液化石油气与煤气中毒检验的异同

目的 研究液化石油气与煤气中毒鉴定的异同。方法 将实验小白鼠、SD大鼠及家兔分别经液化石油气和煤气染毒,测定中毒后血中碳氧血红蛋白饱和度(HbCO%)及丙烷。结果 煤气中毒家兔体内碳氧血红蛋白饱和度达及49.95%;煤气中毒死亡小白鼠及大鼠体内HbCO%大于60%;液化石油气中毒死亡的家兔、小白鼠及大鼠血中检出丙烷,而体内HbCO%与正常的家兔、小白鼠及大鼠体内HbCO%无明显差异。结论 煤气中毒可通过测定其体内HbCO%进行鉴定;液化石油气中毒后体内HbCO%未见明显升高,可通过测定血中丙烷进行鉴定。     

血中碳氧血红蛋白饱和度测定影响因素的研究

目的 考察血中碳氧血红蛋白饱和度(HbCO％)测定的影响因素,为其结果评定和所需样品保存条件提供实验依据。方法 利用三种分光光度法,测定30d内不同条件下保存的CO阳性血的HbCO％的变化。结果 还原双波长法、双波长法测定结果比较稳定,单波长法抗干扰能力较差;尸检所取血样的保存条件包括温度、保存时间及与空气接触程度对HbCO％的测定均有影响,其中温度影响较为显著。结论 利用还原双波长法与双波长法,并结合光谱扫描观察峰形变化可得到比较可靠的结果。30d内4℃条件下,密闭容器中血样接触少量空气不影响其HbCO％的测定。     

A New Approach for the Carbon Monoxide (CO) Exposure Diagnosis: Measurement of Total CO in Human Blood Versus Carboxyhemoglobin (HbCO)

The aim of the study is to present the application of a headspace–gas chromatography–mass spectrometry (HS‐GC‐MS) method for the determination of the carbon monoxide (CO) blood concentration and to compare it with carboxyhemoglobin (HbCO) saturation. In postmortem cases, the HbCO measured by spectrophotometry frequently leads to inaccurate results due to inadequate samples or analyses. The true role of CO intoxication in the death of a person could be misclassified. The estimation of HbCO from HS‐GC‐MS CO measurements provides helpful information by determining the total CO levels (CO linked to hemoglobin (HbCO) and CO dissociated from hemoglobin). The CO concentrations were converted in HbCO saturation levels to define cutoff blood CO values. CO limits were defined as less than 1 μmol/mL for living persons, less than 1.5 μmol/mL for dead persons without CO exposure, and greater than 3 μmol/mL for dead persons with clear CO poisoning.     

A practical method for the accurate determination of methemoglobin in blood containing carboxyhemoglobin

Kinetics of the oxidation of carboxyhemoglobin (HbCO) by potassium ferricyanide was studied photometrically in a weakly acid solution. An increase in the absorbance at 630 nm reached a maximum within 10 min when over a 100-fold excess of ferricyanide to hemoglobin iron was used. A slight decrease in the absorbance was observed after completion of the reaction when over a 500-fold excess of the reagent was used. In the presence of 0.4% Sterox SE, the absorbance began to decrease without complete oxidation. From these findings, a simple, rapid and accurate method for the determination of methemoglobin (Met-Hb) in blood was devised. The method was compared with two other methods, using 11 blood samples containing various amounts of HbCO, and proved to be suitable for blood containing elevated HbCO as well as for ordinary blood.     

Postmortem formation of carbon monoxide

Since carbon monoxide (CO) production after death was suggested in a drowned body, CO and carboxyhemoglobin (HbCO) levels in blood and body cavity fluids of cadavers which were not exposed to fire and CO have been analyzed. CO released from the tissues was determined by gas chromatography and gas chromatography-mass spectrometry, and the total concentration of hemoglobin (Hb) was measured as cyanmethemoglobin (CNmHb). The HbCO level was calculated by the ratio of CO content and CO-binding capacity. CO levels (ml/100 g at STP) of the seven cases in which blood and body cavity fluids could be collected ranged from 0.13 to 0.87 in blood and 0.02 to 0.80 in body cavity fluids. HbCO levels in blood and body cavity fluids were from 0.3 to 6.0% and from 2.3 to 44.1%, respectively. In a typical case showing postmortem formation of CO, the CO levels in body cavity fluids were higher than that in blood. It is suggested that CO in a putrefied body is due to CO in blood prior to death and the CO formed by the decomposition of Hb, myoglobin and other substances during putrefaction. The significance of HbCO levels in body cavity fluids of cases with marked postmortem decomposition seems difficult to interpret without the value of HbCO in blood.     

