尿中吗啡的氮磷检测——气相色谱分析法

目的建立尿中吗啡的简便快速、灵敏可靠的GC/NPD分析方法。方法样品尿加内标烯丙吗啡,酶或酸催化水解,氯仿-异丙醇(9:1)液液提取或GDX403树脂固相提取,BSA衍生化,HP-5柱和氮磷检测器进行分析。结果 提取率62％～85％,检出限1.2～3.1ng/ml,线性范围20～2000ng/ml,回收率(97％～99％)±(6％~9％)(Mean±cv,N=5)。结论 方法适合于实际案件中尿样的检验。     

电子烟油和毛发中合成大麻素CUMYL-PEGACLONE的检测

目的建立联合高效液相色谱-串联质谱法（highperformanceliquidchromatography-tandem massspectrometry,HPLC-MS/MS）和气相色谱-质谱法（gaschromatography-massspectrometry,GC-MS）检测电子烟油和毛发中合成大麻素5-戊基-2-(2-苯基丙-2-基)-2,5-二氢-1H-吡啶[4,3-b]吲哚-1-酮（CUMYL-PEGACLONE）的方法。方法 采用HPLC-MS/MS和GC-MS建立CUMYL-PEGACLONE检测方法,对涉毒人员毛发和查获的电子烟油进行检测。结果 GC-MS测得CUMYL-PEGACLONE主要质谱特征离子m/z为91、179、197、254和372;CUMYL-PEGACLONE在2～50 ng/mL质量浓度范围内线性关系良好,线性相关系数（r）大于0.99;毛发中CUMYL-PEGACLONE的HPLC-MS/MS方法检出限为0.01 ng/mg,定量限为0.02 ng/mg;电子烟油中CUMYL-PEGACLONE的HPLC-MS/MS方法检出限为1 ng/m...     

QTRAP LC-MS/MS同时测定毛发中20种毒品及代谢物

目的建立了毛发中20种毒品及代谢物的液相色谱-四极杆/线性离子阱质谱(QTRAP LC-MS/MS的检测方法。方法将洗净的毛发样品粉碎后经甲醇超声提取,离心取上清液过滤膜后,以含有5mM氟化铵的水溶液和乙腈作为流动相,经Phenomenex Kinetex?Biphenyl(100×3.0 mm, 2.6μm)分离,采用多反应监测(MRM)、信息依赖性采集(IDA)、增强子离子扫描(EPI),结合20种毒品EPI谱库检索的多步模式进行分析。结果 20种毒品及相关代谢物在浓度范围0.02ng/mg～2ng/mg内线性良好,线性相关系数均大于0.995;方法检出限(S/N=3)为0.10ng/g～1.00ng/g;在0.05、0.20、1.00ng/mg 3个添加水平的回收率为80.1%～110.3%,相对标准偏差1.05%～6.39%。结论本方法简便、快捷、可靠、灵敏度高,可满足鉴定工作需要。     

毛发中甲基苯丙胺及代谢产物苯丙胺的分析研究

介绍了毛发中甲基苯丙胺（ MAMP）及代谢产物苯丙胺（ AMP）的 GC/NPD、 GC/MS的定性定量分析方法。毛发用 0.1 mol/L HCl水解, 4－苯基丁胺（ 4－ PBA）为内标,液－液提取,三氟乙酸酐（ TFA）衍生化。毛发用量为 10mg,检出限为 GC/NPD 0.5ng/mg, GC/MS 0.1ng/mg,回收率大于 78％。该方法成功应用于染毒豚鼠毛发中 MAMP及其代谢产物 AMP浓度变化过程的测定。     

