Concentrations of phenobarbital, flurazepam, and flurazepam metabolites in autopsy cases.

In five cases of death resulting from acute intoxication with phenobarbital and flurazepam, the blood, urine, brain, lung, liver, and kidney levels of these drugs as well as the levels of N-1 hydroxyethyl, N-1 desalkyl, and N-1 desalkyl-3-hydroxy flurazepam metabolites were determined. Concentration of flurazepam and its metabolites was determined by using new gas chromatographic conditions employing a selective detector for nitrogen-containing substances and a column of 1% SP-1000. In addition, the EMIT technique was also employed on blood and urine samples and the results compared with GLC data.     

Diagnostic implication of blood and urine morphine content in alcohol intoxication

A total of 198 cases of acute parenteral poisoning with opiates are characterized. The range of concentrations of opiates metabolites in the blood and urine, main causes of death due to opiate poisoning in alcohol intoxication are analysed. Opiates toxicity was assessed with the logit-regression method and dose-effect curves valid for analysis of relationships between probability of death and opiate metabolites concentration in blood and urine. Correlation between probability of death and detection of morphine and ethanol in biological media of the victims is considered. Concentrations of morphine in blood and urine definitely indicating opiates poisoning in alcohol intoxication as a cause of death are determined.     

Acute intoxication caused by overdose of flunitrazepam and triazolam: high concentration of metabolites detected at autopsy examination

ABSTRACT: A 52-year-old woman was found dead on the floor of the living room on the first floor of a house, which belonged to the man with whom she shared the house. On visiting the site, her clothes were found to be undisturbed. Packages of flunitrazepam (Silece, 2 mg/tablet) and triazolam (Halcion, 0.25 mg/tablet) were found strewn around the victim. Toxicological analysis was performed, and the concentrations of flunitrazepam, triazolam, and their metabolites in the victim's blood and urine were measured by high-performance liquid chromatography coupled with photodiode array and mass spectrometry. A high blood concentration of 7-aminoflunitrazepam was detected (1,270 ng/g), and further metabolites such as 7-acetamidoflunitrazepam, 7-acetamidodesmethylflunitrazepam, and 7-aminodesmethylflunitrazepam were detected in the blood and urine samples. In addition, 4-hydroxytriazolam and α-hydroxytriazolam were detected in her urine at a concentration of 950 and 12,100 ng/mL, respectively.On the basis of the autopsy findings and toxicology results of high concentrations of both flunitrazepam and triazolam derivatives, the cause of death was determined to be acute intoxication from flunitrazepam and triazolam.     

Detection of S-methylfenitrothion, aminofenitrothion, aminofenitroxon and acetylaminofenitroxon in the urine of a fenitrothion intoxication case

A 23-year-old male attempted suicide by ingesting approximately 50 ml of 5% fenitrothion emulsion, and vomited soon afterwards. He was admitted to a hospital about 3 h after ingestion. He recovered and was discharged from hospital 3 days after admission. The serum cholinesterase activity (normal range: 175-440 I.U.) was only 29 at 3 h, 32 at 1 day, 59 at 2 days and 75 at 3 days after ingestion. Fenitrothion and its metabolites in the body fluids were extracted by an Extrelut column extraction method, detected by a gas chromatograph equipped with either a hydrogen flame ionization detector or a flame photometric detector, and confirmed by a gas chromatograph-mass spectrometer. Fenitrothion concentration in the blood was 169.5 ng/g at 3 h after ingestion. The half life of blood fenitrothion concentration was found to be about 4.5 h. Fenitrothion metabolites, 3-methyl-4-nitrophenol, aminofenitrothion, aminofenitroxon, acetylaminofenitroxon and S-methylfenitrothion, were detected in the urine samples. All of them except S-methylfenitrothion were detected in the urine samples collected up to 62 h after ingestion. It would appear therefore that fenitrothion poisoning can be determined by detection and analysis of the metabolites in urine even if fenitrothion has not been detected in the blood.     

Forensic-medical diagnostic implication of morphine levels in the blood and urine

Toxicological characteristics are presented for 198 cases of acute parenteral poisoning with morphine and heroin. The range of their metabolites concentration in the blood and urine encountered in practice are analysed. Principal causes of death due to opiate poisoning in inpatients are shown. Opiates toxicity was assessed by the method of logit-regression and dose-effect curves for analysis of probability of death depending on opiate metabolite concentration in blood and urine. Relations between probability of death and detection of morphine in biological media of the victims are considered. Morphine concentrations in the blood and urine undoubtedly indicating morphine poisoning are determined.     

