甲基苯丙胺滥用与司来吉兰服用的区分:尿液中甲基苯丙胺和苯丙胺的手性分析

目的考察司来吉兰及其代谢物在尿液中的含量变化,并结合实际案例探讨手性分析区分甲基苯丙胺滥用与司来吉兰服用的可行性。方法采用CHIROBIOTICTM V2手性液相色谱柱对尿液样品进行手性分离和液相色谱-串联质谱(LC-MS/MS)法测定,并对司来吉兰服药志愿者尿样、疑服用司来吉兰的涉毒人员尿样进行甲基苯丙胺和苯丙胺的手性分析。结果服用5 mg司来吉兰后,尿液中司来吉兰的检出时限仅为7h。尿液中R(-)-甲基苯丙胺和R(-)-苯丙胺约在7h质量浓度最高,分别为0.86μg/m L和0.18μg/m L,并在80 h和168 h后无法检出。应用该方法成功分析了疑服用司来吉兰的涉毒人员尿液中甲基苯丙胺和苯丙胺的来源。结论甲基苯丙胺和苯丙胺的手性分析以及司来吉兰代谢物检测可区分甲基苯丙胺滥用与司来吉兰服用。     

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。     

Immunoassay for methamphetamine with a new antibody

p- and o-Aminomethamphetamine were synthesized as haptens to be coupled with carrier protein at the benzene ring of methamphetamine. Immunogens were prepared by the glutaraldehyde method or the MBS (N-(m-maleimidobenzoyloxy)succinimide) type cross-linking reagent method. In particular, immunization with p-aminomethamphetamine-bovine serum albumin (BSA) conjugate prepared by the glutaraldehyde method gave an anti-methamphetamine antiserum having a low cross-reactivity with methylephedrine. With the antiserum, three kinds of immunoassays for methamphetamine were established. An enzyme immunoassay (EIA) and an enzyme-linked immunosorbent assay (ELISA) were developed with alkaline phosphatase (ALP) as a label enzyme. The amount of antibody bound ALP conjugate was determined by its activity in dephosphorylating p-nitrophenyl phosphate in EIA and nicotinamide adenine dinucleotide phosphate (NADP+) in ELISA. The range of methamphetamine measurable by ELISA was 0.025-0.5 ng/well and its sensitivity was superior to that of EIA (0.3-300 ng/tube). A latex agglutination inhibition reaction test (LAIRT) was also developed for the mass screening method of urine samples. The sensitivity of this method for methamphetamine was 0.1 micrograms/ml urine.     

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.     

GC法检测血液和尿液中甲基苯丙胺和咖啡因

目的建立同时测定血、尿中甲基苯丙胺和咖啡因含量的方法。方法应用GC／NPD技术,以4-苯基丁胺为内标,直接碱化,用氯仿提取,三氟乙酸酐衍生化,8CB熔融石英毛细管柱（30m×0．25mm×0．25μm）分析。结果生物样品中甲基苯丙胺与咖啡因在0．012—7．5μg/mL浓度范围内线性关系良好,检测限（S／N=3）依次为1．2ng／mL,0．6ng／mL（血）;1．6ng／mL,0．8ng／mL（尿）。苯丙胺在0．017—10．0μg／mL浓度范围内线性关系良好,检测限为1．6mg／mL（血）,3．2ng／mL（尿）。所有样本回收率均大于85％。结论本方法准确、灵敏,适用于血、尿中甲基苯丙胺及其代谢物苯丙胺的三氟乙酸酐衍生化物和咖啡因的同时检测,为判定滥用毒品种类、追查毒品来源以及研究生物体内甲基苯丙胺和咖啡因的交互影响提供了检测手段。     

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 μl 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 μg/ml for amphetamine, 0.1 μg/ml for methamphetamine and MDA, 0.05 μg/ml for MDMA, 0.025 μg/ml for MDEA and 0.015 μg/ml for PCP. Relative standard deviation (R.S.D.) values ranged between 5 and 20% for the studied drugs.     