过敏性休克死亡体内血栓素B_2含量变化的研究

本研究采用非平衡法,对青霉素和血清过敏性休克致死机体的血浆、肺、脾和肾中血栓素B_2(Thromboxane,TXB_2)进行放射免疫分析(RIST)。正常对照组血浆中TXB_2含量是9.63±1.77(ng/ml),实验组休克前是9.264±3.01(mg/ml),两者P>0.05。青霉素休克组30.36±10.72(ng/ml);血清休克组40.10±6.51(ng/ml),与对照及休克前相比均P<0.01。对照、青霉素和血清过敏性休克肺中TXB_2依次为:89.90±6.57、171.96±18.07和187.70±18.89(ng/g)(P<0.01)。脾中依次为:68.334±10.09、137.68±15.97和173.72±18.75(ng/g)(P<0.01)。肾中依次为:73.89±5.05、128.30±19.99和152.15±17.77(ng/g)(P<0.01)。过敏性休克致死的机体置室温6或12h,或冰箱48h后,不明显影响TXB_2的检测。研究者认为:发生过敏性休克时,血栓素系统发生剧烈变化,表现为血和脏器中TXB_2的增加,可为确定过敏性休克死亡提供一个重要的生化指标。     

液液萃取-超高效液相色谱-串联质谱法测定常见食用植物油中5种鸦片生物碱

目的建立酸化甲醇(pH=3)液液萃取-超高效液相色谱-串联三重四极杆质谱(UPLC-MS/MS)测定常见食用植物油中5种鸦片生物碱吗啡、可待因、蒂巴因、罂粟碱、那可汀的检验方法。方法样品加入正己烷摇匀后用酸化甲醇(pH=3)提取,BEH C18色谱柱分离,乙腈(0.01%甲酸)-水(0.01%甲酸+0.05%氨水,体积比)梯度洗脱,电喷雾离子源正离子(ESI+)及多反应监测模式检测。结果结果显示5种待测成分在0.5~300ng/g范围内线性关系良好;方法检出限(S/N=3)在0.1~2ng/g间、定量限(S/N=10)在0.5~3ng/g间;回收率(20ng/g,200ng/g)在82.0%~101.4%间,相对标准偏差(RSD,n=6)为1.4%~4.2%,基质效应(20ng/g,200ng/g)在-5.3%~5.8%间,日间精密度为2.8%~6.7%。结论本方法前处理简单、耗时短,溶剂使用量少,灵敏度高,适合大批量常见食用植物油中5种鸦片生物碱的同时检测。     

用GC／ECD方法分析海洛因中毒尿液吗啡代谢物

目的　考查尿检材中海洛因的代谢物吗啡和单乙酰吗啡的液液萃取条件、三氟乙酰化和气相色谱电子捕获检测 (GC/ECD)条件。方法　以烯丙吗啡为内标 ,氯仿∶异丙醇 (9∶1)为液相萃取剂萃取尿中的吗啡和单乙酰吗啡 ,采用MBTFA衍生化 (三氟乙酰化 ) ,GC/ECD检测。结果　尿中加样相对回收率吗啡 89% ,单乙酰吗啡 75 % ,最小检测量吗啡 5 0ng ,单乙酰吗啡 10 0ng。通过实验兔的中毒实验 ,对尿检材进行了分析。 结论　所建立的萃取与检测方法分析海洛因中毒尿检材中的吗啡准确、灵敏 ,可用于海洛因的吸毒检验     

SPE-LC-MS/MS法测定尿液与血液中海洛因3种代谢物

目的采用SPE-LC-MS/MS方法,同时检测尿液与血液中海洛因主要代谢物3-β-D-葡萄糖醛酸吗啡(M3G)、吗啡和O6-单乙酰吗啡(O6)。方法采用BAKERBONDTMspe Octadecyl(C18)进行提取,应用LC-MS/MS方法检测并通过MRM及内标法进行量化。结果尿液中M3G、吗啡、O6-单乙酰吗啡的最低检测限(LOD)分别为1.24pg、6.71pg、0.47pg;回收率依次为82.25±12.25%、93.75±13.25%、88.70±11.90%。血液中M3G、吗啡、O6-单乙酰吗啡的最低检测限分别为1.50pg、8.21pg、0.52pg。回收率依次为89.85±21.15%、73.70±17.90%、90.10±3.90%。结论本文所建方法同时适用于尿液与血液中海洛因主要代谢物M3G、吗啡、O6-单乙酰吗啡的提取、净化、分析。     

