乌头急性中毒死亡者乌头生物碱的体内分布

目的研究乌头急性中毒死亡者体液和组织中乌头生物碱的分布．为乌头中毒案的法医学鉴定取材和结果评价提供参考。方法用液相色谱一串联质谱法测定中毒死亡者体液和组织中乌头生物碱的含量。结果乌头碱在死者体液和组织中的含量从大到小依次为尿液、胆汁、胃内容物、心血、胰、心、肠、肝、肾、胃、肺、胆囊、脾，脑中未检出。结论尿液、胆汁和血液是检测体内鸟头生物碱的较佳检材。     

γ-羟基丁酸在急性中毒大鼠体液和组织中的检测及分布

目的建立生物检材中γ-羟基丁酸(GHB)的检测方法,研究GHB急性中毒大鼠体内GHB的分布,为GHB中毒的鉴定提供方法和评价依据。方法用GC/MS法检测生物检材中的GHB;以1000mg/kg剂量给大鼠灌胃使其染毒,分别于1h和3h处死,测定体液和组织中GHB的含量。结果测组织中内源性GHB的线性范围是1～20μg/g,R2=0.9974;测组织中外源性GHB的线性范围为100～1500μg/g,R2=0.9958。相对回收率为98%～103%。体内内源性GHB的含量均≤10μg/mL或10μg/g。尿液中GHB含量为最高,其他依次为:胃、血液、肠、肾、肺、脾、心、肝和脑。结论所建方法准确、便捷,适用于GHB中毒的鉴定;尿液是体内检测GHB的最佳检材。     

甲基苯丙胺及其代谢产物在急性中毒豚鼠体内的分布

目的研究甲基苯丙胺 (MAP)及其代谢产物苯丙胺 (AP)在急性中毒豚鼠体内的含量分布。方法应用GC/NPD技术 ,以 4 苯基丁胺 (4 PBA)为内标 ,样品经水解后碱化或直接碱化至pH >11,环已烷混旋提取 ,三氟乙酸酐 (TFA)微波衍生化 ,测定MAP急性中毒豚鼠体液和组织中MAP及AP的含量。结果急性中毒死亡豚鼠体内各器官和体液中MAP及AP含量最高为肺 ;其次为肝、脑、肾、脾、肠、心、血 ;再次为胃、胆汁 ;最少是尿。结论MAP在动物体内代谢迅速 ,组织或体液中MAP和AP浓度的比值与豚鼠给药后存活时间有关     

曲马多在急性中毒大鼠体内的分布

目的建立一种快速、准确的气相色谱分析方法,研究曲马多在急性中毒大鼠体内的分布,为曲马多中毒案的法医学鉴定取材和结果评价提供参考。方法以1140mg/kg(5×LD50)剂量曲马多对大鼠灌胃染毒,运用气相色谱法检测其体液和组织中曲马多的浓度。结果血液、尿液中曲马多的检出限为0.1μg/mL,肝中的检出限为0.1μg/g。方法的日内及日间精密度分别在3.1%和5.5%以内,血液中曲马多的回收率在98%以上。曲马多在急性中毒大鼠体液和组织中的含量从高到低依此为心血、肝、外周血、尿液、玻璃体液、肾、肺、脾、心、大脑。结论所建方法能够满足体内毒物分析的要求,血液、尿液、肝、肺和肾均可作为体内曲马多分析的良好检材。     

