气相色谱-质谱法测定聚醚砜奶瓶中二苯砜的含量及迁移量

采用气相色谱-质谱联用仪(GC-MS)对聚醚砜(PES)奶瓶中的二苯砜进行定性确证和定量分析。样品粉碎并用三氯甲烷超声溶解后,用乙腈沉淀树脂。选用HP-5MS色谱柱并使用选择离子扫描(SIM)模式进行定性和定量分析。定性离子为m/z77、97、125和218,定量离子为m/z125。二苯砜的线性范围为0.1～100mg/L,仪器的定量检出限为0.004mg/L。奶瓶样品中二苯砜的加标回收率为91%～113%,相对标准偏差(RSD)小于7.7%。将奶瓶进行迁移实验后,水、酸性和油性食品模拟物分析的加标回收率分别为88%～102%、96%～111%和89%～110%,RSD分别为5.2%、5.4%和8.7%。     

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。     

液相色谱-串联质谱测定面条和米粉中的硫脲

建立了米面制品中硫脲的液相色谱-串联质谱(LC-MS/MS)测定方法.实验优化了样品提取方法、液相色谱条件和质谱参数.样品用80%乙醇超声波提取,离子交换色谱分离,色谱柱为NUCLEOSIL 100-5SA 阳离子交换柱,流动相为乙腈-(1%乙酸+0.2%乙酸铵)水溶液(30: 70),流速0.5mL/min.采用电喷雾质谱正离子模式电离,多反应选择离子检测,检测离子对为m/z 77/60和m/z 77/43,其中m/z 77/60为定量离子对.结果表明: 本方法简便快速、准确可靠,相对标准偏差＜4.0%;回收率为83%～90%;检出限为0.5 mg/kg;定量下限为 5 mg/kg.     

气相色谱/质谱法测定猪肉中4种苯二氮(艹卓)类镇静剂残留

建立了同时测定猪肉中4种苯二氮类药物(地西泮、艾司唑仑、阿普唑仑、三唑仑)残留量的固相萃取气相色谱质谱方法。用乙腈提取药物,C18固相萃取柱净化,GC/MS分析。运用HP5毛细管柱(30m×0.25mm×0.25μm)进行分离,电子轰击电离源(EI)质谱选择离子模式(SIM)检测(地西泮m/z241、256、257、284;艾司唑仑m/z205、239、259、294;阿普唑仑m/z204、273、279、308;三唑仑m/z238、313、315、342),外标法定量(定量离子m/z分别为256、259、270和313)。4种苯二氮类药物的标准曲线线性回归系数均在0.99以上,地西泮线性范围超过5～100μg/L;回收率为60%～70%;相对标准偏差7.6%～12.9%,最低检出限为2μg/kg。艾司唑仑、阿普唑仑、三唑仑3种药物的线性范围超过50～1000μg/L;回收率为60%～115%;相对标准偏差3.8%～19.7%,检出限为10μg/kg。     

液相色谱-串联质谱检测蔬菜和茶叶中吡虫啉的残留量

介绍了利用液相色谱-串联质谱（LC-MS/MS）快速、准确地测定蔬菜、茶叶产品中吡虫啉残留量的方法。前处理方法为用乙腈提取,再用弗罗里硅土和活性炭混合柱净化。用多反应监测技术确定吡虫啉的两对离子(m/z 256.0/209.3,m/z 256.0/175.2)为定性离子对,m/z 209.3为定量离子。方法的定量限为0.01 mg/kg,线性范围为0.01～0.5 mg/L,加标回收率为76%～90%,相对标准偏差（RSD）为7.4%～11.0%。     

正交试验优化-顶空固相微萃取-气相色谱-串联质谱法测定水中戊二醛

建立了顶空固相微萃取-气相色谱-串联质谱测定水中戊二醛的方法。设计5因素4水平完整的正交试验,通过极差分析获得顶空固相微萃取优化条件。10 mL,pH 1的水样加入6 g NaCl,经非极性PDM S,100μm纤维头于75℃萃取25 min,210℃解析进样0.2 min。采用VF-5(60 m×0.25 mm×0.25μm)色谱柱程序升温分离,选择多反应监测(M RM)模式采集质谱信息。以m/z 82/54为定量离子,以m/z 82/39为定性离子,外标法定量。结果表明,戊二醛质量浓度在0.02~0.6 mg/L范围内线性良好,相关系数(r)>0.9996,方法检出限7μg/L,定量限20μg/L。低(0.04 mg/L)、中(0.1 mg/L)、高(0.4 mg/L)3个水平加标回收率为87.4%~103.7%,相对标准偏差(RSD)<6%。方法适用于测定水中的戊二醛。     

