动物尿液中15种甾类同化激素的液相色谱-串联质谱同时测定

采用液相色谱-电喷雾串联质谱仪（LC-ESIMS/MS）,在多反应监测（MRM）模式下建立了动物尿液中15种甾类同化激素（睾酮、孕酮、诺龙、甲基睾酮、丙酸睾酮、丙酸诺龙、苯丙酸诺龙、大力补、勃地龙、群勃龙、康力龙、醋酸群勃龙、甲炔诺酮、甲羟孕酮、醋酸甲羟孕酮）的快速确证测定方法。试样经酶解处理后,过C18固相萃取柱净化,氮吹至干,残余物用0.50 mL乙腈-水（体积比1∶1）溶解后测定。采用正离子扫描方式进行仪器方法学研究,确定监测离子对,进行MRM模式定性定量分析。该方法的检出限（LOD）为0.2～0.5μg/L,定量下限（LOQ）为0.5～1.0μg/L;在2.0～200.0μg/L范围内线性关系良好,相关系数均大于0.998。在1.0、5.0μg/L的添加水平上,上述15种激素的平均回收率为59%～118%,相对标准偏差为1.0%～11.2%。该法操作简单,灵敏度高,可用于动物尿液中15种甾类同化激素的测定。     

超高效液相色谱-串联质谱法测定动物肌肉组织和鸡蛋中残留的11种甾体激素类药物

建立了采用超高效液相色谱-串联质谱(UPLC-MS/MS)同时测定猪、牛、羊和鸡肌肉组织及鸡蛋中睾酮、甲基睾酮、黄体酮、群勃龙、勃地龙、诺龙、美雄酮、司坦唑醇、丙酸诺龙、丙酸睾酮及苯丙酸诺龙等11种甾体激素多残留的分析方法。试样在碱性条件下用叔丁基甲醚提取,冷冻离心脱脂净化,以乙腈和甲酸水溶液为流动相,梯度洗脱,反相液相色谱分离。采用电喷雾离子化、多反应监测方式(MRM),对11种甾体激素同时进行定性定量测定。动物肌肉和鲜蛋中睾酮、甲基睾酮、勃地龙、美雄酮及司坦唑醇的检出限为0.3 μg/kg,群勃龙、诺龙、黄体酮、丙酸诺龙、丙酸睾酮及苯丙酸诺龙的检出限为0.4 μg/kg。在动物组织及鸡蛋中添加1,2及10 μg/kg 水平的药物回收试验中,睾酮、甲基睾酮、勃地龙、美雄酮及司坦唑醇的回收率均在62.3%～105%之间,相对标准偏差为0.5%～15%;群勃龙、诺龙、黄体酮、丙酸诺龙、丙酸睾酮及苯丙酸诺龙的回收率大于50.0%,相对标准偏差小于16%。11种甾体激素在1～100 μg/L范围内,线性关系良好,相关系数都大于0.99。该方法的样品前处理简单、快速,测定灵敏、准确,选择性好,可满足动物源食品中甾体激素类药物多残留的同时测定。     

超高效液相色谱-三重四极杆复合线性离子阱质谱法测定动物组织中的甾类同化激素

采用超高效液相色谱-三重四极杆复合线性离子阱质谱仪(UPLCQTRAP),建立了动物组织中甲基睾酮、泼尼松龙、丙酸睾酮、群勃龙、睾酮、康力龙、美雄酮、诺龙和孕酮的测定方法。动物组织绞碎后添加Na2CO3均质,与硅藻土充分混合后填入空柱内,用20 m L叔丁基甲醚进行2次萃取,收集洗脱液,经旋转蒸发至干,用甲醇水溶液(1∶1,V/V)定容后测定。使用多反应监测(MRM)模式,确定检测离子对、进行数据采集。方法在1.0~100μg/L范围内线性关系良好,检出限(LOD)为0.04~0.19μg/kg,定量限(LOQ)为0.10~0.64μg/kg。在2~50μg/kg添加水平上,9种激素的平均回收率为73.3%~116.1%,相对标准偏差(RSDs)为3.4%~19%。方法适用于动物组织中甲基睾酮、泼尼松龙、丙酸睾酮、群勃龙、睾酮、康力龙、美雄酮、诺龙和孕酮等甾类同化激素的测定。     