度冷丁滥用者毛发分段分析及其结果评价

以度冷丁滥用者为研究对象,在度冷丁滥用者毛发中检出度冷丁及代谢物去甲度冷丁、N一羟甲基度冷丁和N-乙酰度冷丁。60例度冷丁滥用者头发中度冷丁和去甲度冷丁的含量分别为103±130ng／mg和117±143ng／mg。度冷丁稳定地存在于头发中,检出时限至少为药后20个月,而去甲度冷丁则随着离头发根距离的增加而降低。头发分段分析揭示度冷丁在毛干中的分布和滥用史、剂量和含量存在相关性。     

固体进样杆-GC/MS-SIM技术检验头发中6-单乙酰吗啡

目的建立固体进样杆-GC/MS-SIM技术,检测人头发中毒品海洛因的主要代谢产物6-单乙酰吗啡的方法。方法样品头发洗净剪碎后,经MSTFA衍生化,采用GC/MS-SIM定性定量分析。结果 6-单乙酰吗啡在浓度0.1ng/mg～18.0ng/mg范围内线性相关系数为0.9972,方法检出限为0.1ng/mg。结论本方法头发使用量小,准确度、精密度良好、灵敏度高,是高效、快速、实用的测定头发中6-单乙酰吗啡的方法。     

Analysis of hair after contamination with blood containing 6-acetylmorphine and blood containing morphine

The study was carried out to investigate external contamination of hair by blood in heroin-related post-mortem cases. Solutions were prepared containing 0.05, 0.1, 0.2, 0.5 and 3.0μg/mL of 6-monoacetylmorphine (6-AM) only or morphine only in human blood. Samples of approximately 3.2g of drug-free hair were contaminated by soaking in the blood solutions for 5min. They were then removed and left at room temperature. Approximately 0.5g of hair was collected from each of the blood soaked hair samples at 6h, 1, 2, 4 and 7 days after contamination. As each hair sample was collected it was shampoo-washed to prevent further drug absorption. Hair samples were analysed in triplicate using a fully validated method described previously. 6-AM broke down to morphine in all samples. In hair contaminated with blood containing 0.05, 0.1 and 0.2μg/mL 6-AM or morphine drug was either not detected or was detected below the limit of quantitation (0.2ng/mg hair) at all contamination times. In hair contaminated with blood spiked with 0.5μg/mL morphine, the concentration in hair ranged from 0.54 to 0.91ng/mg and in hair contaminated with blood spiked with 3.0μg/mL, from 3.25 to 5.77ng/mg. The concentrations of 6-AM ranged from 0.65 to 1.11ng/mg and morphine from 0.34 to 0.80ng/mg in hair contaminated with 0.5μg/mL 6-AM in blood. 6-AM ranged from 2.12 to 3.67ng/mg and morphine from 0.84 to 2.05ng/mg in hair contaminated with 3μg/mL 6-AM in blood. For 6-AM and morphine ANOVA statistical evaluation showed no significant difference among the concentrations over time.     

Effect of murine retroviral infection on hair and serum levels of cocaine and morphine.

LP-BM5 retrovirally infected female C57BL/6J mice were administered cocaine, morphine or both by daily intraperitoneal injection for 9 weeks. Drug concentrations were measured by radioimmunoassay in serum and in hair extracts. Hair samples obtained from all drug-treated mice were positive for the drug injected, while none of the saline-treated mice had detectable drug levels in hair or serum. The average morphine concentration obtained from non-infected mice was 11 ng/mg hair whereas the amount found in the LP-BM5-infected mice was significantly higher (20 ng/mg hair). Mice injected with both morphine and cocaine were given 50% of the regular dose of each drug and drug levels in the hair of these animals were approximately half that of mice injected with the full dose of the single drug. Non-infected mice treated with both drugs had a mean value of 7 ng morphine/mg hair and 374 ng cocaine/mg hair while retrovirus-infected mice had significantly higher concentrations, 10 ng morphine/mg hair and 1160 ng cocaine/mg hair (P less than 0.001). Serum concentrations of cocaine and morphine were significantly higher (P less than 0.01) in the retrovirus-infected animals from 40 min to 1.5 h. The increased concentrations of cocaine and morphine in serum during retrovirus infection are accompanied by a significant increase in the amount of drug incorporated into the hair matrix. This change indicates that retroviral infection may influence the disposition of these drugs in the systemic circulation.     

