腐败生物检材中多种碱性滥用药物的检测

目的建立腐败生物检材中多种碱性滥用药物的提取、净化和仪器分析方法。方法用环己烷作为提取溶剂液-液萃取,同时采用Bond Elut Certify小柱、甲醇淋洗、二氯甲烷：异丙醇：氨水（78：20：2）洗脱固相萃取分离提取,GC／MS、GC／NPD定性定量分析各种生物检材中的滥用药物。结果从所送死者肝组织、胃组织、心血及胃内容、尿样、各检材中均同时检出吗啡、可待因、舒乐安定和异丙嗪成份,其中肝组织含量分别为吗啡0．094μg／g、可待因0．257μg／g、异丙嗪0．110μg／g,尿液含量分别为吗啡0．334μg／ml、可待N4．054μg／ml、异丙嗪0．066μg／ml,心血含量分别为吗啡0．036μg／ml、可待N0．106μg／g、异丙嗪0．088μg／ml。结论此方法准确、可靠、科学,可以用于法医毒物分析领域体内检材多种碱性药物的检测。     

GC/MS研究海洛因代谢物在吸毒者体内的分布

应用GC／MS－SIM测定了海洛因代谢物吗啡在两例海洛因延缓死亡者的体内分布,并分析了收集到的7例案子的毛发（头发、腋毛和阴毛）中6-单乙酰吗啡和吗啡含量。生物检材和毛发经酸水解、提取、醋酸酐或双（三甲基硅基）三氟乙酰胺（BSTFA）衍生化,然后进行GC／MS-SIM分析。结果表明尿、胆汁和肝脏是判定死者是否曾使用海洛因的最佳检材;毛发分析与生物检材相比有其独特的优点,可提供数月甚至数年的用药情况。为公安司法机关打击吸毒、惩治犯罪提供更可靠、有效的证据。     

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     

生物体液中吗啡的提取方法研究

介绍了血和尿两种生物体液中吗啡的固相提取方法。采用衍生化气相色谱法作为测试手段。系统考查了５种国产和进口固相萃取剂、３种洗脱剂及提取ｐＨ值对尿和血中吗啡提取率的影响。实验结果表明：国产ＧＤＸ－３０１、ＧＤＸ－４０３和进口Ｃ１８等固相萃取剂均对吗啡有较好的提取行为;氯仿：异丙醇（９：１）对固相萃取剂上的吗啡有较强的洗脱行为;若采用ＧＤＸ－３０１为固相萃取剂,尿中吗啡在ｐＨ值为９左右时,提取率可达９０％以上,而后提取率随ｐＨ值提高下降;血中吗啡随ｐＨ值提高,提取率提高,在强碱状态下,提取率可达９０％以上     

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。     

生物检材中阿维菌素的HPLC—MS／MS分析

目的建立生物检材包括血、肝组织、胃组织中阿维菌素（Avermectins）的HPLC—MS／MS分析方法。方法采用Oasis HLB固相萃取柱进行提取,以XTerra^TM RP18柱（2．1mm×100mm,3．5μm）色谱柱分离,以甲醇-0．1％冰醋酸水溶液（75：25）为流动相,流速为0．2mL／min。结果线性范围10ng／mL～3μg／mL,最小检出限为0．1ng／mL。结论本方法准确、快速,可用于生物检材血中阿维菌素的定性定量分析,肝及胃组织中阿维菌素的定性分析。     

内标法固相提取-GC/MS检测海洛因吸食者尿液中代谢物

本文建立了以SKF-525A作内标、GDX－301作固相提取剂、用GC／MS方法测定海洛因吸食者尿液中代谢物浓度的方法。系统考查了吗啡、单乙酰吗啡的提取回收率、线性关系等指标。所建立的方法对吗啡和单乙酰吗啡的回收率均大于80％;最小检测浓度小于0.1μg／ml;用代谢物特征离子与内标物特征离子峰高比法测定吗啡与单乙酰吗啡的浓度,在每ml尿添加0．25μg～250μg范围内,二者均有良好的提取线性关系。并对几例海洛因滥用者的尿液进行了检测。     