污水中18种类固醇激素化合物的痕量分析

采用HLB固相萃取柱和超高效液相色谱-串联质谱法(UPLC - MS/MS),在多反应监测(MRM)模式下建立了污水处理厂进出水样中18种类固醇激素(群勃龙、诺龙、雄烯二酮、睾酮、炔诺酮、甲基睾酮、孕酮、康力龙、羟孕酮、泼尼松、氢化泼尼松、六甲强龙、醋酸甲地孕酮、安宫黄体酮、倍他米松、地塞米松、醋酸泼尼松龙和醋酸氢化可...     

高效液相色谱串联质谱法同时测定水产品中24种性激素

建立了同时测定24种性激素的高效液相色谱串联质谱法,包括:睾酮、甲基睾酮、诺龙、苯丙酸诺龙、群勃龙、康力龙、勃地酮、雄烯二酮、美雄酮、炔诺酮、乙酸甲孕酮、乙酸甲羟孕酮、乙酸氯地孕酮、17α羟基孕酮、21α羟基孕酮、甲羟孕酮、左炔诺孕酮、雌酮、雌二醇、雌三醇、炔雌醇、己烷雌酚、己烯雌酚、双烯雌酚。乙酸乙酯提取2次,硅胶柱净化。采用甲醇、水作为流动相,经过CAPCELLPAK C18色谱柱分离后,采用APCI离子源,外标法定量。方法定量限为0.5～2μg/kg,加标回收率为80%～102%,相对标准偏差为6%～10%。方法实现了3类性激素的同时定量及确证分析。     

多重机制杂质吸附萃取净化-快速液相色谱-串联质谱法测定鱼组织中11种同化激素

建立了准确、灵敏的鱼组织中11种同化激素(勃地酮、雄烯二酮、诺龙、美雄酮、甲睾酮、睾酮、醋酸睾酮、群勃龙、丙酸睾酮、康力龙、氟甲睾酮)的多重机制杂质吸附萃取净化-快速液相色谱-串联质谱的分析方法。鱼组织均质样品经甲醇提取后,在上清液中加入一定量的C18固体吸附剂、中性氧化铝吸附剂和氨基功能化纳米吸附剂实现快速净化。采用Shim-Pack XR-ODSII色谱柱(100 mm×2.0 mm, 2.2 μm)分离,以乙腈(含0.1%甲酸)和水(含0.1%甲酸)为流动相进行梯度洗脱,电喷雾正离子多反应监测(MRM)模式下检测,外标法定量。结果表明,11种目标化合物在线性范围内具有良好的线性关系,相关系数大于0.999,其在鱼组织中的检出限(S/N＞3)为0.03～0.4 μg/kg,定量限(S/N＞10)为0.1～1.5 μg/kg,平均回收率为80.9%～98.1%,相对标准偏差(RSD)为5.2%～11.5%。该方法简便、快速、准确,可用于鱼组织中同化激素的定性、定量监测。     

高效液相色谱-串联质谱法同时检测鸡肉和鸡蛋中合成类固醇类激素和糖皮质激素

建立了鸡肉和鸡蛋中合成类固醇类激素(睾酮、甲基睾酮、群勃龙、勃地龙、诺龙、美雄酮、司坦唑醇、丙酸诺龙、丙酸睾酮及苯丙酸诺龙)和糖皮质类激素(泼尼松、泼尼松龙、地塞米松、氟氢可的松、甲基泼尼松、倍氯米松及氢化可的松)多残留的液相色谱-串联质谱(LC-MS/MS)检测方法.样品经乙腈超声提取,正己烷脱脂净化,以甲醇-甲酸水溶液为流动相,经C18柱分离后进行LC-MS/MS选择反应监测模式下的定性及定量分析.合成类固醇类激素采用正离子模式检测,糖皮质激素则采用负离子模式检测,正、负离子化模式一次进样同时检测.类固醇类和糖皮质类激素的定量检出限为0.5 μg/kg.在0.5、 1.0和5.0 μg/kg 3种浓度添加水平,上述激素的平均回收率为73.4%～108.9%;相对标准偏差为3.4%～13.4%.可实现样本灵敏、准确地定性定量分析.     