Miniaturized sample preparation method for determination of amphetamines in urine

A simple and miniaturized sample preparation method for determination of amphetamines in urine was developed using on-column derivatization and gas chromatography-mass spectrometry (GC-MS). Urine was directly applied to the extraction column that was pre-packed with Extrelut and sodium carbonate. Amphetamine (AP) and methamphetamine (MA) in urine were adsorbed on the surface of Extrelut. AP and MA were then converted to a free base and derivatized to N-propoxycarbonyl derivatives using propylchloroformate on the column. Pentadeuterated MA was used as an internal standard. The recoveries of AP and MA from urine were 100 and 102%, respectively. The calibration curves showed linearity in the range of 0.50-50 microg/mL for AP and MA in urine. When urine samples containing two different concentrations (0.50 and 5.0 microg/mL) of AP and MA were determined, the intra-day and inter-day coefficients of variation were 1.4-7.7%. This method was applied to 14 medico-legal cases of MA intoxication. The results were compared and a good agreement was obtained with a HPLC method.     

SPME-GC-MS法快速检测尿液中的甲基苯丙胺

目的建立SPME-GC-MS快速检测吸毒人员尿液中的甲基苯丙胺的方法。方法以SPME法提取尿液中的甲基苯丙胺,以1-萘胺作内标,用GC-MS法检测。结果在2～2000ng/mL的范围内呈线性关系(r=0.9985,n=7),甲基苯丙胺的检测限为0.5ng/mL(信噪比3),在低、中、高(200、500、1000ng/mL)浓度的平均相对回收率为102.6%、98.5%、93.2%,日内及日间RSD分别小于8.1%、7.2%。结论用此方法检测尿液中的甲基苯丙胺,灵敏度高,简单快速,易操作,适用于吸毒人员的快速定性定量检测。     

Distribution and optical purity of methamphetamine found in toxic concentration in a civil aviation accident pilot fatality

Toxicological evaluation of postmortem samples collected from a pilot involved in a unique fatal civil aircraft accident is described in this paper. A one-occupant airplane was substantially damaged upon colliding with terrain in poor visibility. Remains of the pilot were found outside the aircraft. Pathological examination revealed multiple blunt force injuries and vascular congestion. The fluorescence polarization immunoassay disclosed 8.0 microg/mL amphetamines in urine. Gas chromatographic/mass spectrometric analyses determined the presence of methamphetamine (1.13 microg/mL in blood and 59.2 microg/mL in urine) and amphetamine (0.022 microg/mL in blood and 1.50 microg/mL in urine). Methamphetamine was distributed throughout the body, including the brain. The amount of methamphetamine in gastric contents was 575-fold higher than that of amphetamine. The (+)- and (-)-forms of methamphetamine were present in equal proportions in gastric contents. The methamphetamine concentration found in blood was in the range sufficient to produce toxic effects, causing performance impairment.     

A case of fatal hemorrhage in the cerebral ventricles following intravenous use of methamphetamine

We describe a case of massive hemorrhage in the cerebral ventricles, probably caused by methamphetamine abuse. A 44-year-old male was found dead in a prone position in a hotel room. Old and new injection marks were observed in his right cubital fossa. Petechiae were observed on the conjunctiva of his right eye, laryngeal mucosa, epicardium and under the capsule of the liver (to a slight or moderate degree). The brain, weighing 1.67 kg, was heavily edematous; the lateral and fourth ventricles were filled with hematomas. Subarachnoid, intracerebral hemorrhages were not observed. Cerebral vascular abnormalities were not evident. There were no remarkable changes in other organs, other than congestion. Gas chromatographic-mass spectrometric analysis of the urine disclosed the presence of methamphetamine and amphetamine. The concentration of methamphetamine within the femoral venous blood and intraventricular hematoma was 0.347 microg/ml and 0.189 microg/g, respectively. Amphetamine was not detected in either sample. Urine contained 3.15 microg/ml methamphetamine and 0.063 microg/ml amphetamine. These results indicate that intraventricular hemorrhage might have occurred shortly after intravenous self-administration of methamphetamine. Cerebral arterial spasm and hypertension resulting from the administration of methamphetamine might have resulted in intraventricular hemorrhage.     

