中毒致死者体内芬氟拉明的GC/NPD,GC/MS法测定

建立了生物检材中芬氟拉明的定性定量分析方法。体液及脏器组织经有机溶剂提取后 ,用GC/MS法进行药物筛选、定性 ,生物检材中的芬氟拉明浓度用4 -苯丁胺作内标、GC/NPD法测定。测得芬氟拉明中毒致死者的血液、尿液、肝等组织中浓度分别为7.8μg/ml、64.2μg/ml、31.3μg/g。并对尸体解剖所见及方法可行性进行讨论     

体液中氟乙酰胺SPE-GC/MS检测

目的　利用GC/MS与固相萃取 (SPE)技术相结合 ,开发血和尿样中氟乙酰胺鼠药的GC/MS定量分析新方法 ,并用于实际案例检测。方法　选择乙酰胺为内标 ,通过比较不同固相柱的萃取效率和不同条件对回收率的影响 ,优化用于血和尿样中氟乙酰胺萃取的固相柱和提取条件 ,利用氟乙酰胺与乙酰胺质谱图的分子离子峰面积之比与氟乙酰胺浓度的定量关系 ,建立血和尿样中氟乙酰胺鼠药的GC/MS定量分析新方法。结果　用硅胶柱萃取 ,峰面积之比与氟乙酰胺浓度在 5 0～ 90 μg/ml范围呈线性关系 ,检测限为 1 0 μg/ml。血样中氟乙酰胺检测的平均回收率达 91 6% ,标准偏差小于 7 3 %。结论　此法对实际样品的测定证明可满足氟乙酰胺鼠药中毒的定性定量要求。     

氟乙酰胺、氟乙酸中毒代谢产物“氟柠檬酸”的GC／MS分析研究

目的　分析研究氟乙酰胺、氟乙酸中毒代谢产物“氟柠檬酸”。　方法　采用家兔分时段喂食氟乙酰胺、氟乙酸和作者合成的“氟柠檬酸” ,然后从家兔组织中提取氟柠檬酸并进行GC/MS分析。　结果　中毒致死的家兔未检出氟柠檬酸成分 ,仅喂食氟柠檬酸致死的家兔体内可检出氟柠檬酸成分。　结论　氟乙酰胺、氟乙酸在动物体内不能代谢成氟柠檬酸。     

顶空气相色谱法测定生物组织中的一氧化碳

本文主要研究用顼空气相色谱法测定生物检材中的一氧化碳。分析一个样品只需三分钟即可完成。本法不但适用于血样检材,而且适用于生物组织,甚至腐败生物检材,对于血液样品的最小检测量为50μl,变异系数为0.023。本文研究的方法已成功地应用于法庭科学一氧化碳中毒案件的检验。并描述了贮存的方法。     

固相萃取技术与GC／MS、GC／NPD结合检验血中毒鼠强

利用GDX-403固相萃取技术对血样直接提取,以咖啡因为内标,对毒鼠强进行GC/MS、GC/NPD分析,毒鼠强回收率65%～80%.并利用GC/NPD高灵敏度,使GC/MS和GC/NPD在检测分析中互补.本方法操作简便、快捷,适合检案要求.     

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。     

埋葬4年的开棺腐败尸体中安定、氯丙嗪等6种安眠药物的检验

本文介绍用SPE提取、GC/MS检验埋葬4年的开棺腐败检材中安定、氯丙嗪等6种安眠药物的新方法.哦     

GC/MS快速测定生物样本中地芬尼多及代谢物

正盐酸地芬尼多,化学名α,α-二苯基-1-哌啶丁醇盐酸盐,又名眩晕停,常用于治疗眩晕症、晕车晕船等[1]。有文献曾报道地芬尼多超剂量致小儿中毒的病例[2]。本文采用GC/MS快速测定法对人体生物检材中地芬尼多进行检测,为同行进行相关检验时借鉴。1样本与检验1.1样本及前处理送检某服用盐酸地芬尼多过量致死者心血、尿液、胃内容物、肝组织样本。其中取心血0.5m L、尿液     

从放置两年的中药残渣中检出钩吻成份

采用气相色谱/氢火焰检测器(GC/FID)和气相色谱/氮磷检测器(GC/NPD)分析方法,从一起放置近两年的投毒案检材:煮过的中药残渣中检出了钩吻成份-钩吻素甲,并应用气相色谱/质谱(GC/MS)分析方法进行了确证检验,同时检出钩吻素子。     