高效液相色谱-串联质谱法检测配合饲料中11种蛋白同化激素含量

建立了快速分析配合饲料中睾酮、甲基睾酮、勃地龙、美雄酮、雄烯二酮、脱氢异雄酮、诺龙、丙酸诺龙、司坦唑醇、美伦孕酮、黄体酮11种蛋白同化激素的高效液相色谱-串联质谱(HPLC-MS/MS)法。样品采用乙腈提取,经PSA粉净化后上机测定。采用Phenomenex C₁₈(100 mm×2.1 mm,2.6μm)色谱柱,以0.01%甲酸溶液-乙腈作为流动相进行梯度洗脱,电喷雾离子源正离子模式检测,同位素内标法定量。结果表明,11种蛋白同化激素的线性范围为1～100 ng/mL,相关系数均为0.999,检出限为20μg/kg,定量下限为50μg/kg。50、250、500μg/kg加标水平下,鸡配合饲料中各蛋白同化激素的回收率为94.5%～111%,日内相对标准偏差(RSD)和日间RSD均不大于13%;猪配合饲料中各蛋白同化激素的回收率为90.1%～109%,日内RSD不大于9.0%,日间RSD不大于8.8%。实际样品中检出睾酮和勃地龙,含量分别为9.09～14.68 mg/kg和1.22～1.84 mg/kg。该方法可为饲料中蛋白同化激素的滥用监管提供技术支撑。     

超高效液相色谱-串联质谱法同时测定鱼制品中残留的7种性激素

以电喷雾离子源(ESI)为电离源,在正离子采集模式下建立了鱼制品中7种性激素（甲基炔诺酮、甲基睾酮、丙酸睾酮、醋酸甲羟孕酮、醋酸甲地孕酮、醋酸氯地孕酮、诺龙）的超高效液相色谱-质谱/质谱(UPLC-MS/MS)检测方法。样品被酶解后用甲醇提取,提取液经氯化锌(ZnCl2)去脂、LC-C18和LC-NH2固相萃取柱净化、Waters ACQUITYTM UPLC BEH-C18色谱柱(100 mm×2.1 mm, 1.7 μm)分离,在多反应监测模式下进行UPLC-MS/MS分析。7种性激素的方法检出限(S/N=3)为0.08～0.17 μg/kg,定量限(S/N=10)为0.24～0.58 μg/kg。考察了内标法和基质匹配外标法对7种性激素进行定量的回收率与精密度: 添加水平为1, 4 μg/kg时,以内标法定量,7种性激素的平均回收率为76%～118%,相对标准偏差（RSD）为5.0%～11.3%;以基质匹配外标法定量,7种性激素的平均回收率为66%～94%,RSD为4.5%～10.7%。该结果表明两种方法均能够满足鱼制品中7种性激素的多残留检测要求。应用建立的方法对市售脱脂大黄鱼及烤鱼片进行检测,未发现7种目标违禁性激素。     

动物肌肉组织中甾类同化激素多组分残留的液相色谱-质谱检测方法

建立了不同动物肌肉中甾类同化激素(表睾酮、丙酸睾酮、19-去甲基睾酮、甲基睾酮、孕酮、甲羟孕酮、雌二醇、雌三醇、炔雌醇、雌酮)多残留量的LC/MS/MS确证方法。样品加醋酸缓冲溶液均质,加酶溶液酶解后,再加甲醇超声提取,用叔丁基甲醚液-液萃取至少2次,之后经反相固相萃取柱净化,以乙腈-水为流动相,经C18柱分离后进行LC/MS/MS多反应监测模式下的定性及定量分析。其中雄激素,孕激素采用正离子扫描,雌激素则采用负离子扫描。17beta-NT、MTS、ETS、MED、PG、PTS、EST、17beta-ES、EES和ESN的定量检出限为0.5~1.0μg/kg。在1.0μg/kg的定量检出限添加水平,上述10种激素的平均回收率为55%~77%;相对标准偏差为7.1%~35%。可实现样本灵敏、准确的定性定量分析。     

Determination of residual anabolic steroid in meat by gas chromatography-ion trap-mass spectrometer