Sample pre-treatment for CO-oximetric determination of carboxyhaemoglobin in putrefied blood and cavity fluid

Blood or blood-containing cavity fluid samples recovered from decomposed bodies in suspected carbon monoxide (CO) poisoning cases often have low total haemoglobin (tHb) levels or contain significant amounts of oily droplets, methaemoglobin (MetHb) and sulphaemoglobin (SHb), all conditions which render the validity of the measurements of carboxyhaemoglobin (HbCO) by commercially available CO-oximeters doubtful. Two sample pre-treatment methods, namely, centrifugal evaporation and addition of a commercially available standard haemoglobin solution containing a known level of HbCO, were developed to render such putrefied samples amenable to analysis by CO-oximeters. The methods developed were validated with samples of various degrees of putrefaction and various HbCO levels. The relative uncertainty of the determined HbCO levels as compared to their corresponding reference levels for the centrifugal evaporation method was approximately 5% and that for the standard addition method was <20%.     

Production of carbon monoxide in cadavers

Carbon monoxide (CO), total hemoglobin (Hb) and carboxyhemoglobin (HbCO) in the blood and reddish discolored body cavity fluids of cadavers which had not been exposed to fire and CO were analyzed. In 13 cadavers found on land, the maximum saturation of HbCO in the blood was 3.6%, and was 10.1% in the body cavity fluids. There was only one case in which the HbCO saturations in the body cavity fluids were more than 10%. In seven drowned bodies found in fresh water, the highest HbCO saturation in the blood was 6.1%, and was 44.1% in the body cavity fluids. There were three cases in which the HbCO saturations in the body cavity fluids were more than 10%. In 12 drowned bodies found in sea water, the HbCO saturations in the blood were not more than 6.2%, and the maximum saturation of HbCO in the body cavity fluids was 83.7%. There were eight cases in which the HbCO saturations in the body cavity fluids were more than 10%. The results seem to indicate that the interpretation of HbCO saturation in the blood would not be affected significantly by the postmortem formation of CO, and that body cavity fluids should not be used for CO determination.     

95例尸体血中HbCO％的分析

血中碳氧血红蛋白饱和度(简称HbCO％,下同)含量是判断一氧化碳中毒,推断火灾中尸体生前状态的依据。本文证明:血中HbCO％与其年龄、性别及不同情况下CO中毒有关。一氧化碳中毒的尸体含量较高(平均大于60％);火灾事故中遇难的尸体含量中等(平均在30～50％);而被杀后投入火场或服毒后自焚则较低(平均小于20％)。     

血液样品中防腐剂对碳氧血红蛋白稳定性的影响

目的研究临床上常用8种试剂对血液样品中碳氧血红蛋白(HbCO)稳定性的影响。方法将血液样品分为高、低两个HbCO浓度组,选用临床常用的甲醛、氟化钠、乙二胺四乙酸二钠、亚硝酸钠、草酸钾、肝素钠、柠檬酸钾及氟化钠与草酸钾混合物(1:3)8种试剂,按常用浓度分别添加到血样品中,并于添加后0h、2h、8h、24h、3d、7d用紫外可见光分光光度法检测其中HbCO饱和度,用统计学方法进行结果分析。结果本实验选用的8种试剂只有甲醛和亚硝酸钠对HbCO的稳定性影响较为显著,而其余6种对HbCO稳定性的影响无统计学意义。结论在检验疑似CO中毒并经甲醛或亚硝酸钠防腐的检材时应慎重,以免导致错误的鉴定结论。     

The determination of carboxyhaemoglobin in the presence of sulphaemoglobin

The quantitative analysis of carboxyhaemoglobin (HbCO) in fresh blood samples containing sulphaemoglobin (SHb) and in post-mortem blood samples was investigated using two automated spectrophotometers. The OSM 3 Hemoximeter gives much more accurate determinations of HbCO than the IL 282 Co-Oximeter in the presence of SHb. In addition, the OSM 3 Hemoximeter is designed to correct for the presence of SHb and turbidity of blood samples. It is thus suitable for the analysis of post-mortem samples from fire victims and decomposed bodies which may be very putrefied and contain SHb.     