Distribution of 6-monoacetylmorphine and morphine in head and pubic hair from heroin-related deaths

There is limited published data to aid interpretation of analytical findings from hair analysis. The aim of the study was to collate 6-monoacetylmorphine (6-AM) and morphine concentrations in head and pubic hair from heroin users and to propose reference ranges and relate these to the amount of heroin used. The ratio of morphine-to-6-AM was also investigated. A total of 82 head hair samples divided into 173 segments of various lengths and 15 pubic hair samples were collected at postmortem from heroin users. The hair was analysed using a previously published method. A statistical evaluation demonstrated that in head hair, the lower, middle and upper concentration ranges of 6-AM were 0.1–0.9, 0.9–12.5 and 12.5–154.1 ng/mg and those of morphine were 0.1–0.8, 0.8–6.0 and 6.0–36.3 ng/mg. In pubic hair, the lower, middle and upper concentration ranges of 6-AM were 0.2–0.5, 0.5–2.3 and 2.3–18.2 ng/mg and those of morphine were 0.2–0.4, 0.4–2.4 and 2.4–13.3 ng/mg. The morphine-to-6-AM ratio showed a large variation. The ratio tended to decrease from proximal to distal segments. The statistical results suggest low, middle and high concentration ranges which we propose can be used for estimating the amount of heroin consumed into corresponding low or occasional, regular or habitual and heavy or excessive drug use. The ratio of morphine-to-6-AM showed great variation and did not support the proposal that a ratio less than 0.77 is needed to prove ingestion of heroin.     

SPE/UPLC法检测血中吗啡、苯丙胺类及氯胺酮

目的建立SPE/UPLC方法在同一条件下同时检测血中吗啡、苯丙胺类及氯胺酮。方法采用SCX 3cc（60mg）固相萃取柱萃取血中吗啡、MA、MDMA、MDA及氯胺酮,用超高效液相色谱（UPLC）-二极管阵列检测器（PDA）检测,结合保留时间和紫外光谱进行定性、定量分析,对实验各环节进行优化,并进行实际案例检测。结果吗啡、MA、MDMA、MDA、氯胺酮的固相萃取提取回收率分别为81.4%±2.51%、88.2%±2.48%、91.8%±2.03%、93.8%±1.46%、74.8%±2.27%,峰面积和质量浓度的线性关系良好（r〉0.999）,线性范围分别为0.08～100μg/mL、0.4～100μg/mL、0.2～75μg/mL、0.3～75μg/mL、0.4～100μg/mL,检出限分别为30pg、200pg、80pg、100pg、200pg。结论本文所建方法适用于血中吗啡、苯丙胺类、氯胺酮常见毒品的筛选及定量分析。     

Simultaneous Quantitative Determination of Amphetamines,Opiates, Ketamine,Cocaine and Metabolites in Human Hair: Application to Forensic Cases of Drug Abuse

A method using liquid chromatography–tandem mass spectrometry (LC–MS/MS) to simultaneously quantify amphetamines, opiates, ketamine, cocaine, and metabolites in human hair is described. Hair samples (50 mg) were extracted with methanol utilizing cryogenic grinding. Calibration curves for all the analytes were established in the concentration range 0.05–10 ng/mg. The recoveries were above 72%, except for AMP at the limit of quantification (LOQ), which was 48%. The accuracies were within ±20% at the LOQ (0.05 ng/mg) and between −11% and 13.3% at 0.3 and 9.5 ng/mg, respectively. The intraday and interday precisions were within 19.6% and 19.8%, respectively. A proficiency test was applied to the validated method with z-scores within ±2, demonstrating the accuracy of the method for the determination of drugs of abuse in the hair of individuals suspected of abusing drugs. The hair concentration ranges, means, and medians are summarized for abused drugs in 158 authentic cases.     

