Blood cyanide determination in two cases of fatal intoxication: comparison between headspace gas chromatography and a spectrophotometric method

Blood samples of two cases were analyzed preliminarily by a classical spectrophotometric method (VIS) and by an automated headspace gas chromatographic method with nitrogen-phosphorus detector (HS-GC/NPD). In the former, hydrogen cyanide (HCN) was quantitatively determined by measuring the absorbance of chromophores forming as a result of interaction with chloramine T. In the automated HS-GC/NPD method, blood was placed in a headspace vial, internal standard (acetonitrile) and acetic acid were then added. This resulted in cyanide being liberated as HCN. The spectrophotometric (VIS) and HS-GC/NPD methods were validated on postmortem blood samples fortified with potassium cyanide in the ranges 0.5-10 and 0.05-5 mug/mL, respectively. Detection limits were 0.2 mug/mL for VIS and 0.05 mug/mL for HS-GC/NPD. This work shows that results obtained by means of the two procedures were insignificantly different and that they compared favorably. They are suitable for rapid diagnosis of cyanide in postmortem cases.     

Rapid and sensitive quantitation of cyanide in blood and its application to fire victims.

We developed a head-space method for the determination of blood cyanide by gas chromatography with electron-capture detection. In this technique, a reaction precolumn packed with chloramine-T was used for the conversion of hydrogen cyanide into cyanogen chloride. Since the reaction precolumn eliminated the necessity of trapping hydrogen cyanide from biological samples, blood cyanide could be analyzed quickly by acidification only. Using this method, blood cyanide levels of fire victims were determined at autopsy. The serum values of cyanide ranged from 0.11 micrograms/ml to 18.12 micrograms/ml. However, a significantly higher cyanide content was detected in the left ventricular blood than in the right. This indicates that death was caused by the fire and suggests that the collecting point of the blood sample is an important factor in the determination of inhaled cyanide. There was a positive correlation between blood cyanide and carboxyhemoglobin contents.     

固相萃取-GC/MS法检测生物检材中的百草枯

目的采用固相萃取-气相色谱/质谱分析方法检测血液、尿液和脏器组织中的百草枯。方法人血液、尿液和猪肺组织样品经三氯乙酸去除蛋白后,取上清用十二烷基三甲基溴化铵和十二烷基硫酸钠处理过的C18小柱提取,提取物用硼氢化钠在碱性条件下还原,产物用气相色谱/质谱法分析,外标法定量。结果生物检材中百草枯回收率为78%～87%,最低检出限为0.1μg/mL,在0.5～1mg/mL范围内线性关系良好,可对实际案例检材进行定量检测。结论本文固相萃取-气相色谱/质谱分析方法能满足中毒生物检材检验及临床毒物检验需要。     

Automated headspace solid-phase microextraction and capillary gas chromatography analysis of ethanol in postmortem specimens

Solid-phase microextraction (SPME) is a relatively new solventless sample preparation technique that allows simultaneous sampling, extraction, pre-concentration, and introduction of analytes from a sample matrix in a single procedure. This methodology has been used for the analysis of several drugs of forensic toxicology interest including volatile compounds. This paper describes a methodology for analysis of ethanol and other volatile compounds using automatic headspace solid-phase microextraction (HS-SPME) and capillary gas chromatography in postmortem specimens. The methodology was initially developed using standard solutions of acetaldehyde, acetone, methanol, and ethanol. Isobutanol was used as internal standard. Postmortem samples of blood, urine, and vitreous humor were obtained during medico-legal autopsies. To date, there are no published paper regarding alcohol analysis in vitreous humor specimens using HS-SPME and limited literature analyzing blood and urine samples. HS-SPME analysis showed that, under optimized conditions, ethanol and isobutanol (internal standard) were well-separated from other volatile compounds such as acetaldehyde, acetone, and methanol considered to be potential interferents in ethanol analysis. The calibration curves for each volatile compound demonstrated good linearity throughout the concentration range from 0.001 to 1.0 g/dl and the detection limit of ethanol in the studied specimens was approximately 0.0001 g/dl.     