The use of natural and synthetic anabolic steroids in animal fattening has been prohibited in Taiwan and many countries because of their potential toxic effect on public health. This paper describes a newly developed gas chromatography-ion trap-mass spectrometry (GC-IT-MS) method for the quantitative determination of various residual anabolic steroids in meat. Anabolic steroid was derivatized with N-methyl-N-trimethylsilytrifluoroacetamide prior to GC-IT-MS analysis. MS² was employed for quantitative measurement. In addition, 2d-estradiol was used as an internal standard. Quantitative determination was based on the ratio of peak area of steroid derivative to peak area of internal standard derivative. Good linearity of each compound, 0.03-1.0 μg/ml, was determined. Solvent extraction was used to extract residual anabolic compounds in meat samples and a solid phase extraction (SPE) procedure was utilized for sample cleanup and pre-concentration. The limits of detection of anabolic compounds approximately ranged from 0.1 to 0.4 μg/kg. The detection limit was comparable with or better than reported methods and was below the minimum required performance limits (MRPLs) established by the European Community (EC). The application of this newly developed method was demonstrated by analyzing various beef, pork, chicken and several animal internal organ samples from local markets.     

体育领域热点——克仑特罗检测方法研究近况及发展方向

克仑特罗在临床上主要用于治疗哮喘,但由于其同时又具有蛋白同化作用,因此也被非法滥用于畜牧业和体育领域.畜牧业中的滥用现象会导致该药物在动物肌肉或其他可食性组织中残留,误食此类肉食品会引发运动员兴奋剂尿检阳性事件.2014年以来,克仑特罗每年的阳性检出例数一直位居当年所有阳性物质之首,其中绝大多数阳性均与误食克仑特罗污染...     

类固醇兴奋剂分析方法的研究进展

蛋白同化雄性类固醇是一类滥用最为普遍的兴奋剂物质,对其进行有效的控制和检测关系到运动员的身心健康和体育比赛的公平公正。对类固醇兴奋剂分析方法的改进和发展是目前兴奋剂检测的重要任务。本文主要是对自2002年以来类固醇兴奋剂样品的预处理和检测手段的研究进展做一概述,包括气相色谱-质谱法、液相色谱-质谱法、免疫法、电化学方法以及质谱法等。     

高效液相色谱法同时测定牛肉组织中6种类固醇类激素类药物

建立了高效液相色谱法同时测定牛肉组织中勃地龙、诺龙、美雄酮、甲基睾酮、丙酸睾酮和丙酸诺龙的分析方法.试样经乙腈提取,冷冻离心脱脂净化,以甲醇-水为流动相,梯度洗脱,流速为1.0 mL/min.该方法的检出限(LOD)为0.0051～0.0086 mg/kg,定量限(LOQ)为0.0220～0.0287 mg/kg,在0...     

Quantification of testosterone undecanoate in human hair by liquid chromatography–tandem mass spectrometry

Testosterone undecanoate (T‐C11) can be used by athletes in order to improve performance. After oral intake, T‐C11 is rapidly metabolized, hampering discrimination between exogenous and endogenous testosterone. A possible alternative is to detect the intact ester in hair. A method based on liquid chromatography–tandem mass spectrometry was developed for the determination of T‐C11 in hair. The sample procedure consisted of digestion of 200 mg of pulverized hair with tris(2‐carboxyethyl)phosphine hydrochloride and liquid–liquid extraction with n‐pentane. Several parameters such as the mobile phase, the ionization source and the washing step were optimized. The method was validated at different spiked levels obtaining satisfactory values for accuracy (between 92 and 102%) with relative standard deviations lower than 7% and a limit of detection of 0.2 ng/g. The applicability of the method was checked by the analysis of three samples from patients using T‐C11. A peak for the analyte was detected in all samples with concentrations between 0.4 and 8.4 ng/g. Copyright © 2009 John Wiley & Sons, Ltd.     