氯胺酮在家兔死后体内的弥散研究

目的研究氯胺酮在大白兔体内死后弥散过程和再分布机制。方法 48只实验大白兔随机分为8组,采用缺氧处死后以150mg/kg氯胺酮灌胃,尸体仰卧位于室温下放置;在0~96h内分8个时间点各解剖1组,提取体液和脏器组织样品;采用GC/MS法定性结合GC-NPD法定量检测样品中氯胺酮含量,并计算心血/外周血中氯胺酮含量的比值。结果大白兔死后氯胺酮灌胃尸体放置96h内,脑、尿液、玻璃体液、左上/下肢肌肉样本中均未检测到氯胺酮,心血、外周血、心肌、脾、肾、肝、肺、胆汁中氯胺酮含量随死后时间呈动态升高的变化;其中距离胃较近的组织(如脾)较早检测到含量较高的氯胺酮,而距离较远的组织或体液中氯胺酮含量较低且较晚检测到;心血/外周血中氯胺酮含量比值为1.73。结论氯胺酮在家兔体内存在死后再分布,从胃到器官组织、心血顺浓度梯度弥散是主要机制。脑、玻璃体液、尿液、肢体肌肉不受死后弥散的影响,可作为生前服毒与死后染毒氯胺酮的鉴别依据。     

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。     

芬太尼中毒死亡大白兔体内分布研究

目的建立芬太尼中毒致死的动物模型,探讨芬太尼在致死大白兔体内的分布规律。方法用6只雄性大白兔按5.4mg/kg(2LD50)经耳缘静脉推注芬太尼注射液,大白兔死后迅速解剖并提取心、肝、脾、肺、肾、脑、肌肉、睾丸、胃、心血、周围血、胆汁和尿液,用正己烷∶乙醇(20∶1)萃取,利用UPLC-MSn法检测各组织和体液中芬太尼含量,使用SPSS15.0进行方差分析,均数两两比较的SNK法进行统计分析。检验水准为α=0.05。结果实验大白兔给药后1min出现颈项强直、四肢抽搐等中毒症状,平均4.7min因呼吸抑制而死亡。死后肺内芬太尼含量最高,其次是肾和心,而尿液中含量较低。结论本实验的结果与相关案例报道基本吻合,提示肺、肾和心脏是芬太尼中毒案件鉴定的理想检材,芬太尼在致死大白兔体内的分布规律可为相关案件的鉴定提供一定的依据。     

甲胺磷在犬体内的死后分布

目的建立甲胺磷的犬灌胃染毒致死模型,观察甲胺磷在犬体内的死后分布规律。方法犬经8倍LD50（7.4mg/kg）剂量甲胺磷灌胃后,观察其中毒症状,死亡后即刻解剖,分别取心、肝、脾、肺、肾、脑、右上肢肌、右下肢肌、胸肌、胃组织、心血、胆汁、玻璃体液和尿液,GC/MS和GC法检测其中甲胺磷含量。结果犬8倍LD50甲胺磷灌胃染毒后20min内出现中毒症状（,53.3±14.1）min死亡。各组织脏器及体液中甲胺磷含量由高到低分别为胃（99.84±0.87）μg/g、脾（46.87±28.67）μg/g、肝（43.82±22.74）μg/g、肾（43.79±29.04）μg/g、心血（35.36±13.98）μg/mL、肺（35.25±18.59）μg/g、尿34.81μg/mL、胸肌（19.23±17.18）μg/g、右上肢（16.92±8.98）μg/g、心（15.09±6.11）μg/g、右下肢（12.83±7.63）μg/g、脑（10.91±4.13）μg/g、胆汁（6.75±1.45）μg/mL、玻璃体液（6.22±4.97）μg/mL。结论甲胺磷在犬体内死后分布不均,胃、脾、肝、肾、心血、肺、尿检材中含量较高,可作为疑似甲胺磷中毒毒物分析的检材。     