腐败血液中乙醇的顶空气相色谱分析

目的分析血液腐败后产生的乙醇及其他物质并探讨腐败血液中乙醇的检测及计算方法。方法以正常人空白血液制作腐败血样,采用1,4-二氧六环为内标物,通过顶空气相色谱进行定性及定量分析。结果血中乙醇在0.0625～1mg/mL范围内线性关系良好（r^2=0.9996）,各质量浓度组的变异系数（CV%）〈2%,血中乙醇的最低检出限为1μg/mL（S/N≥3）。腐败血样所产生乙醇与正丙醇的比例大致为25：1。结论检验方法简便、准确。为法医毒化检验相关工作提供了依据。     

液相色谱-串联质谱法检测血液中的美西律

目的建立测定血液中美西律(mexiletine)的液相色谱-串联质谱联用法(LC-MS/MS)。方法采用简便的乙腈蛋白沉淀法对血液进行预处理,应用Allure PFP Propyl液相柱分离,用电喷雾正离子模式离子化,多反应监测模式对美西律进行分析。结果美西律与内标纳洛酮分离良好,在0.02～10.00μg/mL内线性关系良好,相关系数为0.9999,回归方程为y=0.0283x-0.0151,日内与日间精密度的RSD均小于15%,最低检测限为0.01μg/mL。结论建立的LC-MS/MS方法简单、灵敏、可靠,可同时适用于美西律临床药物监测和法医毒物分析的需要。     

Morbus Fahr--considerations on a case of sudden death

This paper presents 21 cases related to cyanide intoxication by oral ingestion. Cyanide concentrations in biological specimens are especially different from the type of postmortem specimens, and very important in interpreting the cause of death in postmortem forensic toxicology. Besides the detection of cyanide in autopsy specimens, the autopsy findings were unremarkable. Biological samples (0.2mL or equal to less than 10μg of cyanide) were analyzed colorimetrically for cyanide. In a series of 21 cyanide fatalities, the concentration ranges (mean±SD) of cyanide in heart blood, peripheral blood and gastric contents were 0.1-248.6mg/L (38.1±56.6mg/L), 0.3-212.4mg/L (17.1±45.1mg/L) and 2.0-6398.0mg/kg (859.0±1486.2mg/kg), respectively. The ranges of the heart/peripheral blood concentration ratio and gastric contents/peripheral blood concentration ratio were 0.3-10.6 (mean 3.4) and 3.4-402.4 (mean 86.0), respectively. From the difference of cyanide concentration and the concentration ratio of cyanide in different types of postmortem specimens, the possibility of the postmortem redistribution of cyanide and death by oral ingestion of cyanide could be confirmed. We reported cyanide fatal cases along with a review of literature.     

固相萃取-气相色谱法检测生物检材中斑蝥素

目的建立固相萃取-气相色谱法检测生物检材中斑蝥素的方法。方法采用HLB固相萃取柱提取,气相色谱-内标法检测。结果斑蝥素在0.1～200mg/L范围内呈良好的线性关系,相关系数为0.999以上;精密度（RSD）小于5%。对于添加血样,方法检出限为0.05μg/mL,加标回收率范围为93.03%～98.29%。结论该方法操作简便、快速、灵敏,提取回收率高,提取物含杂质较少,可用于实际案件中全血和尿样中斑蝥素的检测。     

HS-SPME-GC/MS联用法测定生物检材中的百草枯

目的建立检测生物检材中百草枯的顶空固相微萃取-气相色谱-质谱联用（HS-SPME-GC/MS）的分析方法。方法尿样中加乙基百草枯作为内标,在氯化镍作催化剂的条件下,用硼氢化钠在碱性条件下进行还原,HS-SPME萃取,提取物经GC/MS分析。全血需先离心,沉淀血细胞提取上清液,再用甲醇沉淀蛋白。最终得到的上清液加内标乙基百草枯,以下操作同尿样。结果尿样和血样中的百草枯的还原产物在1.0μg/mL~100μg/mL范围内线性关系良好,回归方程分别为y=0.0957x-0.0163,r=0.9974（n=6）;y=0.1096x＋0.0871,r=0.9964（n=6）。尿样、血样低、中、高三个质量浓度,RSD值均小于7%。回收率分别为尿样85.49%~100.83%,血样94.72%~99.68%。结论本法操作简便易行、灵敏度高、快速准确。为检测生物检材中的百草枯提供了有效的方法。     

顶空气相色谱法检测生物检材中乙醇及其相关物质

目的建立生物检材中乙醇及其相关物质的检测方法。方法生物检材加入内标异丙醇后用顶空气相色谱法进行检测（FID检测器）,以保留时间定性,内标法定量。结果该方法线性范围为0．05035-1．613mg／ml。相关系数r=0．9999,最低检测限（limit of detection,LOD）3．379μg／ml,分析方法平均回收率为98．24％～106．5％,日内精密度RSD〈2．2％,日间精密度RSD〈1．4％,总分析时间不超过18min。结论该方法可用于生物检材中乙醇及其相关物质的检测。     

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。     

Simple and simultaneous quantification of cyanide,ethanol, and 1-propanol in blood by headspace GC–MS/NPD with Deans switch dual detector system