血液和尿液样品中海洛因代谢物稳定性研究

目的对尿液和血液中海洛因代谢物3-β-D-葡萄糖醛酸吗啡（M3G）,吗啡,O6-单乙酰吗啡（O6）在180d内的稳定性进行研究。方法准备空白添加血液、尿液、染毒动物（大白兔）血液、尿液和吸食海洛因者血液、尿液样本,分别置于20℃、4℃、-20℃下,分别于0、1、2、4、7、14、28、56、112、156、180d时间点测定样品中M3G、吗啡,O6相对含量。结果在3种不同温度下,随保存时间的延长,血液、尿液中的O6含量均逐渐下降至零;血液中吗啡含量升高（空白血液添加组）或下降（染毒动物组）,在尿液则均升高;血液样中M3G含量均升高,尿样中则略有下降。下降和升高的幅度均随保存温度的下降而缩小。结论海洛因代谢物在-20℃时保存稳定性最佳。     

Benzodiazepine findings in blood and urine by gas chromatography and immunoassay

Gas chromatography (GC) and immunoassay techniques applied to blood and urine specimens were compared for the screening of benzodiazepines in postmortem forensic toxicology. Five hundred and six such successive postmortem cases in which both urine and peripheral blood was sent for toxicological analysis by the medical examiners were selected. The urine specimens were tested by the Emit((R)) d.a.u. Benzodiazepine Assay, and in parallel, the blood and urine specimens were screened for benzodiazepine drugs and their metabolites by an established automated dual-column GC method. The lowest number of positives (153) was obtained when immunoassay was performed without enzyme hydrolysis. When urine samples were hydrolysed before immunoassay, the number of positives increased to 175. The highest number of positives (200) was obtained in urine by GC, and the screening of blood by GC yielded 185 quantitative results. Despite the urine GC screening produced the most positives, the quantitative screening of the blood by GC appears to be the most efficient approach in postmortem forensic toxicology, considering the fact that although urine findings confirm the presence of the drug, quantitative results in urine are irrelevant to acute toxicity.     

Time of drug elimination in chronic drug abusers. Case study of 52 patients in a "low-step" detoxification ward

The elimination time of illicit drugs and their metabolites is of both clinical and forensic interest. In order to determine the elimination time for various drugs and their metabolites we recruited 52 volunteers in a protected, low-step detoxification program. Blood samples were taken from each volunteer for the first 7 days, daily, urine sample for the first 3 weeks, daily. Urine was analyzed using a fluorescence-polarization immunoassay (FPIA) and gas chromatography/mass spectrometry (GC/MS), serum using GC/MS. The elimination times of the drugs and/or their metabolites in urine and serum as well as the tolerance intervals/confidence intervals were determined. Due to the sometimes extremely high initial concentrations and low cut-off values, a few of the volunteers had markedly longer elimination times than those described in the literature. The cut-off values were as follows: barbiturates II (200ng/ml), cannabinoids (20ng/ml), cocaine metabolites (300ng/ml), opiates (200ng/ml). GC/MS detected the following maximum elimination times: total morphine in urine up to 270.3h, total morphine and free morphine in serum up to 121.3h, monoacetylmorphine in urine up to 34.5h, 11-nor-9-carboxy-delta-9-tetrahydrocannabinol (THC-COOH) in urine up to 433.5h, THC-COOH in serum up to 74.3h, total codeine in urine up to 123h, free codeine in urine up to 97.5h, total codeine in serum up to 29h, free codeine in serum up to 6.3h, total dihydrocodeine (DHC) in urine up to 314.8h, free DHC in urine up to 273.3h, total and free DHC in serum up to 50.1h. Cocaine and its metabolites were largely undetectable in the present study.     

The detection of 6-monoacetylmorphine in urine, serum and hair by GC/MS and RIA

6-Monoacetylmorphine (6-MAM) is a good indicator for the intake of heroin and can be detected in blood, urine and hair of heroin users. A new radioimmunoassay (RIA) designed specifically for 6-monoacetylmorphine (6-MAM) was tested for its usefulness for the quantitation of the drug in urine, serum and hair. Its cross-reactivity with heroin and its metabolites, and related compounds was also determined. Eighty-nine hair, six serum and 25 urine samples where 6-MAM had been previously identified by GC/MS were analysed for 6-MAM with the new RIA kit. A good correlation existed between the GC/MS and RIA results for the hair samples. However, the amount of 6-MAM found in serum and urine differed considerably between the two methods. This difference could be explained by the cross-reactivity of the antibody with morphine and morphine-6-glucuronide, which are present in much larger amounts in serum and urine, than in hair. To evaluate a new rationalisation procedure, some hair samples were split into two portions after incubation. One part was analyzed for 6-MAM by RIA, and the other portion by GC/MS.     