高效液相色谱法同时测定稻田中苄嘧磺隆和苯噻酰草胺残留

建立了同时测定稻田(稻田土壤、水和植株)中苄嘧磺隆和苯噻酰草胺残留量的高效液相色谱(HPLC)分析方法。稻田水样品用二氯甲烷直接萃取;稻田土壤样品用碱性乙腈-二氯甲烷(1:1, v/v)混合液直接提取;水稻植株样品用碱性二氯甲烷提取后,二氯甲烷提取液经弗罗里硅土柱净化。上述样品溶液采用C18不锈钢色谱柱(150 mm×4.6 mm, 5 μm)分离,流动相为水-甲醇(30:70, v/v),流速为0.5 mL/min,柱温为30 ℃,紫外检测波长为238 nm,外标法定量。苄嘧磺隆和苯噻酰草胺在0.05～5.00 mg/L范围内的线性关系均很好(r＞0.9999)。在稻田水、土壤和水稻植株中添加3个水平(0.05, 0.10, 1.00 mg/kg)的苄嘧磺隆和苯噻酰草胺,两者的回收率均在85.39%～113.33%之间,相对标准偏差为0.91%～10.24%。这表明该方法的灵敏度、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-串联质谱法对家畜尿液中苯乙醇胺A残留检测研究

建立了高效液相色谱-串联质谱(HPLC-MS/MS)检测猪尿、牛尿和羊尿中苯乙醇胺A残留的方法。尿液经酶解、加入内标物、乙酸乙酯萃取、MCX固相萃取柱净化后,供HPLC-MS/MS检测。采用电喷雾离子源正模式,在多反应检测(MRM)模式下分析,苯乙醇胺A定性离子对分别为m/z 345/150和345/327,定量离子对为m/z 345/327;苯乙醇胺A内标物定性离子对为m/z 348/330,定量离子对为m/z 348/330。苯乙醇胺A含量在0～50.0μg/L范围内的线性关系良好(R2=0.9990);检出限为0.03μg/L,定量限为0.1μg/L。在猪尿、牛尿和羊尿中的回收率分别78.4%～82.9%,85.7%～93.3%和79.8%～84.9%;相对标准偏差分别为0.8%～4.2%,1.6%～5.6%和2.9%～5.8%。     

SPE-HPLC-MS定量法测定果蔬中农药马拉硫磷残留量

建立了SPE-HPLC-MS法定量测定果蔬中农药马拉硫磷残留量。固相萃取小柱为SupelcleanTM ENVITM-18柱（3 mL）,丙酮为洗脱液;色谱柱为安捷伦快速高分离亚二微米液相色谱柱Zorbax RRHTSB-C18（1.8μm,4.6 mmi.d.&#215;50mm,Agilent）;流动相为70%甲醇（含2 mmoL甲酸铵）＋30%水,等梯度洗脱;质谱采用正离子电离方式,选择m/z 283和m/z 243碎片离子为定性离子,以丰度最高的碎片离子m/z 283为定量离子,用MRM模式监测;外标法定量。方法相关系数r2=0.9968,检出限（LOD）为0.002 mg/kg,加标回收率为78.3%-96.2%,相对标准偏差（RSD）为3.5%-18.8%,适合样品中低含量马拉硫磷残留量的测定。     

气相色谱-质谱联用对菠菜中丁烯氟虫腈残留的检测

建立了固相萃取(SPE)/气相色谱-质谱(GC-MS)测定菠菜中丁烯氟虫腈残留量的分析方法.利用乙腈提取,提取液依次过无水硫酸钠、氯化钠和PSA固相萃取柱后采用GC-MS进行检测,选择定量离子m/z 403,选择定性离子m/z 421、55、213、371.6次重复测定峰面积的相对标准偏差小于10%;定量下限为0.05 mg/kg,检出限为0.01 mg/kg,在0.05 ～100 mg/kg范围内具有良好的线性关系,为丁烯氟虫腈的检测和判断提供了方法.     