Cyanide is a powerful and rapidly acting poison. In Japan, cyanide poisoning is rare, and regular cyanide testing can be costly and time consuming. In contrast, alcohol analysis is routinely performed in most forensic laboratories. In this study, we attempted to develop a method for the simultaneous quantification of cyanide and alcohols in blood using headspace gas chromatography (HS–GC). As nitrogen-phosphorus detection (NPD) is more sensitive to hydrogen cyanide than mass spectrometry (MS), a Deans switch was used to switch the detectors during a single run. The separation provided by three analytical columns, PoraBOND Q, CP-Sil 5 CB, and HP-INNOWax, was investigated, and PoraBOND Q was selected. The use of HS–GC–MS/NPD with a Deans switch enabled the simple and simultaneous quantification of cyanide, ethanol, and 1-propanol. Eighteen other volatile compounds were detected in the SIM/scan mode of the MS.     

HS-SPME-GC/MS法检测尿液及毛发中苯丙胺类毒品

目的采用顶空固相微萃取（HS-SPME）、GC/MS分析方法,对生物样品中苯丙胺（AM）、甲基苯丙胺（MAM）、3,4-亚甲二氧基苯丙胺（MDA）和3,4-亚甲二氧基甲基苯丙胺（MDMA）4种苯丙胺类毒品进行定性定量分析。方法在碱性和饱和盐处理状态下,采用100μm聚二甲基硅氧烷（PDMS）萃取纤维,于顶空瓶中进行生物样品AM、MAM、MDA、MDMA 4种毒品萃取,以2-甲基苯乙胺为内标,经气-质联用选择离子检测（GC/MS/SIM）模式进行定性定量分析。对HS-SPME条件优化,对方法的精密度、准确度和检出限进行测定。结果 AM、MAM、MDA、MDMA 4种毒品尿液中的最低检出限为5ng/mL,毛发中的最低检出限为0.5ng/mg。尿液中线性关系范围为0.05μg/mL~5μg/mL,r〉0.991,回收率为82%~108%,RSD为2.6%~6.1%（n=5）;毛发中线性关系范围为5ng/mg~500ng/mg,r〉0.992,回收率为80%~113%,RSD（%）为1.4%~6.8%（n=5）。结论 HS-SPME-GC/MS各项定量参数符合分析要求。该方法简单、灵活、经济、快速、无溶剂,适用于生物检材中该类毒品的分析。     

Simple analysis of arylamide herbicides in serum using headspace-solid phase microextraction and GC/MS

A simple and sensitive method for analysis of four arylamide herbicides (butachlor, propanil, diphenamide and propyzamide) in serum was developed using a headspace–solid phase microextraction (SPME) and a gas chromatograph–mass spectrometer (GC–MS). A vial containing a serum sample and sodium chloride was heated at 90°C. The extraction fiber of the SPME was exposed for 45 min in the headspace of the vial. The compounds adsorbed on the fiber were desorbed by exposing the fiber in the injection port of the GC–MS. The calibration curves, using an internal standard method, demonstrated good linearity throughout the concentration range from 0.25 to 10.0 μg/ml. Propyzamide was used for an internal standard. The limit of detection was 0.10, 0.05, and 0.25 μg/ml for butachlor, diphenamide, and propanil, respectively. No interferences were found, and the time for analysis was 60 min for one sample. In addition, this proposed method was applied to a suicide case in which the patient ingested Kusanon A^®, a herbicide. Propanil, which was the main ingredient in the herbicide, was detected in the eight serum samples collected from the patient during the hospitalization at the concentration range from 26.7 to 1.1 μg/ml.     

Detection of gamma-hydroxybutyrate (GHB) in beverages

OBJECTIVE: To establish an analytical method for the determination of GHB in beverages using GC/MS and LC/MS/MS. METHODS: After beverage samples with GHB-d6 as the internal standard were extracted with ethyl acetate, then the extracts were derivatized with N,O-bis(trimethylsilyl)trifluoroacetamide (BSTFA), at last the derivateized extracts analyzed by gas chromatography- mass spectrometry. After beverage samples with GHB-d6 as the internal standard were diluted by mobile phase then directly analyzed by LC/MS/MS. Results The limit of detection was 0.2 microg/mL and both relative standard deviations for between-day and within-day assays were < 8.54% in GC/MS. The limit of detection was 2 microg/mL and both relative standard deviations for between-day and within-day assays were <8.62% in LC/MS/MS. Conclusion These methods of qualitative and quantitative analysis were found to be sensitive, accurate, rapid and suitable for the forensic toxicology to test of GHB in real cases.     