液相色谱-串联质谱法测定血液和尿液中秋水仙碱

目的建立检测血液和尿液中秋水仙碱的液相色谱-串联质谱法。方法0.5mL血液或尿液以丁丙诺啡为内标,经pH9.2硼酸盐缓冲溶液碱化后,用乙酸乙酯进行提取,在ZORBAX SB-C18液相柱(150mm×2.1mm×5μm)上以V(甲醇)∶V(20mmol/L乙酸铵和0.1%甲酸缓冲溶液)=80∶20为流动相,流速为0.2mL/min,采用电喷雾正离子模式离子化、多反应监测模式检测秋水仙碱,内标法定量。结果血液、尿液中秋水仙碱与内标丁丙诺啡色谱分离良好,秋水仙碱在0.1~50 ng/mL内均具有良好的线性,相关系数>0.9990,最低检出限为0.05ng/mL,方法回收率为94%~116%,日内与日间精密度(RSD)均小于8.5%。结论所建LC-MS-MS方法灵敏度高、操作简便、快速、准确,适用于血液及尿液等生物检材中痕量秋水仙碱成分的检测。     

溴敌隆及其代谢物-苄叉丙酮在犬体内的死后分布

目的研究溴敌隆及其代谢物-苄叉丙酮在中毒致死犬体内死后分布规律,为溴敌隆中毒检材的采取提供实验依据。方法分别经口给予犬2倍和4倍LD_(50)溴敌隆,待其死亡后迅速解剖取材,气相色谱-质谱联用法测定心血、外周血、尿、胆汁、心、肝、脾、肺、肾、脑、左下肢肌、膀胱、胃、胃内容、胰等脏器和体液中溴敌隆和代谢物-苄叉丙酮的含量。结果犬经2倍和4倍LD_(50)溴敌隆灌胃染毒后3d开始出现出血症状,(178.40±20.94)h后死亡。溴敌隆和代谢物-苄叉丙酮在各组织脏器及体液中的死后分布为:溴敌隆2LD_(50)组溴敌隆:胆汁尿、肝、心、肾心血、外周血、脾、肺等;苄叉丙酮:胆汁、尿、心血、外周血、肺、胃内容中含量高于其他脏器。溴敌隆4LD_(50)组溴敌隆:胆汁、尿肝、外周血心血、胃内容物等脏器。苄叉丙酮:胆汁、尿、肺浓度高于其他脏器。结论溴敌隆及其代谢物-苄叉丙酮在中毒致死犬体内死后分布不均匀,溴敌隆在胆汁、尿、肝脏、心血和外周血含量较高,代谢物-苄叉丙酮在胆汁、尿、肺较高。胆汁、尿、肝脏、心血、外周血可作为疑似溴敌隆中毒毒物分析的检材。     

Colchicine poisoning: case report of two suicides

Colchicine overdose is uncommon but potentially life threatening because of the high toxicity of the drug. Poisoning by colchicine may occur following ingestion of medication used in acute attacks of gout and inflammatory diseases. We describe two cases involving suicide by the ingestion of medications marketed in France. In case 1, only heart blood was taken after body external examination. In case 2 an autopsy was performed and heart blood, urine, gastric contents and bile were taken for toxicological analysis. Colchicine was assayed in biological specimens by an HPLC-DAD method, after extraction by dichloromethane at pH 8, adding prazepam as internal standard (IS). Analyses were performed on a Symetry C-8 column. Mobile phase was a gradient of acetonitrile/pH 3.8 phosphate buffer. Colchicine is eluted at 13.1 min and the method is linear for blood, urine and bile over the range 4-1000 ng/mL. LOQ is 4 ng/mL. The concentrations of colchicine detected are: case 1: heart blood 13 ng/mL; case 2: heart blood 66 ng/mL, urine 500 ng/mL, gastric content 12 ng/mL, bile 5632 ng/mL. Our findings are in the range of lethal concentrations previously described, but there is no correlation with the amount of ingested drug. Even after massive overdose, it could be impossible to detect colchicine in blood, and as there is a widespread enterohepatic recirculation before excretion in bile and feces, bile is the target sample to analyse. We conclude in both cases that the cause of death was suicide with colchicine. It appears very important to perform an autopsy in order to obtain bile, urine, heart blood and femoral blood.     