气相色谱-质谱法测定乳制品中光引发剂异丙基硫杂蒽酮的残留量

建立了采用气相色谱（GC）-质谱(MS)检测由包装材料迁移到乳制品中的光引发剂异丙基硫杂蒽酮残留量的方法。使用氘代蒽为内标,样品经Carrez试剂除蛋白质后用丙酮-正己烷(体积比为1∶1)提取,上层提取液用氟罗里硅土固相萃取小柱净化。采用单四极杆质谱进行样品筛选和定量,选取的监测离子为m/z 184,m/z 224,m/z 239,m/z 254(异丙基硫杂蒽酮)和m/z 80,m/z 94,m/z 188,m/z 160(氘代蒽)。疑似样品采用离子阱串联质谱法进行确证,选取的母离子和子离子分别为m/z 254,m/z 239(异丙基硫杂蒽酮)和m/z 188,m/z 160(氘代蒽)。本方法的测定低限(LOQ)分别为7.0 μg/L(GC-MS)和5.0 μg/L(GC-MS/MS),回收率为74.9%~89.6%。采用该方法对11种不同类型的乳制品进行了检测,发现了两例阳性样品。     

液相色谱-串联质谱法测定虾夷扇贝和长牡蛎中软骨藻酸的残留

建立了液相色谱-串联质谱测定虾夷扇贝和长牡蛎中贝类毒素软骨藻酸残留的检测方法。样品经50%甲醇提取,LC-SAX柱净化,3mL0.1mol/L甲酸溶液洗脱,电喷雾离子源(ESI),在正离子、多反应监测方式(MRM)模式下进行定性与定量,定性离子对为m/z 311.98/265.91,m/z 311.98/247.9,m/z 311.98/192.91,以m/z 311.98/265.91为定量离子对,外标法定量。结果表明,方法的检测限为0.01μg/g,定量限为0.02μg/g。在0.02~10μg/mL范围内线性相关系数为0.9999。当添加软骨藻酸质量分数为20~1000 ng/g时,虾夷扇贝样品中软骨藻酸的平均回收率为81.3%~105.4%,RSD为3.9%~8.9%(n=6);长牡蛎样品中软骨藻酸的平均回收率为83.5%~106.6%,RSD为4.6%~6.4%(n=6)。方法满足对贝类产品中软骨藻酸残留的测定。     

An improved liquid chromatography/tandem mass spectrometry method for the determination of 8-oxo-7,8-dihydro-2'-deoxyguanosine in DNA samples using immunoaffinity column purification

The analysis of 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxodG) represents an important biomarker of oxidative stress. A sensitive method for the detection of 8-oxodG in DNA samples has been developed that utilizes immunoaffinity column purification of 8-oxodG followed by liquid chromatography/mass spectrometry/mass spectrometry (LC/MS/MS) multiple reaction monitoring (MRM) mode analysis. An internal standard of stable-isotopically labelled 8-oxodG containing [(15)N(5)] was added prior to the enzymatic digestion of DNA to deoxynucleosides, which was then subjected to immunoaffinity column purification followed by microbore positive ion LC/MS/MS MRM. The 8-oxo-7,8-dihydroguanine (8-oxoG) base product ion at m/z 168 was monitored following cleavage of the glycosidic bond of the 8-oxodG [M+H](+) ion at m/z 284. Similar determinations were made for [(15)N(5)]8-oxodG by monitoring the [(15)N(5)]8-oxoG base product ion at m/z 173 formed from the [M+H](+) ion at m/z 289. The introduction of the immunoaffinity column purification step into the method represents a significant improvement for the accurate determination of 8-oxodG since all artefactual peaks that are observed following the direct injection of digested DNA onto the LC/MS/MS system are removed. The identity of these artefactual peaks has been confirmed to be 2'-deoxyguanosine (dG), thymidine (dT) and 2'-deoxyadenosine (dA). The presence of these artefactual peaks in MRM mode analysis can be explained as a consequence of a concentration effect due to their considerably higher relative abundance in DNA compared to 8-oxodG. The highest signal intensity was observed for the artefactual peak for dA due to the fact that the adenine base formed an adduct with methanol, which is a constituent of the mobile phase. The resulting [M+H](+) ion at m/z 284 (dA m/z 252 + CH(3)OH m/z 32) gave rise to a product ion at m/z 168 following the loss of deoxyribose in MRM mode analysis. Control calf thymus DNA was digested to deoxynucleosides and unmodfied deoxynucleosides were removed by immunoaffinity column purification; the enriched 8-oxodG was determined by LC/MS/MS MRM. The level of 8-oxodG in control calf thymus DNA was determined to be 28.8 +/- 1.2 8-oxodG per 10(6) unmodified nucleotides (n = 5) using 5 microg of digested DNA. The limit of detection of the microbore LC/MS/MS MRM for 8-oxodG was determined to be 25 fmol on-column with a signal-to-noise ratio of 3.5.     