A solid-phase microextraction method for the detection of ignitable liquids in fire debris

A solid-phase microextraction (SPME) procedure involving direct contact between the SPME fibers and the solid matrix and subsequent gas chromatography/mass spectrometric analysis for the detection of accelerants in fire debris is described. The extraction performances of six fibers (100 mum polydimethylsiloxane, 65 mum polydimethylsiloxane-divinylbenzene, 85 mum polyacrylate, 85 mum carboxen-polydimethylsiloxane, 70 mum Carbowax-divinylbenzene, and 50/30 mum divinylbenzene-Carboxen-polydimethylsiloxane) were investigated by directly immersing the fibers into gasoline, kerosene, and diesel fuel. For simulated fire debris, in the direct contact extraction method, the SPME fiber was kept in contact with the fire debris matrix during extraction by penetrating plastic bags wrapping the sample. This method gave comparable results to the headspace SPME method in the extraction of gasoline and kerosene, and gave an improved recovery of low-volatile components in the extraction of diesel fuel from fire debris. The results demonstrate that this procedure is suitable as a simple and rapid screening method for detecting ignitable liquids in fire debris packed in plastic bags.     

UPLC-MS/MS检测人血中18种有机磷及氨基甲酸酯类农药

目的建立人血中18种有机磷及氨基甲酸酯类农药超高压液相色谱-串联质谱(UPLC-MS/MS)的检测方法。方法血液中加入乙腈沉淀蛋白,采用Waters BEH C18(1.7μm 2.1×50mm)柱子,流动相为5mmol/L乙酸铵水-甲醇,流速:0.3m L/min;进样量:2μL,电喷雾离子源(ESI),正离子检测,采用多反应监测方式进行定量分析。结果药物最小检测限(LOD)在0.1~40ng/m L之间,定量限(LOQ)在0.5~50ng/m L之间,各药物浓度在定量限到500ng/m L范围内线性良好,回收率均在64.3%~111.9%之间,相对标准偏差为3.9%~10.3%。结论该方法专属性强、灵敏、准确,可以适用于法庭与临床毒物分析。     

A simple, rapid and simultaneous analysis of complex volatile hydrocarbon mixtures in blood using gas chromatography/mass spectrometry with a wide-bore capillary column

A screening method for detecting volatile hydrocarbons in blood has been developed using gas chromatography/mass spectrometry with a wide-bore capillary column and a headspace method. Toluene-d8 and indan were used as the internal standards for quantitative analysis. Hydrocarbons with retention indices from 600 to 1200 were simultaneously and quantitatively detected in relatively low concentrations (0.01 microgram/ml) in reconstructed ion chromatography. This method could prove useful in forensic cases in which urgent examination of complex hydrocarbon mixtures, e.g. petroleum components, is required.     

乌头碱在家兔体内的代谢动力学初步研究

本文应用甲醇-0.05mol/L碳酸铵水溶液-二氯甲烷(90:10:2)作流动相,在YWGC_(18)H_(37)反相键合相色谱柱上分离乌头碱和内标,用紫外分光检测器在235nm外定量,改进了动物组织内痕量乌头碱的HPLC检测法。运用该法检测家兔静脉注射乌头碱后的血毒物浓度,初步研究了乌头碱在家兔体内的代谢动力学过程,表明其体内过程符合开放二室模型,T_(1/2α)=1.4682min,T_(1/2β)=34.1379min。体内乌头碱可以原形由尿和胆汁中排出,但以前6h尿排泄为主。     

Measurement of Uncertainty for Aqueous Ethanol Wet‐Bath Simulator Solutions Used with Evidential Breath Testing Instruments

Aqueous ethanol wet‐bath simulator solutions are used to perform calibration adjustments, calibration checks, proficiency testing, and inspection of breath alcohol instruments. The Toxicology Bureau of the New Mexico Department of Health has conducted a study to estimate a measurement of uncertainty for the preparation and testing of these wet‐bath simulator solutions. The measurand is identified as the mass concentration of ethanol (g/100 mL) determined through dual capillary column headspace gas chromatography with flame ionization detector analysis. Three groups were used in the estimation of the aqueous ethanol wet‐bath simulator solutions uncertainty: GC calibration adjustment, GC analytical, and certified reference material. The standard uncertainties for these uncertainty sources were combined using the method of root‐sum‐squares to give u_c = 0.8598%. The combined standard uncertainty was expanded to U = 1.7% to reflect a confidence level of 95% using a coverage factor of 2. This estimation applies to all aqueous ethanol wet‐bath simulator solution concentrations produced by this laboratory.