生物检材中苯丙胺类兴奋剂和氯胺酮的LC-MS/MS分析

目的建立生物检材中苯丙胺类兴奋剂和氯胺酮的液相色谱-串联质谱(LC-MS/MS)分析方法。方法生物检材包括血液、尿液和毛发,采用稀释法和液液提取的前处理方法,应用两个不同的液相柱,优化LC-MS/MS分析方法,并考察了血液和尿液基质的离子抑制作用。结果同时分析苯丙胺和MDA,液相1在3m in内完成,液相2可用于确认分析或复杂基质分离。尿液稀释法检材用量少,前处理简便快速。毛发中苯丙胺类兴奋剂和氯胺酮的最低检测限(LOD)为0.005~0.05ng/mg。对送检案例检材产妇头发和胎毛进行苯丙胺类兴奋剂和氯胺酮的分析。结论本方法可用于生物检材中苯丙胺类兴奋剂和氯胺酮的同时分析,血、尿等生物检材的离子抑制作用是影响本方法灵敏度的主要原因。     

Prevalence of gamma-hydroxybutyrate (GHB) in serum samples of amphetamine, metamphetamine and ecstasy impaired drivers

Two hundred and forty-seven serum samples which have been collected by police during roadside testing and have been found positive for amphetamine, methamphetamine, 3,4-methylenedioxyamphetamine (MDA), 3,4-methylenedioxymethamphetamine (MDMA) and/or 3,4-methylenedioxyethamphetamine (MDE) were analyzed for gamma-hydroxybutyrate (GHB). Serum samples were spiked with deuterated GHB as internal standard and acetonitrile was added to achieve dilution and protein precipitation. Samples were analyzed with a LC-MS/MS system operated in the multiple reaction monitoring mode (MRM) using a TurboIonSpray source. Chromatographic separation was achieved using a Synergi Polar RP column applying a gradient elution with a runtime of 15 min. To differentiate between endogenous and exogenously administered GHB a cut-off concentration of 10 microg/mL was applied. Five samples exceeded this concentration and were found positive for GHB. These samples were only found positive for amphetamine but no other amphetamine derivatives were detected, while in three samples THC and in one sample cocaine, benzoylecgonine and ethanol were found.     

Simultaneous hair testing for opiates, cocaine, and metabolites by GC-MS: a survey of applicants for driving licenses with a history of drug use

A sensitive GC-MS method for the simultaneous determination of opiates, cocaine, and metabolites in hair at a cut-off level of 0.1 ng/mg was adopted to assess past exposure to these drugs in applicants for driving licenses with a history of drug use. The sampling protocol consisted of collection of one hair (sample A, 5-cm length) and one urine sample. When hair and urine (EMIT Syva, cut-off levels: 0.3 mg/l for opiates, 0.15 mg/l for cocaine, GC-MS confirmation of positives) were both positive or negative the protocol was concluded. In the other cases, the assessment of 'current exposure' to drugs was carried out, in order to avoid seriated random urinalysis, by collecting a second hair sample (sample B) 6 weeks later and analysing the proximal 1-cm segment. Out of the 214 'A' hair samples analyzed, 14 (6.5%) tested positive for morphine and/or 6-acetylmorphine (6AM), and 26 (12%) for cocaine and/or benzoylecgonine (BE), whereas none of the samples tested positive for both drugs. Levels between 0.1 and 1 ng/mg of the single analytes were found in eight out of the 14 morphine-6AM positives (57%) and in 18 out of the 26 cocaine-BE positives (69%). The time course of positive cases showed a progressive decrease of morphine-6AM positives and a corresponding increase of cocaine-BE positives within the study period September 1995-February 1999. No cases with positive urine and negative hair were observed. Among the 40 positive cases, seven (four and three for opiates and cocaine, respectively) were found to be 'currently exposed to drug', four by urinalysis (three and one) and three by analysis of the hair sample B (1 and 2).     