Determination of the Fusarium mycotoxins, fusaproliferin and beauvericin by high-performance liquid chromatography-electrospray ionization mass spectrometry.

A method is described using LC-MS for the detection of the mycotoxins fusaproliferin (FUS) and beauvericin (BEA) in cultures of Fusarium subglutinans and in naturally contaminated maize. Protonated molecular ion signals for FUS and BEA were observed at m/z 445 and m/z 784, respectively. Collision induced dissociation of the readily dehydrated protonated molecular ion of the sesterterpene FUS (m/z 427) led to the loss of another water molecule (m/z 409) and acetic acid (m/z 385), while the cyclic lactone trimer BEA fragmented to yield the protonated dimer (m/z 523) and monomer (m/z 262), respectively. Detection of FUS was best performed in the MS-MS mode while BEA displayed a stronger signal in the MS mode. The on-column instrumental detection limits for pure FUS and BEA were found to be 2 ng and 20 pg (S/N=2) while those in naturally contaminated maize were 1 microg/kg and 0.5 microg/kg, respectively. Five South African strains of F. subglutinans were analyzed following methanol extraction of which four produced FUS at levels between 330 mg/kg and 2630 mg/kg while only three produced BEA at levels between 140 mg/kg and 700 mg/kg. Application of this method to naturally contaminated maize samples from the Transkei region of South Africa showed FUS at levels of 8.8-39.6 microg/kg and BEA at 7.6-238.8 microg/kg.     

气相色谱-质谱法测定纺织品中N-乙基全氟辛烷磺酰胺

提出了用气相色谱-质谱法测定纺织品中N-乙基全氟辛烷磺酰胺的方法。试样经甲醇超声提取后,在旋转蒸发仪中浓缩至5 mL,通过DB-5MS色谱柱分离,采用选择离子监测模式检测,定性离子为m/z69,108,131,169,448,定量离子为m/z108。N-乙基全氟辛烷磺酰胺的质量浓度在0.2~20.0 mg.L-1范围内与峰面积呈线性关系,检出限(3S/N)为0.69μg.L-1。用标准加入法做回收试验,测定平均回收率为97%。     

Observation of Na(+)-bound oligomers of quercetin in the gas phase

While developing a liquid chromatography/tandem mass spectrometry method for the analysis of the flavonoid quercitin, it was observed that quercetin (3,3',4',5,7-pentahydroxyflavone) exhibited clustering in both the positive and negative ion mode. Two series of positive ion clusters were observed; the first series corresponds to singly charged [2M + Na](+) at m/z 627.2 to [13M + Na](+) at m/z 3947.5, while the second series corresponds to doubly charged [7M + 2Na](2+) at m/z 1080.4 to [25M + 2Na](2+) at m/z 3798.5. In the negative ion mode, the behavior of quercetin parallels that of apigenin (4',5,7-trihydroxyflavone) in that [M + NO(3)](-), [2M + NO(3)](-), and [3M + NO(3)](-) were observed at m/z 364.1, 666.0, and 968.9, respectively; in addition, quercitin clusters with chloride ions ([2M + Cl](-) at m/z 638.9 and [3M + Cl](-) at m/z 940. 9) were observed. The results of tandem mass spectrometric examination of several cluster ions are reported.     

Mass spectrometric characterization of toremifene metabolites in human urine by liquid chromatography-tandem mass spectrometry with different scan modes