体液中微量士的宁的富集及同时检测

目的将分子印迹技术运用到法医毒物分析中,建立一种全新的测定体液中微量士的宁的方法。方法运用分子印迹原位聚合技术,在色谱柱中一步合成了对士的宁具有专属识别能力的分子印迹聚合物,以此聚合物为介质,装填一厘米的小柱,建立体液中微量士的宁的富集及同时检测方法。结果以士的宁分子印迹聚合物作为尿液和血浆中微量士的宁的富集和检测介质,方法的检出限为4.9ng,样品回收率均大于92%,相对标准偏差小于6.59%,工作曲线的线性相关系数分别为0.9991和0.9966。运用此方法对中毒家兔血浆和尿液中的士的宁进行了测定。结论建立的新方法可以实现对士的宁专属的、灵敏的检测,适合于法医学毒物分析运用。     

Identification and quantitation of xenobiotics by 1H NMR spectroscopy in poisoning cases

In order to analyse a wide range of xenobiotics and their metabolites present in biological fluids, NMR spectroscopy can be used. A large variety of xenobiotics (therapeutic agents, pesticides, solvents, alcohols) can be characterized and quantitated directly, without sample preparation. NMR investigations were applied to acute poisoning cases, involving drugs such as salicylates and valproic acid (VPA). In a salicylate poisoning case, the three major metabolites of acetylsalicylic acid have been detected in crude urine, and rapid identification of lysine revealed the origin of the intoxication, namely lysine acetylsalicylate (Aspegic). Valproic acid as its glucuronide was identified in urine samples from two poisoned patients. 1H NMR was also used to identify and quantitate paraquat (Gramoxone) in urine owing to its two aromatic signals at 8.49 and 9.02 ppm, in two acutely poisoned patients (183 and 93 mg/l). An intentional poisoning case with tetrahydrofuran (THF) was also investigated. Serum and urine samples were collected. THF was characterized by its resonances at 1.90 and 3.76 ppm, and quantified at 813 and 850 mg/l in the two biological fluids, respectively. Moreover, two other compounds were detected: lactate and gamma-hydroxybutyric acid (GHB). 1H NMR spectroscopic analysis of serum samples from three poisoned patients revealed methanol in one case and ethylene glycol in the two others. Moreover, in the same spectrum, the corresponding metabolites formate and glycolate were found. Compared with the reference chromatographic or spectrophotometric methods, requiring time-consuming extraction and/or derivatization steps, NMR spectroscopy allows the determination of many exogenous and endogenous compounds, without any pre-selection of the analytes.     

三种安定类药物在中毒家兔体内的分布研究

为探求安定类药物在急性中毒家兔体内的代谢分布，采用固相萃取法和HPLC同时测定氯硝安定、佳静安定和安定。家兔按一定剂量将三种药物同时灌胃造成急性中毒2小时，处死后测定血、胆汁、尿液及其它脏器的三种药物浓度。结果表明，氯硝安定在胆汁和尿中含量较高，为0．82μg／ml和0．68μg／ml，而佳静安定及安定在胆汁和肝中浓度高，分别为9．32μg／ml和13．81μg／g。提示三种药物在家兔体内分布既有相同点也有显著差别。因此，利用本方法既可同时测定三种不同药物，也可为法医检案中毒案例的最佳检材采取和毒物分析结果评价提供了科学依据。     

Chlorobutanol poisoning. Report of a fatal case.

A fatal chlorobutanol intoxication is reported and a gas chromatographic method for the determination of this drug in human fluids and tissues is described. Analytical findings for blood, urine, stomach contents, bile, liver, kidney, spleen, and brain are reported.     

Fatal colchicine poisoning

In two cases, after i.v. injections of colchicine serum concentrations of 170 ng/ml and 240 ng/ml were found before death. Colchicine was extracted from serum with the aid of Extrelut extraction columns and analysed using HPLC. Urine was also analysed and the findings were confirmed by drawing a UV-curve for colchicine using the stop-flow method. In one case, colchicine was still detectable in urine 10 days after injection.