Doping control analysis of selected peptide hormones using LC-MS(/MS)

With the constantly increasing sensitivity and robustness of liquid chromatography-mass spectrometry-based instruments combined with enhanced reproducibility as well as mass accuracy and resolution, LC-MS(/MS) has become an integral part of sports drug testing programs particularly concerning the detection of peptide hormones. Although several of the relevant peptidic drugs such as insulins (Humalog LisPro, Novolog Aspart, etc.), growth hormone releasing peptides (GHRPs, e.g., GHRP-2, GHRP-6, Hexarelin, etc.), and insulin-like growth factors (e.g., IGF-1, IGF-2, long-R(3)-IGF-1) are currently analyzed using dedicated top-down analytical procedures, i.e. employing specifically tailored sample preparation procedures followed by targeted LC-MS(/MS) measurements focusing on intact analytes, first approaches towards multi-analyte methods have been established. These allow the determination of the prohibited substances in blood and urine doping control specimens following therapeutic applications. In addition, the use of new complementary devices such as ion mobility analyzers, e.g., in hybrid mass spectrometers yielded promising data for the differentiation of isobaric insulins, which outlines the potential to further accelerate and multiplex doping control analytical assays to meet the continuously increasing demands of rapid and unambiguous test methods. Moreover, the potential of LC-MS/MS to target recombinant peptide hormones such as human growth hormone using bottom-up approaches has been demonstrated by targeting proteotypic peptides that unambiguously differentiate the recombinant molecule from the naturally occurring and endogenously produced analog.     

Rapid analysis of 3,4-methylenedioxymethamphetamine: a comparison of nonaqueous capillary electrophoresis/fluorescence detection with GC/MS

Because of the increasing use of 3,4-methylenedioxymethamphetamine (3,4-MDMA), a rapid and sensitive analytical technique is required for its detection and determination. Using nonaqueous capillary electrophoresis/fluorescence spectroscopy (NACE/FS) detection, it is possible to determine this drug at the level 0.5 ppm without any pre-treatment in less than 5 min. After liquid-liquid extraction, the sample can be condensed and a detection limit of 3,4-MDMA in urine of 50 ppb (S/N = 3) can be achieved. The precision of the method was evaluated by measuring the repeatability and intermediate precision of migration time and the corrected peak height by comparison with a 3,4-MDMA-D5 internal standard. With the conventional GC/MS method, it is necessary to derivatize the 3,4-MDMA before injection and the GC migration time also is in excess of 20 min. Therefore, NACE/FS represents a good complementary method to GC/MS for use in forensic analysis.     

Simultaneous determination of eight catechins and four theaflavins in bottled tea by liquid chromatography-tandem mass spectrometry for forensic analysis

Tea, and particularly bottled tea, is widely consumed worldwide and is often encountered at crime scenes in poisoning cases or used in place of urine in drug abuse monitoring. Tea is a rich source of polyphenols, such as catechins and theaflavins, and these compounds are useful for identification of trace quantities of tea samples. However, information on the contents of catechins and theaflavins in bottled tea is limited. In this study, a method was developed for simultaneous analysis of eight catechins and four theaflavins in tea using liquid chromatography-tandem mass spectrometry (LC-MS/MS). The concentrations of these polyphenols were determined in bottled black, oolong, and green teas after a simple pretreatment process by the standard addition method. The developed LC-MS/MS method was rapid and all tested polyphenol compounds were separated within ~14 min. All tea types contained all the catechins, at varying concentrations, but not all the theaflavins were present in all the tea types. This indicates that the theaflavin composition reflects the degree of the fermentation and could be used for discrimination among different types of tea. All the green tea samples contained all eight catechins; however, the concentrations of these compounds varied among the tea samples. Principal component analysis and hierarchical cluster analysis were useful for discrimination of samples. It has been unclear whether the variations of chemical components are useful for forensic discrimination. Our results demonstrate that, in addition to identification of tea varieties, catechins and theaflavins can be used for the discrimination of bottled tea samples.     

Differentiation of side chain isomers of ring-substituted amphetamines using gas chromatography/infrared/mass spectrometry (GC/IR/MS).