The metabolism and excretion of toremifene were investigated in one healthy male volunteer after a single oral administration of 120 mg toremifene citrate. Different liquid chromatographic/tandem mass spectrometric (LC/MS/MS) scanning techniques were carried out for the characterization of the metabolites in human urine for doping control purposes. The potential characteristic fragmentation pathways of toremifene and its major metabolites were presented. An approach for the metabolism study of toremifene and its analogs by liquid chromatography-tandem mass spectrometry was established. Five different LC/MS/MS scanning methods based on precursor ion scan (precursor ion scan of m/z 72.2, 58.2, 44.2, 45.2, 88.2 relative to five metabolic pathways) in positive ion mode were assessed to recognize the metabolites. Based on product ion scan and precursor ion scan techniques, the metabolites were proposed to be identified as 4-hydroxy-toremifene (m/z 422.4), 4'-hydroxy-toremifene (m/z 422.4), α-hydroxy-toremifene (m/z 422.4), 3,4-dihydroxy-toremifene (m/z 404.2), toremifene acid (m/z 402.2), 3-hydroxy-4-methoxy-toremifene (m/z 456.2), dihydroxy-dehydro-toremifene (m/z 440.2), 3,4-dihydroxy-toremifene (m/z 438.2), N-demethyl-4-hydroxy-toremifene (m/z 408.3), N-demethyl-3-hydroxy-4-methoxy-toremifene (m/z 438.3). In addition, a new metabolite with a protonated molecule at m/z 390.3 was detected in all urine samples. The compound was identified by LC/MS/MS as N-demethyl-4,4'-dihydroxy-tamoxifene. The results indicated that 3,4-dihydroxy-toremifene (m/z 404.2), toremifene acid (m/z 402.2) and N-demethyl-4,4'-dihydroxy-tamoxifene (m/z 390.3) were major metabolites in human urine.     

UPLC-MRM法测定饲料中的三聚氰胺

提出了一种UPLC-MRM测定饲料中微量三聚氰胺的分析方法. 饲料经10 g/L三氯乙酸溶液提取和22 g/L乙酸铅溶液沉淀蛋白质, 过混合型阳离子交换柱(MCX)纯化, 离心后用0.45 μm滤膜过滤, 用超高效液相色谱-质谱-质谱联用仪(UPLC-MS-MS)分析测定, 以三聚氰胺母离子126.9 (m/z)和子离子67.5与84.6 (m/z)定性、定量目标物. 饲料样品加标回收率(n=6)为84.5%, 检测限0.01 μg/L, 相对偏差(RSD) 6.5%.     

Capillary zone electrophoresis/mass spectrometry of 5-aminolaevulinic acid and porphobilinogen

A capillary zone electrophoresis/electrospray ionisation mass spectrometry (CZE/ESI-MS) method has been developed for the separation and detection of 5-aminolaevulinic acid (ALA) and porphobilinogen (PBG). Capillaries were 70 cm long with an inner diameter of 75 micrometer and outer diameter of 375 micrometer. The buffer used was aqueous ammonium acetate (50mM, pH 5.2) with a co-axial 'make-up' flow of methanol/aqueous 0.1% formic acid (1:1 v/v) at a flowrate of 6 microL/min. A voltage of 20 kV was used for CZE and an ESI voltage of 3.5 kV. Full scan data was acquired over the range m/z 100-500 in positive ion mode, from which selected ion electropherograms were extracted; at m/z 132 for the protonated molecular ion of ALA and m/z 210 for the methylenepyrrolenine fragment ion of PBG. The protonated molecular ion of PBG, m/z 227, was found to be too facile to monitor, easily losing ammonia in the electrospray source and better sensitivity was achieved by monitoring the resulting fragment ion. The detection limits were circa 100 attomoles of ALA and 10 attomoles of PBG at a signal-to-noise ratio (S/N) better than 10, providing sufficient sensitivity for clinical use and offering advantages over existing techniques.     

Simultaneous determination of triptolide, tripdiolide and tripterine in human urine by high-performance liquid chromatography coupled with ion trap atmospheric-pressure chemical ionization mass spectrometry

An accurate and selective method for the simultaneous determination of triptolide, tripdiolide and tripterine in human urine using hydrocortisone as an internal standard (IS) by high-performance liquid chromatography coupled with atmospheric-pressure chemical ionization mass spectrometry in negative ion mode has been developed. After triptolide, tripdiolide and tripterine in human urine were extracted with ethyl acetate and cleaned by solid-phase extraction with C(18) cartridges, a satisfactory separation was achieved on an XDB C(18) short column (30 x 2.1 mm i.d., 3 microm) using the mobile phase of acetic acid-ammonium acetate (5 mmol/L, pH = 4.5)-acetonitrile-methanol in gradient elution. Detection was operated by APCI in selected ion monitoring mode. The target ions m/z 359, m/z 375, m/z 449 and m/z 419 were selected for the quantification of triptolide, tripdiolide, tripterine and IS, respectively. The linear range was 1.0-100.0 ng mL(-1), and the limits of quantification in human urine were found to be 0.1-0.5 ng mL(-1) for the three compounds. The precisions (CV%) and accuracies were 6.6-12.9 and 85.1-97.0%, respectively. The developed method could be applied to the determination of triptolide, tripdiolide and tripterine in human urine for diagnosis of the intoxication and for forensic purposes.