Ionization of anabolic steroids by adduct formation in liquid chromatography electrospray mass spectrometry

The ionization of 46 anabolic steroids has been studied. The absence of basic or acidic moieties in most of these analytes makes their direct ionization as [M + H]+ by atmospheric pressure interfaces difficult. The formation of adducts with different components of the mobile phase has been found to be an efficient way to ionize anabolic steroids by electrospray. Different mobile phases using methanol (MeOH) or acetonitrile as organic solvent and HCOOH, Na+ or NH4+ as additives have been tested to favor the adduct formation. A direct correlation between the chemical structure of the anabolic steroid and the possibility to ionize it in a particular chromatographic condition has been found. According to their ionization, anabolic steroids can be divided into seven different groups depending on both the nature and the relative position of their functional groups. The formation of different adducts such as [M + Na + MeOH]+ or [M + H + CH3 CN - H2O]+ is required in order to ionize some of these groups and the optimal mobile phase composition for each group of anabolic steroids is proposed. Despite the ionization limitations due to their chemical structure, most of tested anabolic steroids could be ionized using the adduct formation approach.     

Relationships between structure,ionization profile and sensitivity of exogenous anabolic steroids under electrospray ionization and analysis in human urine using liquid chromatography–tandem mass spectrometry

The relationships between the ionization profile, sensitivity, and structures of 64 exogenous anabolic steroids (groups I–IV) was investigated under electrospray ionization (ESI) conditions. The target analytes were ionized as [M + H]⁺ or [M + H–nH₂O]⁺ in the positive mode, and these ions were used as precursor ions for selected reaction monitoring analysis. The collision energy and Q3 ions were optimized based on the sensitivity and selectivity. The limits of detection (LODs) were 0.05–20 ng/mL for the 64 steroids. The LODs for 38 compounds, 14 compounds and 12 compounds were in the range of 0.05–1, 2–5 and 10–20 ng/mL, respectively. Steroids including the conjugated keto‐functional group at C3 showed good proton affinity and stability, and generated the [M + H]⁺ ion as the most abundant precursor ion. In addition, the LODs of steroids using the [M + H]⁺ ion as the precursor ion were mostly distributed at low concentrations. In contrast, steroids containing conjugated/unconjugated hydroxyl functional groups at C3 generated [M + H ? H₂O]⁺ or [M + H ? 2H₂O]⁺ ions, and these steroids showed relatively high LODs owing to poor stability and multiple ion formation. An LC‐MS/MS method based on the present ionization profile was developed and validated for the determination of 78 steroids (groups I–V) in human urine. Copyright © 2015 John Wiley & Sons, Ltd.     

Effects of propyphenazone and other non-steroidal anti-inflammatory agents on the synthetic and endogenous androgenic anabolic steroids urinary excretion and/or instrumental detection

This paper describes the effects of oral administration of non-steroidal anti-inflammatory drugs on the endogenous and synthetic anabolic androgenic steroids urinary excretion as assessed by gas-chromatography mass-spectrometry. Experiments were carried out on 5 male subjects, with pathologies and/or diseases, treated with non-steroidal anti-inflammatory drugs. To set up the individual baseline variability of testosterone and its main metabolites, urine samples were collected for 3 days, every 2 h prior to the administration of the drug(s); whereas the study of the effects of a single dose of each drug, here considered, on the endogenous androgen steroid urinary concentrations, was assessed by collecting urine samples for 2 days, every 2 h. Data obtained after drugs administration were then evaluated taking into account the individual baseline variability. The results showed that, only in the case of propyphenazone administration, the relative urinary concentrations of some testosterone metabolites were significantly altered. More specifically, the urinary levels of dehydroepiandrosterone, 11keto-etiocholanolone, 11β-hydroxyandrosterone, 11β-hydroxyetiocholanolone, androsterone, etiocholanolone and some metabolite ratios decrease significantly, generally between 2 and 10 h after administration of the drug, whereas no effects were observed on urinary calculated concentrations of testosterone, epitestosterone, 5α-androstane-3α,17β-diol, 5β-androstane-3α,17β-diol and testosterone/epitestosterone ratio. The observed effects do not depend on alterations on pharmacokinetics (excretion/metabolism), but on steroid sample preparation steps (hydrolysis and derivatization) inhibition. More specifically the significant decrease of dehydroepiandrosterone and testosterone metabolites urinary levels was due to a reduced yield of the steroid derivatization step for the presence in urine of the main metabolites of propyphenazone, namely hydroxyl-propyphenazone metabolites.