Common analytical methods used for identifying samples obtained from clandestine laboratories were evaluated for their ability to differentiate between possible amphetamine isomers and homologs. A series of ring-substituted (4-methyl, 4-methoxy, and 3,4-methylenedioxy) amphetamine and N-methylphenethylamine isomers was analyzed using color tests, thin-layer chromatography, gas chromatography/mass spectrometry (GC/MS) and GC/infrared (GC/IR). The N-acetyl derivatives of the isomers were analyzed using GC/IR/MS. GC/IR/MS readily differentiated the 4-methylphenylalkylamine isomers. MS and IR spectra were also obtained for each pair of the 4-methoxyphenylalkylamine isomers and the 3,4-methylenedioxyphenylalkylamine isomers, but differentiation via GC/IR/MS was difficult. The N-acetyl derivatives of each pair of isomers could be readily differentiated using GC/IR/MS. Good library researchable spectra for N-acetylamphetamine could be obtained for IR identification with 10 ng (on-column) and MS identification with 2 ng. The spectrometrically independent IR and MS data obtained for the N-acetyl derivatives indicated that the combination of GC/IR/MS can add a significant level of confidence in the analysis of ring-substituted arylalkylamines.     

LC-MS／MS测定尿液中可卡因及其代谢物苯甲酰爱康宁

目的建立尿液中可卡因(cocaine,COC)及其代谢物苯甲酰爱康宁(benzoylecgonine,BZE)的液相色谱-串联质谱分析方法。方法尿液经固相萃取后,用AllurePFP丙基柱分离,以V(甲醇):V(20mmol/L乙酸胺和0.1%甲酸的缓冲溶液)=80∶20为流动相,采用二级质谱多反应监测模式检测COC和BZE。按10mg/kg的剂量对豚鼠腹腔注射可卡因,给药后收集7d尿液。结果尿液中COC和BZE在2.0～100ng/mL质量浓度范围内线性关系良好(r=0.9995),最低检测限(LOD)为0.5ng/mL;回收率大于90%;日内和日间精密度均小于6%;豚鼠尿液中主要检测目标物是BZE,且BZE检测时限也较COC长。结论所建方法灵敏度高,选择性好,适用于尿液中可卡因和苯甲酰爱康宁的检测。     

Prolonged excretion of 7-aminoclonazepam in urine after repeated ingestion of clonazepam: A case report

Urinary analyses of the metabolite 7-aminoclonazepam (7-AC) can be helpful in monitoring drug abuse and in the context of suspected drug-facilitated sexual assaults (DFSA). Only two studies have reported detection times of 7-AC in urine after a single dose of clonazepam, and no previous studies have reported detection times after repeated ingestions of clonazepam. This report describes along detection time of 7-AC in urine in the case of a 28-year-old woman with a two year history of daily drug abuse of heroin and clonazepam, who was admitted to a detoxification unit. Urinary samples were delivered every morning for 9 days. Screening analysis in urine was performed by immunoassay, and confirmation analysis by LC-MS/MS. 7-AC was detected for 9 days, and the concentration at day 9 was still high (97ng/ml), compared to previously reported data. These results indicate that after repeated ingestions of clonazepam, 7-AC can possibly be detected for about 2-3 weeks after cessation, applying cut-off levels commonly used in drug testing programs and DFSA cases.     

基质辅助激光解吸飞行时间质谱分析生物样品中甲基苯丙胺

目的建立尿样和头发中甲基苯丙胺的基质辅助激光解吸飞行时间质谱（matrix-assisted laser desorption/ionization time of flight mass spectrometry,MALDI-TOF-MS）分析方法。方法尿样采用液液提取,头发经0.1mol/L盐酸水解后采用液液提取,以碳纳米管为基质应用MALDI-TOF-MS法检测。结果尿样中甲基苯丙胺的最低检测限（LOD）为0.5μg/mL,线线范围为线性范围为0.5～100μg/mL（R2=0.9970）;毛发中甲基苯丙胺的最低检测限（LOD）为0.4ng/mg,线性范围为0.4～60ng/mg（R2=0.9976）,对送检案例中尿样和头发检材进行检测,效果良好。结论本方法适用于尿样和头发中甲基苯丙胺的分析,与传统气相色谱质谱联用和液相色谱-质谱联用相比,分析速度更快,适合大批量样品同时分析。     

Identification of lorazepam and sildenafil as examples for the application of LC/ionspray-MS and MS-MS with mass spectra library searching in forensic toxicology

A mass spectra (MS) library using in-source collision induced dissociation (ESI-CID) as well as a tandem-mass spectra (MS-MS) library with product ion spectra of drugs has recently been developed with a triple-quadrupole ionspray mass spectrometer [1,2]. For the ESI-CID MS library, single-quadrupole mode and for the MS-MS library triple-quadrupole mode have been used. These mass spectra libraries were applied successfully for the general-unknown screening for drugs and metabolites in serum and urine with liquid-chromatography-mass spectrometry (LC-MS) using a PE/SCIEX API 365 with a turboionspray source. As examples, the identification of lorazepam and lorazepam-glucuronide in a serum extract and the identification of sildenafil and alkyloxidated sildenafil in urine are presented here.     