Determination of a newly encountered designer drug "p-methoxyethylamphetamine" and its metabolites in human urine and blood

A newly synthesized designer drug, para-methoxyethylamphetamine (PMEA) was unexpectedly detected in the postmortem specimens of fatality involving drug intoxication in 2005, Japan. For unequivocal identification, the isomeric discrimination of PMEA and its positional-isomers was performed by GC/MS with the trifluoroacetylation. In order to prove the intake of PMEA, the characteristic metabolites of PMEA were also identified by GC/MS analysis of the urine specimen with trifluoroacetylation. As a result, para-methoxyamphetamine, para-hydroxyethylamphetamine (POHEA) and para-hydroxyamphetamine were identified as the major metabolites of PMEA. For the quantitative analyses of PMEA and its three metabolites in body fluids, an automated column-switching LC/MS procedure was developed, and applied to the postmortem blood and urine specimens. In this fatal case, blood concentration of PMEA was estimated to be 12.2 microg/mL and this level seemed extremely high in comparison with lethal blood-levels of its analogues, representing acute-intoxication of the victim. Based on the quantitative results, PMEA was found to be extensively metabolized to POHEA via O-demethylation, partly followed by its conjugation.     

A fatal poisoning with 5-methoxy-N,N-diisopropyltryptamine, Foxy

A fatal overdose involving case by 5-methoxy-N,N-diisopropyltryptamine (5-MeO-DIPT) is reported. 5-MeO-DIPT and its two metabolites, 5-hydroxy-N,N-diisopropyltryptamine (5-OH-DIPT) and 5-methoxy-N-isopropyltryptamine (5-MeO-NIPT), were identified by LC-MS. The level of 5-MeO-DIPT, 5-OH-DIPT and 5-MeO-NIPT in blood and urine was 0.412, 0.327 and 0.020 microg/ml, and 1.67, 27.0 and 0.32 microg/ml, respectively. These blood and urine levels were higher than published data for such poisoning.     

Volatile substance abuse--post-mortem diagnosis

A substantial number of children and adolescents world-wide abuse volatile substances with the intention to experience an euphoric state of consciousness. Although the ratio of deaths to nonfatal inhalation escapades is low, it is an important and preventable cause of death in young people. In the analytical investigation of volatile substances proper sample collection, storage and handling are important in view of the volatile nature of the compounds. Volatile organic compounds in post-mortem matrices such as blood, urine and tissues are generally determined by gas chromatography after extracting the compounds with methods such as static and dynamic headspace or even with pulse-heating and solvent extraction. In post-mortem cases, metabolites in urine seem less relevant, however, trichloroethanol and trichloroacetic acid were determined in several cases. When interpreting qualitative and quantitative results, researchers should be aware of false conclusions. The main reason why scepticism is necessary is the occurrence of losses of analytes during sampling, sample handling and storage, which results in false quantitation.     

苯并二氮类药物及其主要代谢物的薄层色谱分析

目的建立饮料、血、尿中 11种常见苯并二氮类药物及尿中 7种主要代谢物的薄层色谱分析法(HPTLC)。方法分析物采用GDX10 1树脂进行固相萃取 ,乙醚作为洗脱溶剂。苯 :丙酮 (10∶6)等作为展开体系 ,改良碘化铋钾显色。结果所建方法绝对灵敏度 0 3～ 0 6μg,尿检出限 0 4～ 1 0 μg/ml、血检出限 0 6～ 1 0 μg/ml、饮料检出限 0 4～ 0 8μg/ml。结论HPTLC法简便、快速 ,适合作为常规毒物分析方法     

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.     

氯硝安定在生物体内的代谢

目的推测氯硝安定在生物体内的主要代谢方式,检测其代谢产物。方法取5只Wistar大鼠,连续3d给每只大鼠灌胃氯硝安定（剂量分别为1、2、2mg）,收集灌胃后24h内尿液;给3只大鼠各灌胃2mg氯硝安定,2h后处死,取血液和肝组织等检材;收集3名口服5mg氯硝安定的志愿者24h内尿液。分别对不同检材进行处理后,气相色谱/质谱联用（GC/MS）检测。结果在大鼠阳性尿液和志愿者阳性尿液中,均检出7-乙酰氨基氯硝安定和7-氨基氯硝基安定;在大鼠血液中,主要检出氯硝安定和7-氨基氯硝基安定;在大鼠肝组织中,主要检出7-乙酰氨基氯硝安定,还有少量7-氨基氯硝安定和氯硝安定。结论氯硝安定进入生物体后,其7位硝基被还原为氨基,氨基接着被乙酰化,形成7-氨基氯硝基安定和7-乙酰氨基氯硝安定代谢物,其中7-乙酰氨基氯硝安定为主要代谢物。     

Profiles of delta 9-tetrahydrocannabinol metabolites in urine of marijuana users: preliminary observations by high performance liquid chromatography-radioimmunoassay

Metabolic profiles of 11-nor-9-carboxylic acid-delta 9-tetrahydrocannabinol (COOH-THC) and other THC metabolites were determined in an infrequent and a frequent marijuana user by high performance liquid chromatography-radioimmunoassay (HPLC-RIA). In the infrequent user, no unconjugated COOH-THC was detected in urine samples for the first 8 h following smoking, whereas this metabolite was detected in the urine samples from a frequent user. A metabolite was also detected in the frequent user, which was not present in the urine sample from the infrequent user.     