甲氰菊酯在家兔体内的死后分布研究

目的建立甲氰菊酯家兔灌胃染毒致死模型和生物检材中甲氰菊酯的气相色谱和气相色谱-质谱联用检测方法,研究甲氰菊酯在家兔体内的死后分布规律。方法家兔6只,甲氰菊酯经口灌胃染毒,死亡后迅速解剖,取心血、外周血、肝等组织,气相色谱和气相色谱-质谱联用法检测甲氰菊酯含量;部分组织经甲醛固定,HE染色,光镜观察其病理改变。结果家兔染毒后2～3h出现中毒表现,染毒后4.5～8h死亡。气相色谱和气相色谱-质谱联用法均检测到甲氰菊酯。甲氰菊酯在家兔体内死后分布为胃壁（458.92±32.82）μg/g、肾（46.47±6.30）μg/g、肝（35.79±20.11）μg/g、大脑（28.77±10.52）μg/g、心（26.49±4.10）μg/g、脾（22.23±5.37）μg/g、胆汁（10.87±1.42）μg/mL、肺（10.32±0.78）μg/g、周围血（8.14±1.12）μg/mL和心血（8.20±1.83）μg/mL。结论甲氰菊酯的灌胃染毒致死模型、气相色谱和气相色谱-质谱联用检测方法及死后分布规律可应用于甲氰菊酯中毒死亡案件的法医学鉴定及法医毒物动力学研究。     

Comparison of Different Analytical Methods for the Determination of Carbon Monoxide in Postmortem Blood

The determination of carbon monoxide (CO) and carboxyhemoglobin (COHb) is of utmost importance in forensic toxicology to determine the cause of death in cases of CO poisoning, fire, and explosions. To this end, reliable and updated analytical methods are required. In this paper, four different methods for the determination of carbon monoxide in postmortem blood samples were compared: (i) the spectrophotometric determination of COHb applying the method proposed by Rodkey and modified by Beutler–West, (ii) the spectrophotometric determination of CO using a micro-diffusion-based method, (iii) the determination of CO by gas chromatography coupled to a TCD detector, and (iv) the determination of COHb by blood gas analysis. Three postmortem blood samples were analyzed with all methods, and the results were comparable. The applied methodologies showed different features depending on the sensitivity, sample preparation, and volume. The HS-GC/TCD method in our hand was the most appropriate, on postmortem samples, and versatile to apply. Unfortunately, only a limited number of postmortem blood samples were available for this study due to the rarity of that kind of intoxication in our jurisdiction.     

Determination of total hemoglobin in forensic blood samples with special reference to carboxyhemoglobin analysis

For the determination of total hemoglobin (Hb) in blood containing elevated carboxyhemoglobin (COHb), a newly developed reagent containing a 100-fold concentration of ferricyanide (20 g/l) and a 2-fold concentration of Sterox SE was compared with a standard reagent (0.2 g/l ferricyanide), the reagent of van Kampen and Zijlstra, using forensic blood samples and experimentally heated blood samples. There were no significant differences between the spectra of hemiglobincyanide (HiCN) solution produced with our reagent and the van Kampen and Zijlstra reagent using experimentally heated blood samples. Although the spectra of HiCN changed gradually with increased heating time and with the passage of time after mixing, the absorbance at 540 nm (A540) did not change until at least 120 min for both the reagents. When forensic blood samples containing elevated COHb were mixed with the van Kampen and Zijlstra reagent, total-Hb concentrations determined 5 min after mixing were 10-20% higher than those determined after 180 min. The overestimates of total Hb determined after 5 min resulted in comparable underestimates of percentage saturation of COHb (COHb%) when COHb% was obtained from the ratio of COHb content, determined by gas chromatogrpahy, to total-Hb concentration in blood. However, there was an extremely good correlation between the values of total Hb in forensic blood samples determined with the van Kampen and Zijlstra reagent after 180 min and those determined with our reagent after 5 min. From the results obtained, our reagent proved to be suitable for the determination of total Hb in forensic science practice.     

二阶导数光谱双波长法测定血中碳氧血红蛋白饱和度的研究

本文将双波长法用于二阶导数光谱中,提出一种新的COHb饱和度测定方法。用本法测定了已知COHb饱和度的标准血样和未知COHb饱和度的检血,都得到了比较满意的结果。     

Automated determination of carboxyhemoglobin contents in autopsy materials using head-space gas chromatography/mass spectrometry

To establish a method for the routine analysis of carboxyhemoglobin (COHb) in autopsy materials including those which have undergone postmortem changes, e.g. thermo-coagulation, putrifaction and contamination, an automated head-space gas chromatography/mass spectrometry (GC/MS) analysis was utilized. The procedure consisted of preparation of the sample in a vial and a carbon monoxide (CO) saturated sample, for estimation of hemoglobin content, in another vial, the addition of n-octanol, potassium ferricyanide and an internal standard (t-butanol), GC separation and determination of CO using a GC/MS system equipped with an automated head-space gas sampler. The method was practical not only with the blood and bone marrow aspirates to confirm the findings on the CO-oximeter system, but also with the thermo-coagulated and putrified blood.     