Identification of anhydroecgonine ethyl ester in the urine of a drug overdose victim

Toxicological evaluation of postmortem urine collected from a 41-year-old deceased white male detected anhydroecgonine ethyl ester (ethylecgonidine, AEEE), a transesterification product of smoked cocaine co-abused with ethanol. A solid phase extraction (SPE) method was used to extract cocaine, AEEE, and related metabolites from urine. SPE on a 1 mL urine sample from the decedent followed by GC-MS detected AEEE. Other metabolites identified by GC-MS included cocaine, cocaethylene, and anhydroecgonine methyl ester (AEME). To determine whether some or all of the AEEE was artifactually produced in the heated GC injector port, an alternative LC-MS method was developed. LC/MS following SPE found at least 50 ng/mL of AEEE in the extract. The mass fragmentation (MS/MS and MS3) of AEEE detected in the urine was compared to spectra of authentic, synthesized compound. AEEE is a potential additional forensic marker for the co-abuse of smoked cocaine and ethanol.     

吗啡及其代谢物在藏毒致死者体内分布初探

目的采用固相萃取、液相色谱一串联质谱（LC-MS／MS）检验方法,考察吗啡和葡萄糖醛酸吗啡（M3G）在一例体内藏毒致急性死亡者体内分布情况。方法提取死者心血、尿、胃内容物、肝、肾、脑等15种检材,经Waters HLB小柱固相萃取后,C18色谱柱分离,采用电喷雾电离（ESI）、多反应监测模式（MRM）检测目标化合物。结果所建方法在0．0l～101μg／mL浓度范围内线性关系良好,提取回收率大于75％。结果显示总吗啡含量（游离态＋结合态）在胃内容物中最高,其次是尿、‘肾,在心血、胃组织、肺和腺体中居中,脑组织和心脏含量最低。结论本例检验结果验证了胃内容物、尿液和肾脏等是该类中毒案件的理想检材,其分布规律也可作为体内毒品分析实验依据。     

Simultaneous analysis of six amphetamines and analogues in hair, blood and urine by LC-ESI-MS/MS. Application to the determination of MDMA after low ecstasy intake

A rapid and sensitive method using LC-MS/MS triple stage quadrupole for the determination of traces of amphetamine (AP), methamphetamine (MA), 3,4-methylenedioxyamphetamine (MDA), 3,4-methylenedioxymethamphetamine (MDMA, "ecstasy"), 3,4-methylenedioxyethamphetamine (MDEA), and N-methyl-1-(3,4-methylenedioxyphenyl)-2-butanamine (MBDB) in hair, blood and urine has been developed and validated. Chromatography was carried out on an Uptisphere ODB C(18) 5 microm, 2.1 mm x 150 mm column (Interchim, France) with a gradient of acetonitrile and formate 2 mM pH 3.0 buffer. Urine and blood were extracted with Toxitube A (Varian, France). Segmented scalp hair was treated by incubation 15 min at 80 degrees C in NaOH 1M before liquid-liquid extraction with hexane/ethyl acetate (2/1, v/v). The limits of quantification (LOQ) in blood and urine were at 0.1 ng/mL for all analytes. In hair, LOQ was <5 pg/mg for MA, MDMA, MDEA and MBDB, at 14.7 pg/mg for AP and 15.7 pg/mg for MDA. Calibration curves were linear in the range 0.1-50 ng/mL in blood and urine; in the range 5-500 pg/mg for MA, MDMA, MDEA and MBDB, and 20-500 pg/mg for AP and MDA. Inter-day precisions were <13% for all analytes in all matrices. Accuracy was <20% in blood and urine at 1 and 50 ng/mL and <10% in hair at 20 and 250 pg/mg. This method was applied to the determination of MDMA in a forensic case of single administration of ecstasy to a 16-year-old female without her knowledge during a party. She suffered from hyperactivity, sweating and agitation. A first sample of urine was collected a few hours after (T+12h) and tested positive to amphetamines by immunoassay by a clinical laboratory. Blood and urine were sampled for forensic purposes at day 8 (D+8) and scalp hair at day 60 (D+60). No MDMA was detected in blood, but urine and hair were tested positive, respectively at 0.42 ng/mL and at 22 pg/mg in hair only in the segment corresponding to the period of the offence, while no MDA was detectable. This method allows the detection of MDMA up to 8 days in urine after single intake.     