Bupropion and alcohol fatal intoxication: case report.

A fatality due to the ingestion of bupropion and ethanol is presented. Bupropion and its metabolites were extracted from several tissues and identified using gas chromatography with nitrogenphosphorus and mass spectrometry detection. The concentrations of bupropion, hydroxybupropion and the erythroamino and threoamino alcohol metabolites in heart blood were 4.2, 5.0, 0.6 and 4.6 mg/l, respectively. The heart blood ethanol concentration was 0.27 g/dl. In addition, bupropion was distributed as follows: subclavian blood, 6.2 mg/l; bile, 1.4 mg/l; kidney, 2.4 mg/l; liver, 1.0 mg/kg; stomach contents, 16 mg and urine, 37 mg/l.     

尿中地西泮及其代谢物的气相色谱电子捕获检测法分析

目的　建立尿中地西泮及其代谢物替马西泮、去甲西泮和奥沙西泮的GC/ECD分析方法。方法　尿样经β 葡萄糖醛酸酶水解后 ,用有机溶剂提取 ,再以N ,O 双三甲硅烷基三氟乙酰胺进行衍生化 ,衍生物用GC/ECD法分析。结果　检材中分析物的回收率 70 %以上 ,检出限 5ng/ml以下。结论　本法可进行口服地西泮 10mg人体 48h内尿液中地西泮代谢物的分析。     

Detection of drugs of abuse in simultaneously collected oral fluid, urine and blood from Norwegian drug drivers

Blood and urine samples are collected when the Norwegian police apprehend a person suspected of driving under the influence of drugs other than alcohol. Impairment is judged from the findings in blood. In our routine samples, urine is analysed if morphine is detected in blood to differentiate between ingestion of heroin, morphine or codeine and also in cases where the amount of blood is too low to perform both screening and quantification analysis. In several cases, the collection of urine might be time consuming and challenging. The aim of this study was to investigate if drugs detected in blood were found in oral fluid and if interpretation of opiate findings in oral fluid is as conclusive as in urine. Blood, urine and oral fluid samples were collected from 100 drivers suspected of drugged driving. Oral fluid and blood were screened using LC-MS/MS methods and urine by immunological methods. Positive findings in blood and urine were confirmed with chromatographic methods. The analytical method for oral fluid included 25 of the most commonly abused drugs in Norway and some metabolites. The analysis showed a good correlation between the findings in urine and oral fluid for amphetamines, cocaine/benzoylecgonine, methadone, opiates, zopiclone and benzodiazepines including the 7-amino-benzodiazepines. Cocaine and the heroin marker 6-monoacetylmorphine (6-MAM) were more frequently detected in oral fluid than in urine. Drug concentrations above the cut-off values were found in both samples of oral fluid and urine in 15 of 22 cases positive for morphine, in 18 of 20 cases positive for codeine and in 19 of 26 cases positive for 6-MAM. The use of cannabis was confirmed by detecting THC in oral fluid and THC-COOH in urine. In 34 of 46 cases the use of cannabis was confirmed both in oral fluid and urine. The use of cannabis was confirmed by a positive finding in only urine in 11 cases and in only oral fluid in one case. All the drug groups detected in blood were also found in oral fluid. Since all relevant drugs detected in blood were possible to find in oral fluid and the interpretation of the opiate findings in oral fluid was more conclusive than in urine, oral fluid might replace urine in driving under the influence cases. The fast and easy sampling is time saving and less intrusive for the drivers.     

SPE-GC／MS法检测大鼠尿中尼美西泮及其代谢物

目的检测尼美西痒阳性大鼠尿液中的代谢物。方法2只Wistar大鼠分别喂食半粒尼美西泮药丸，收集24h内尿液，用B葡萄糖醛酸酶水解，Oasis@HLB柱固相提取，以DB．35Ms柱为分离柱，气相色谱质谱联用法检测。结果从大鼠尿液中检出尼美西泮的4种代谢物：7-乙酰氨基尼美西泮、7-乙酰氨基硝基安定、7-氨基尼美西泮和2-氨基-5-硝基苯基苯甲酮及少量尼美西泮原体。结论尼美西泮在大鼠体内易代谢，在尿液中的主要代谢物为7-乙酰氨基尼美西泮和7-乙酰氨基硝基安定。