阿片类成瘾者血清、尿中吗啡TLCS分析

建立阿片类成瘾者血清、尿液中吗啡的薄层色谱扫描 (TCLS)定量检测方法。样品经酸、碱性水解后调至pH9,氯仿 /异丙醇 ( 9∶1)萃取及GDX 40 3柱固相萃取 ,在紫外区可见光区薄层扫描。测得 3种萃取方法吗啡回收率分别为 75 3 %± 4 9% ,80 9%± 3 2 %和 79 4%± 3 5 % ,血清、尿中吗啡最低检出浓度分别为 0 1μg·ml-1,0 0 5 μg·ml-1(信噪比≥ 3 )。本法可用于阿片类药物成瘾者或中毒者血、尿中吗啡的检测。     

曲马多在家兔体内的死后分布研究

目的研究曲马多在中毒家兔体内死后分布规律,为曲马多中毒检材采取提供实验依据。方法家兔经口给予10倍LD50曲马多,待家兔死亡后迅速解剖取样,气相色谱／质谱联用和气相色谱-FTD法测定其体液、脏器、大脑及右上肢和右下肢肌肉中曲马多的含量,比较其变化规律。结果血液和肝脏中曲马多的最低检出限分别为0．05μg/mL和0．05μg/g,提取回收率为97．60％±0．65％～103．10％±1．24％。曲马多在家兔体内的死后分布为：肾〉胃〉肝〉脾〉肺〉脑〉心〉上肢肌肉〉下肢肌肉〉〉体液（尿〉胆汁、心血〉玻璃体液）。结论大剂量曲马多中毒致死后在体内分布不均匀,组织中曲马多含量明显高于心血、胆汁等体液。     

HPLC法测定百草枯急性中毒大鼠的体内分布

目的 应用高效液相色谱法对口服百草枯急性中毒大鼠体内分布进行测定。方法以200mg／kg剂量百草枯给予Wister大鼠灌胃,4h后脱臼处死,解剖取脑、心、肝、脾、肺、肾、胃、盲肠、肌肉等组织,应用固相萃取法提取,液相色谱法测定各器官组织中百草枯含量。结果各组织经检验,均检出百草枯;组织间百草枯含量（μg／g）相差明显,其中最高为胃（231．47±129．10）,其次为盲肠（87．08±39．86）、肺（22．73±10．20）,最低为心（2．01±0．36）。结论百草枯口服给药后组织分布较为广泛,除胃、肠外各脏器中以肺浓度最高。     

生物检材中吗啡类生物碱的LC-MS／MS分析

目的针对滥用药物分析鉴定实践中亟待解决的问题,开展LC-MS/MS分析生物检材中吗啡类生物碱的应用研究。方法满足不同的鉴定需要,分别建立血液、尿液、唾液和头发等生物检材的样品前处理方法,确定同时分析海洛因、单乙酰吗啡、吗啡、可待因、乙酰可待因、二氢可待因酮和氢吗啡酮等吗啡类生物碱的LC-MS/MS方法。将方法应用于实际案例。结果所建立的方法对吗啡类生物碱分离良好。尿液稀释法、尿液提取法和头发中吗啡的最低检测限(LOD)分别为10ng/mL、0.01ng/mL和0.01ng/mg。结论所建立的方法简便、快速、特异性强、灵敏度高。目标物中加入二氢可待因酮和氢吗啡酮扩大了方法的实用范围。     

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。     

Distribution of morphine and morphine glucuronides in body tissue and fluids--postmortem findings in brief survival

An intoxication following administration of morphine, tramadol and atracurium in a suicide case is reported. The route of administration and the amount of the particular drug were known from the investigation of the death scene and the findings of the postmortem examination. Tramadol was present in the gastric contents as well as in blood, liver, kidney and brain samples, whereas the drug could not be detected in muscle. All body fluids and tissues investigated contained morphine as well as its 3- and 6-glucuronides with the exception of muscle tissue. The concentrations of morphine and its glucuronide metabolites were determined by LC/MS following solid phase extraction. Interestingly, the concentration of M6G in brain, liver and kidney were close to the concentration of M3G in the particular tissue. This phenomenon might be explained by a preferential hydrolysis of M3G or by a preferential formation of M6G postmortem. Measurement of morphine and M6G in femoral blood and cerebrospinal fluid may be a useful indicator in rapid deaths.     