How Reliable are Parenchymal Tissues for the Evaluation of Carbon Monoxide Poisoning? A Pilot Study

Dealing with burnt bodies, the forensic pathologist must first of all answer the question whether the victim was alive at the moment of the fire. This study aims at clarifying whether some human solid tissues may be reliably used for the forensic diagnosis of Co poisoning on burnt bodies providing no collectable blood during the autopsy. From 34 selected cases, both cardiac blood and parenchymal samples were collected to perform CO‐oxymeter, spectrophotometry, and gas chromatography tests: blood CO estimations (blood COHb% and blood[CO]) and parenchymal[CO] values have been compared with special focus on R values. The solid tissues having the best correlations with blood CO amount turned out to be the lung (R 0.84), the liver (R 0.83), the kidney (R 0.79), and the spleen (R 0.92).     

Rapid determination of carboxyhemoglobin in blood by Oximeter

Different methods to determine carboxyhemoglobin (COHb) in blood are described in the literature. In our laboratory three methods to analyze COHb in post-mortem blood samples were compared: the spectrophotometric method of Maehly, a gas chromatographic method with a thermal conductivity detector (GC-TCD) and the Oximeter. Several COHb containing blood samples of deceased persons were analyzed. Results of all three methods were comparable for low concentrations (ca. 10% COHb) as well as for high concentrations (ca. 80% COHb) regardless of the viscosity of the blood samples. The advantages of the Oximeter when compared to Maehly's method and GC-TCD are extreme short time of analysis (<1min), very small blood volume required (<0.1ml) and easy handling. In our opinion application of the Oximeter is not limited to analyses of blood samples from living persons (e.g. in clinical toxicology); it can as well be used for the determination of COHb in post-mortem blood samples. Hence it is a useful and time saving tool in forensic toxicology.     

氯胺酮在急性中毒大鼠体内的死后再分布研究

目的探索氯胺酮在大鼠体内的死后再分布变化规律及温度对再分布的影响。方法48只雄性SD大鼠随机分为2个实验组（室温组24只、冷藏组18只）和1个对照组（6只）,实验组大鼠以氯胺酮290mg／kg灌胃,45min后缺氧处死,分别置于室温（24℃）和冷藏（4℃）条件下,于死后不同时间（0、12、24、48h）取心血、外周血、肝、肺、肾、心肌、大脑,检测其中氯胺酮含量;对照组大鼠以生理盐水灌胃,各对应组织器官样品为空白对照。血和组织样品中加入内标物SKF。。后碱化,乙酸乙酯萃取,GC／MS全扫描定性,内标法、工作曲线法气相色谱定量分析。结果室温条件下,大鼠死后48h内随着死亡时间延长,心血、肺、肝中氯胺酮的浓度呈升高趋势（P〈0．05）,肾脏中氯胺酮的浓度先升高后下降（P〈0．05）,外周血、心肌和脑中氯胺酮的浓度无显著性变化（P〉0．05）。冷藏条件下,血液及组织中氯胺酮浓度变化无显著性差异（P〉0．05）,除心肌外,各样本浓度均低于相应时段室温条件保存的样本。结论氯胺酮在大鼠体内存在死后再分布现象。温度对大鼠死后血液及组织中氯胺酮浓度变化有较明显的影响。     

不同来源一氧化碳中毒死亡者血液中COHb含量分析

目的探索一氧化碳中毒存在的个体差异性,分析女性可能存在的抵御一氧化碳中毒的机制。方法收集207例不同来源的一氧化碳中毒死亡者血液,测量COHb含量,将案例按照不同的因素分类进行统计学分析。结果不同一氧化碳的来源对于死者的COHb浓度影响显著,而性别对于COHb浓度影响不显著,少年儿童和老年人有可能对COHb的抵御能力差于成年人。     

一氧化碳（CO）中毒检测方法

作者查阅近20年国内外相关文献的基础上,对一氧化碳(CO)中毒的检验方法进行了全面的阐述,同时对每种方法的优缺点和适用条件作了比较,并对适用于我国国情的顶空气质联用法进行了改良.     

Interaction between carbon monoxide and ethanol in fire fatalities.

Impairment due to ethanol is clearly a risk factor in deaths due to fire. However, it is less clear whether there is a physiological interaction between ethanol and carbon monoxide (CO) that would alter the carboxyhemoglobin saturation level (COHb sat.) that accounts for death. In an attempt to explore this issue further, 196 fire fatalities investigated by the Office of the Chief Medical Examiner, State of Maryland over a 3-year period were examined. COHb sat. and blood ethanol concentrations (BAC) were tabulated. Twelve cases positive for therapeutic or abused drugs other than lidocaine or atropine were excluded; 184 cases were included. The data indicate that ethanol does not affect the COHb sat. that accounts for death, since the percentage of cases positive for ethanol at a given COHb range shows no trends. Therefore, we conclude that although ethanol remains a risk factor in fire fatalities, the risk appears to be related to the impairment that it produces as opposed to a direct interaction with CO.