超高效液相色谱法（UPLC）同时筛选检测吗啡等7种常见毒品

目的建立快速筛选检测中毒者血液、尿液中吗啡、甲基苯丙胺、苯丙胺、麻黄碱、3，4-亚甲基双氧甲基苯丙胺（MDMA）、3，4-亚甲基双氧苯丙胺（MDA）、氯胺酮并定量分析的方法；方法采用超高效液相色谱（UP—LC）-二极管阵列检测器（PAD）；结果峰面积和质量浓度的线性关系良好，分离效果好、速度快、灵敏度提高；结论该方法与传统的HPLC相比能够更好满足实际办案中吗啡、甲基苯丙胺、苯丙胺、麻黄碱、MDMA、MDA、氯胺酮等中毒者血液、尿液的筛选检测并定量分析。     

Methamphetamine and amphetamine concentrations in postmortem rabbit tissues

The feasibility of detecting methamphetamine and its major metabolite, amphetamine, in postmortem tissues over a 2-year period was examined. It is important to determine if the abuse and toxic effects of drugs can be proved from evidence found in decayed, submerged, or stained tissue materials. The blood, urine, liver, skeletal muscle, skin and extremity bones from rabbits given methamphetamine intravenously were kept at room temperature, under 4 different conditions: sealed in a test tube, dried in the open air, submerged in tap water and stained on gauze. Methamphetamine was present in all the samples, with slight change in concentration in case of sealed and air dried tissues. Changes varied in bones kept in water. There were considerable decreases in methamphetamine in blood and urine stains. Despite long term storage, drug abuse and/or toxicity could be determined, in all tissues examined.     

A screening method for urinary methamphetamine--latex agglutination inhibition reaction test

Methamphetamine in urine samples from abusers was detected by the latex agglutination inhibition reaction test with latex-antibody (Latex-Ab) and latex-methamphetamine (Latex-MA) reagents. Anti-methamphetamine antibody was produced in rabbits by immunization with bovine serum albumin (BSA)-methamphetamine conjugate. Latex particles were coated with antibodies or with rabbit serum albumin (RSA)-methamphetamine conjugate to obtain Latex-Ab and Latex-MA reagents, respectively. The results are read at 4-5 min after mixing the latex reagents. The sensitivity of this method for methamphetamine was 0.4 micrograms/ml urine. Methamphetamine analogs (methylephedrine, amphetamine, phentermine, methoxyphenamine, ephedrine, beta-phenylethylamine, OH-methamphetamine, OH-amphetamine, and OH-ephedrine) all cross-react in varying degrees, while glucosiurea and albuminurea give false positive results in the tests. Though attention must be paid to these effects this simple and rapid test is suitable for the mass screening of urine samples.     

Enantiomeric separation of amphetamine by high-performance liquid chromatography using chiral crown ether-coated reversed-phase packing: application to forensic analysis

d-Amphetamine and l-amphetamine were clearly separated by HPLC analysis using a chiral crown ether column (CROWNPACK CR(+)). As little as 0.1% d-amphetamine in bulk methamphetamine could be determined. The enantiomeric form of the by-product in a drug sample may be helpful in evaluating the possibility of illicit synthesis. When the isomeric composition of amphetamine present in urine from a methamphetamine abuser was examined, only d-amphetamine was detected as a metabolite. The present method was also applied to the enantiomeric separation of norephedrine.     

Studies on fluorescamine: Part I--Applications of fluorescamine in forensic toxicological analysis.

This paper describes some applications of the fluorescamine spot test to forensic toxicological analysis. The fluorescamine test only reacts with primary amines; thus, this test makes a clear-cut distinction between amphetamine and methamphetamine. Previous common spot tests used reacted the same with these two amines. Fluorescamine is 100 times more sensitive in detecting amphetamine extracted from urine on thin-layer chromatograms than ninhydrin. Thus, it is a more sensitive method of detecting amphetamine abuse in urinalysis screening programs.     

Analysis of dimethylamphetamine and its metabolites in human urine by liquid chromatography-electrospray ionization-mass spectrometry with direct sample injection

An analytical method to identify and determine dimethylamphetamine (DMA) and its metabolites in human urine was developed with liquid chromatography-electrospray ionization-mass spectrometry (LC-ESI-MS) involving the direct injection of a urine sample. The urine samples were directly injected by using a gel permeation column, whose stationary phase was polyvinyl alcohol with a small amount of a carboxyl group, so DMA and its metabolites were analyzed rapidly and simply without pretreatment such as extraction, concentration and derivatization. DMA and its metabolites were identified in drug-free human urine spiked with 1 microg of DMA, dimethylamphetamine N-oxide (DMANO) and methamphetamine (MA), and 3 microg of amphetamine (AM) in 1 ml of urine under the full-scan mode. Under the selected ion monitoring (SIM) mode, the limits of detection (signal-to-noise ratio=5) for DMA, DMANO, MA and AM were 20, 20, 20 and 60 ng in 1 ml of urine, respectively. This method was applied to the identification and determination of DMA and its metabolites in urine samples of 10 DMA abusers. The concentrations of DMANO were higher than those of unchanged DMA in all urine samples; thus, DMANO is considered to be a useful metabolite as an indicator to prove DMA intake.     

