs less than 18.0%.