A high-throughput urinalysis of abused drugs based on a SPE-LC-MS/MS method coupled with an in-house developed post-analysis data treatment system

A rapid urinalysis system based on SPE-LC-MS/MS with an in-house post-analysis data management system has been developed for the simultaneous identification and semi-quantitation of opiates (morphine, codeine), methadone, amphetamines (amphetamine, methylamphetamine (MA), 3,4-methylenedioxyamphetamine (MDA) and 3,4-methylenedioxymethamphetamine (MDMA)), 11-benzodiazepines or their metabolites and ketamine. The urine samples are subjected to automated solid phase extraction prior to analysis by LC-MS (Finnigan Surveyor LC connected to a Finnigan LCQ Advantage) fitted with an Alltech Rocket Platinum EPS C-18 column. With a single point calibration at the cut-off concentration for each analyte, simultaneous identification and semi-quantitation for the above mentioned drugs can be achieved in a 10 min run per urine sample. A computer macro-program package was developed to automatically retrieve appropriate data from the analytical data files, compare results with preset values (such as cut-off concentrations, MS matching scores) of each drug being analyzed and generate user-defined Excel reports to indicate all positive and negative results in batch-wise manner for ease of checking. The final analytical results are automatically copied into an Access database for report generation purposes. Through the use of automation in sample preparation, simultaneous identification and semi-quantitation by LC-MS/MS and a tailored made post-analysis data management system, this new urinalysis system significantly improves the quality of results, reduces the post-data treatment time, error due to data transfer and is suitable for high-throughput laboratory in batch-wise operation.     

Research of the extraction method of morphine from biological fluids

A solid-phase extraction method of morphine from urine and blood has introduced. The effect of 5 SPE columns, 3 eluents and pH on morphine recovery has been investigated systematically. Derivative GC was used as a method of detection. The result showed that the column and the eluent of such as GDX-301, GDX-403 and C18 chloroform:isopropanol (9:1) had good behaviors to extraction of morphine. When GDX-301 was used as a sorbent, the recovery of morphine from urine was above 90% at pH 9, then went down with the increase of pH. While the recovery from blood was growing with the increase of pH, which reached above 90% in strong alkaline. The extraction method is simple, inexpensive, efficient and reproducible, which provides an effective and practical method to extract morphine and similar illicit drugs from biological fluids.     

Robotic method for the analysis of morphine and codeine in urine.

A totally automated procedure has been developed for the detection and quantitation of morphine and codeine in urine case samples. The samples were initially screened for these drugs by a Syva EMIT Toxicology System (ETS). A Zymate laboratory robotic system confirms positive samples from Syva ETS by performing the hydrolysis, extraction, and derivatization of morphine and codeine. The derivatized morphine and codeine were detected using gas chromatography/mass spectrometry (GC/MS). Enzymatic hydrolysis conditions were experimentally optimized during method development. The automation of these procedures has proven to be reliable and efficient.     

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。     

Acute intoxication with orphenadrine and clozapine.

This report describes a fatal intoxication with two different drugs: clozapine and orphenadrine. A 38-year-old man was found dead in the bedroom of his residence. Near the body were found various empty pharmaceutical boxes, employed in schizophrenic therapy, two of them containing clozapine and orphenadrine. High concentrations of clozapine and orphenadrine detected in blood, urine and gastric content were related to death. These compounds were identified and quantitated by liquid-liquid extraction followed by gas chromatographic/mass spectrometry (GC/MS) analysis.