The toxicological challenges in the European research project DRUID

Within the epidemiological studies of the integrated European research project DRUID (Driving Under the Influence of Drugs, alcohol and medicines), 13 laboratories from across Europe will analyse whole blood, oral fluid (OF) or urine from the general driving population and injured drivers. To ensure the comparability of toxicological results from the different studies, the collection of samples, analytical methods, target analytes and analytical cut-offs have been standardized for all laboratories involved.Target analytes were selected based on suspected impairing effects and prevalence. Twenty-three drugs are included in the ‘core list’ for which analysis is mandatory: ethanol, amphetamine, MDMA, MDA, MDEA, methamphetamine, cocaine, benzoylecgonine, THC, THC-COOH, 6-acetylmorphine, diazepam, flunitrazepam, alprazolam, clonazepam, oxazepam, nordiazepam, zolpidem, zopiclone, lorazepam, morphine, codeine and methadone. Additionally, 28 other drugs will be analysed in 1–12 countries.All whole blood samples are collected in glass Vacutainer-type tubes containing sodium fluoride and potassium oxalate. Based on a comparative study of 10 collection devices, it was decided to collect oral fluid using the Statsure™ device. Since only a small sample volume is available (5–10 mL blood and 1 mL oral fluid), all laboratories have to develop methods for simultaneous detection of the target analytes. All laboratories agreed to use either LC–MS–MS or GC–MS in SIM-mode. Proficiency testing for both blood and oral fluid are organized.Analytical cut-offs were established for the core list based on those used in ROSITA-2, SAMHSA cut-off values for oral fluid and recommendations from an expert meeting in Talloires.Because of practical and legal considerations, different sample types are used: whole blood, serum/plasma and oral fluid. Literature on correlation between analyte concentrations in these body fluids is limited, which makes several comparisons of study results difficult: (1) comparison of epidemiological (blood, oral fluid and urine) and experimental studies (serum and plasma) performed in DRUID and (2) comparisons within the epidemiological studies themselves (most countries: oral fluid in road-side survey, blood in hospital studies).A combination of literature findings, new findings from DRUID and semi-quantitative results will likely have to be used to solve these problems.     

Application of solvent microextraction to the analysis of amphetamines and phencyclidine in urine

A fast and simple method to detect some commonly abused illicit drugs, amphetamine, methamphetamine, 3,4-methylendioxy-amphetamine (MDA), 3,4-methylendioxy-methamphetamine (MDMA), 3,4-methylendioxy-N-ethylamphetamine (MDEA) and phencyclidine (PCP) in urine using solvent microextraction (SME) combined with gas chromatography (GC) analysis has been developed. The extraction is conducted by suspending a 2 microl drop of chloroform in a 2 ml urine sample. Following 8 min of extraction, the organic solvent is withdrawn into the syringe and injected into a GC with a pulsed discharge helium ionization detector (PDHID). The effects of different extraction solvents and times, pH and sample preparation were studied. The optimized method was capable of detecting drugs in urine at concentrations below Substance Abuse and Mental Health Services Administration (SAMHSA) established cut-off values for preliminary testing. Good linearity and reproducibility of extraction were obtained. The limits of detection were 0.5 microg/ml for amphetamine, 0.1 microg/ml for methamphetamine and MDA, 0.05 microg/ml for MDMA, 0.025 microg/ml for MDEA and 0.015 microg/ml for PCP. Relative standard deviation (R.S.D.) values ranged between 5 and 20% for the studied drugs.     