Simultaneous analysis of amphetamine, methamphetamine, and 3, 4-methylenedioxymethamphetamine (MDMA) in urine samples by solid-phase extraction, derivatization, and gas chromatography/mass spectrometry

A rapid and effective solid-phase extraction procedure using Bond Elute Certify bonded silica sorbent cartridges was adopted to extract amphetamine, methamphetamine, and 3,4-methylenedioxymethamphetamine (MDMA or Ecstasy) from urine samples. The extract was derivatized with trichloroacetic anhydride prior to gas chromatography/mass spectrometry (GC/MS) analysis with selected ion monitoring of the following ions: 190, 91, 188; 204, 91, 202; 162, 135, 202; 194, 123; and 211, 209 for the derivatized amphetamine, methamphetamine, MDMA, d5-amphetamine, and d9-methamphetamine, respectively. The first of the ions listed for each compound was used for quantitation. The compound d5-amphetamine was used as the internal standard for amphetamine, and d9-methamphetamine was used for methamphetamine and MDMA. Results showed a higher than 65% recovery and a reproducibility with less than a 5% coefficient of variation. When a sample size of 2 mL was used, the lowest detectable concentration was about 50 ng/mL, and a near-perfect fit can be obtained (within the 250 to 4000-ng/mL concentration range studied) using a second-order polynomial model.     

基于X-射线衍射法检测甲基苯丙胺晶体并推断来源

目的采用X-射线衍射法(XRD)建立一种快速检测甲基苯丙胺晶体并推断其来源的方法。方法对18起案件中的53份甲基苯丙胺样本进行XRD检验。结果通过分析主要特征峰强度比例,可以得到毒品的定性分析结果,以及样本的晶型取向信息;通过分析XRD谱图中毒品的特征峰半峰宽信息可以得到毒品的结晶度;对样本中明显的杂质峰进行比对,即可得到毒品来源信息参考。结论该方法简便快捷、无损样本、无污染,能够快速、准确、高效地分析结晶状毒品,为确定制贩毒集团上下线及涉毒案件串并案提供佐证。     

The use of cyclohexanone as a "derivatizing" reagent for the GC-MS detection of amphetamines and ephedrines in seizures and the urine

A GC-MS method has been developed for the detection of amphetamine, methamphetamine, and the ephedrines, in seizures and the urine, based on on-GC condensation (derivatization) with cyclohexanone. The method is simple: the dried seizure material or the urine extract was mixed with cyclohexanone and injected into the GC-MS. The method was found to be superior to the methods based on acyl and trimethylsilyl (TMS) derivatization. Unlike for the acyl and TMS derivatives, the molecular and fragment ions of the cyclohexanone condensation products (cyclohexanone derivatives) were of substantial abundance, a useful property in unambiguous compound characterization. Furthermore, the high stability of the "derivatizing" reagent, cyclohexanone, compared with acyl and TMS derivatizing reagents, is a useful property in method development. The present method has proved selective and, tentatively, sensitive enough in the following areas (where methods based on acyl and TMS derivatization, as tested in this laboratory, have failed): (a) detection of amphetamine as a metabolite of methamphetamine; (b) detection of norpseudoephedrine as a metabolite of pseudoephedrine; (c) detection of amphetamine as an impurity of methamphetamine; (d) detection of cathine (norephedrine) as a constituent of Khat leaves; and (e) differentiation of Khat use from phenylpropanolamine use.     

Abuse of "pheticol" and its interference to the analysis of methamphetamine

The study was to eliminate interference from ephedrine in the analysis of methamphetamine. The extraction procedure for methamphetamine was modified to include an oxidation step (2 ml urine specimen was treated with 0.5 ml of 1 mol/L phosphate buffer (pH 6.8) and 0.5 ml 0.3 mol/L sodium periodate). Results showed that ephedrine could be oxidized in the presence of periodate ions into smaller fragments while leaving methamphetamine intact. It is recommended that specimens be treated with sodium periodate prior to extraction in order to eliminate any interference caused by ephedrine.