Detection of meperidine and its metabolites in the hair of meperidine addicts

The presence of meperidine and its metabolites in the hair of meperidine addicts was investigated using GC–MS (EI, PCI). Meperidine and its three metabolites – normeperidine, N-methoxy meperidine and acetyl normeperidine, were found in hair samples from addicted subjects. Methods for the simultaneous determination of meperidine and its metabolites by GC–MS-SIM were also established for human hair samples. After the addition of d₄-meperidine as an internal standard, hair samples weighing 5 mg were incubated in 0.1 M HCl at 45°C overnight, and the resulting digests were extracted with ether. The recoveries were greater than 80%, with coefficients of variation (CVs) between 4.48 and 8.31%. The calibration curves for meperidine and normeperidine in hair were linear over a concentration range of 1 to 500 ng per mg of hair, with correlation coefficients of r=0.9990 and r=0.9992, respectively. Values less than 0.25 ng/mg of hair were cut off. Hair samples obtained from 60 drug addicts were analyzed using this method, and the content of meperidine and normeperidine was determined to be 103±130 and 117±143 ng/mg, respectively. Sectional analysis revealed that meperidine was present and stable in hair for at least 20 months, but normeperidine content at the level of the hair root was higher compared to the tip of the hair shaft. The results also revealed that there was a correlation between the subject’s drug abuse history and the distribution of drug along the hair shaft, and between the doses of meperidine and drug content presented in hair.     

Determination of tramadol in hair using solid phase extraction and GC-MS

Tramadol is a centrally acting synthetic analgesic with mu-opioid receptor agonist activity, it is a widely prescribed analgesic used in the treatment of moderate to severe pain and as an alternative to opiates. Tramadol causes less respiratory depression than morphine at recommended doses. Its efficacy and low incidence of side effects lead to its unnecessary prescribing in patients with mild pain. Tramadol was classified as a "controlled drug" long after its approval for use in Jordan. Analysis of drugs of abuse in hair has been used in routine forensic toxicology as an alternative to blood in studying addiction history of drug abusers. A method for the determination of tramadol in hair using solid phase extraction and gas chromatography-mass spectrometry (GC-MS) is presented, the method offers excellent precision (3.5-9.8%, (M)=6.77%), accuracy (6.9-12%, M=9.4%) and limit of detection 0.5 ng/mg. The recovery was in the range of 87-94.3% with an average of 90.75%. The calibration curve was linear over the concentration range 0.5-5.0 ng/mg hair with correlation coefficient of 0.998. The developed method was tested on 11 hair samples taken from patients using tramadol as prescribed by their physician along with other different drugs in treating chronic illnesses. Tramadol was detected in all hair samples at a concentration of 0.176-16.3 ng/mg with mean concentration of 4.41 ng/mg. The developed method has the potential of being applied in forensic drug hair testing. In Jordan, hair drug testing started to draw the attention of legal authorities which stimulated forensic toxicologists in recent years to develop methods of analysis of drugs known or have the potential to be abused.     

Simultaneous determination of opiates,cocaine and major metabolites of cocaine in human hair by gas chromotography/mass spectrometry (GC/MS)

A procedure is presented for the simultaneous identification and quantification of morphine (MOR), codeine (COD), ethylmorphine (EM), 6-monoacetylmorphine (6-MAM), cocaine (COC), benzoylecgonine (BZE), ecgonine methylester (EME) and cocaethylene (CE), contained in the hair of opiates and cocaine addicts. The method involves decontamination in dichloromethane, pulverization in a ball mill, heat-acid hydrolysis, addition of deuterated internal standards, liquid-liquid extraction and gas chromatography/mass spectrometry (GC/MS) after silylation. The limit of detection (LOD) was ~0.1–0.8 ng/mg for each drug, using a 30-mg hair sample. The method is reproductible, with a coefficient of variation (CV) of ~8–17%. Cocaine and 6-monoacetylmorphine were the major compounds detected in cases of cocaine (14 cases) and heroin (68 cases) intake. Concentrations were in the range 0.4–78.4 ng/mg (COC), 0.0–36.3 ng/mg (BZE), 0.0–1.6 ng/mg (EME), 0.0–2.1 ng/mg (CE), 0.0–84.3 ng/mg (6-MAM), 0.2–27.1 ng/mg (MOR) and 0.1–19.6 ng/mg (COD). An application in forensic sciences, involving multi-sectional analysis, is given.     

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.