Plasma,oral fluid and sweat wipe ecstasy concentrations in controlled and real life conditions

In a double-blind placebo controlled study on psychomotor skills important for car driving (Study 1), a 75 mg dose of +/- 3,4-methylenedioxymethamphetamine (MDMA) was administered orally to 12 healthy volunteers who were known to be recreational MDMA-users. Toxicokinetic data were gathered by analysis of blood, urine, oral fluid and sweat wipes collected during the first 5h after administration. Resultant plasma concentrations varied from 21 to 295 ng/ml, with an average peak concentration of 178 ng/ml observed between 2 and 4h after administration. MDA concentrations never exceeded 20 ng/ml. Corresponding MDMA concentrations in oral fluid, as measured with a specific LC-MS/MS method (which required only 50 microl of oral fluid), generally exceeded those in plasma and peaked at an average concentration of 1215 ng/ml. A substantial intra- and inter-subject variability was observed with this matrix, and values ranged from 50 to 6982 ng/ml MDMA. Somewhat surprisingly, even 4-5h after ingestion, the MDMA levels in sweat only averaged 25 ng/wipe. In addition to this controlled study, data were collected from 19 MDMA-users who participated in a driving simulator study (Study 2), comparing sober non-drug conditions with MDMA-only and multiple drug use conditions. In this particular study, urine samples were used for general drug screening and oral fluid was collected as an alternative to blood sampling. Analysis of oral fluid samples by LC-MS/MS revealed an average MDMA/MDEA concentration of 1121 ng/ml in the MDMA-only condition, with large inter-subject variability. This was also the case in the multiple drug condition, where generally, significantly higher concentrations of MDMA, MDEA and/or amphetamine were detected in the oral fluid samples. Urine screening revealed the presence of combinations such as MDMA, MDEA, amph, cannabis, cocaine, LSD and psilocine in the multiple-drug condition.     

固相萃取／LC-MS／MS测定尿液中吗啡类药物

目的 建立尿液中吗啡类药物的固相萃取／LC—MS／MS方法。方法采用OASIS MCX3cc（60mg）固相萃取柱进行提取,应用LC—MS／MS方法进行检测,运用保留时间和MRM方式对尿液中吗啡类药物及其代谢物进行定性定量分析。结果磷酸盐缓冲液pH4．0时,海洛因、6-MAM、可待因、吗啡、M3G的固相萃取回收率分别达64．33％-70．21％,96．95％～117．57％,83．60％～123．63％,68．82％～91．03％,94．64％～107．33％;最低检测限（LOD）分别为5、10、5、5、2pg,线性范围0．005～10μg／mL;相关系数分别为0．9998、0．9958、0．9992、0．9994、0．9997。结论本文所建方法,适用于尿液中吗啡类药物的分析。     

LC-MS/MS同时分析尿液中15种安眠镇静药物及其代谢物

目的建立尿液中15种常见安眠镇静药物及代谢物的液相色谱-串联质谱分析方法。方法尿液经酶水解、固相萃取后,用C18液相柱分离,以含甲酸铵和甲酸的水、乙腈为流动相梯度洗脱,质谱采用电喷雾电离（ESI）-正负离子模式同时扫描,采用二级质谱多反应监测（MRM）模式检测目标化合物。结果以化合物的保留时间、两对母离子/子离子对定性,尿中常见安眠镇静药物的检测限为0.01～0.5ng/mL（ESI＋）和10ng/mL（ESI-）;相关系数r在0.994以上;日内及日间精密度均在18%以下;绝对回收率在64.80%～116.20%之间。结论方法快速、灵敏、简便、可靠,能同时分析尿液中的15种安眠镇静药物及其代谢物。     

液相色谱-串联质谱法分析生物检材中的河豚毒素

目的建立血液、尿液以及肝中河豚毒素(tetrodotoxin,TTX)的液相色谱-串联质谱分析方法,并进行方法学验证。方法血液、尿液和肝用1%乙酸甲醇溶液去蛋白后,上清液用固相萃取法净化,LC-MS/MS检测。结果血液、尿液和肝中TTX检出限分别为2ng/mL、2ng/mL和4ng/g。血液和尿液在4～100ng/mL、肝在5～100ng/g的范围内线性关系良好,相关系数r≥0.9973;日内精密度和日间精密度均在12.80%以内;回收率大于47.2%。结论所建方法高效、灵敏、准确,可以为河豚毒素中毒的法医学鉴定、临床诊治以及食品安全的监控提供技术保障。