一氧化碳中毒血分光光度定量分析法比较

目的比较7种一氧化碳中毒血样分光光度含量测定方法的特点及适用性。方法用空白血添加一氧化碳配制不同浓度的样品,采用双波长法、还原法（3种）、切线法和导数光谱法（2种）进行检测,对各种方法线性范围、重现性和操作中注意事项等内容进行考察,并用实际案件检材验证和比较。结果还原法一在30%~70%、还原法三在20%~100%,其他方法在20%~70%范围内,线性关系良好;样本浓度超过或低于50%,采用切线法有一定误差;导数法及还原法三因需要制备CO饱和样本,操作略微繁琐,但导数光谱法计算结果准确性好。结论几种方法均可用于一氧化碳中毒血的检测,实验结果可为方法的实际应用提供借鉴和帮助。     

Acute effects of carbon monoxide and cyanide on hepatic mitochondrial function

The effects of carbon monoxide and cyanide on the hepatic redox state and energy charge were investigated. Rats were used for the experiment under pentobarbital anesthesia. Immediately after laparotomy, a rat was placed in an animal chamber made of a transparent plastic box and exposed to a test gas for 3 min. Every test gas was produced in a gas chamber connected to the animal chamber with a flexible tube. HCN was produced from NaCN and H2SO4. In the CO inhalation experiment, various amounts of CO were introduced into the gas chamber. Immediately after an exposure, about 2 g liver was frozen in situ with a precooled clamp. Oozed blood from the wound surface was sampled. Concentrations of ATP, ADP, AMP, acetoacetate, and beta-hydroxybutyrate in hepatic mitochondria were determined, and the redox state and the energy charge were calculated. For cyanide as well as CO, significant negative correlations were found between the concentration in the blood and the redox state. The same held true for the energy charge. The redox state showed a slight increase at low concentrations of both gases; however, thereafter it began to decrease sharply with increases in concentrations. When concentrations of the toxicant in the blood reached certain levels, a kind of turning point, beyond which the redox state does not decrease any more, was observed. It was about 40% for HbCO and about 2.0 micrograms/ml for cyanide, and the points seemed to be related to the concentrations, beyond which cells are irreversibly damaged. On the other hand, the energy charge did not change at low concentrations. With an increase in toxicant concentrations, the energy charge decreased drastically. The rate of decrease in the energy charge became higher when blood concentrations exceeded certain levels. It was about 40% for HbCO and 2.0 micrograms/ml for cyanide. The presence of low levels of blood cyanide did not affect the relationship between the energy charge and the HbCO concentration.     

Experimental study on postmortem formation of carbon monoxide

Rats were drowned and kept immersed for 1 month in either boiled city water, or boiled or unboiled fresh water collected from a river. A small amount of carbon monoxide (CO) formed after death and a low carboxyhemoglobin (HbCO) saturation was found in blood and thoracic cavity fluid of the animals immersed in boiled city water and in boiled fresh water. A considerable amount of CO and a high HbCO saturation was observed in blood and thoracic cavity fluid in two out of three rats immersed in unboiled fresh water at 4-6 degrees C, and in one out of three at 6-16 degrees C. It is suggested that microorganisms in the water, in which the rats were drowned and kept immersed, and low temperatures of around 5 degrees C during storage, played an important role in the postmortem formation of carbon monoxide.     

152例火场尸体的法医学检验分析

目的 探讨火场尸体的法医学检验特点及其鉴定。方法 对86起火场中152例尸体的相关检验资料进行回顾性研究。结果 152例火场尸体,生前烧死109例,纵火焚尸38例,无明显高温作用的尸体5例。主要死因有“烧死综合征”100例,火场有毒气体中毒8例,机械性损伤32例(含高坠死4例),机械性窒息5例,电击、服毒各1例;不能确定死因5例。自杀5例,他杀40例,意外107例。在生前烧死尸体,87例呼吸道内有炭末沉着,71例皮肤局部烧伤边缘组织有红肿,46例检见水泡,17例有“闭眼反应”征象,大部分尸体血中HbCO浓度超过20％;纵火焚尸少见或不见上述改变。结论 检验火场尸体,根据烧死尸体征象和血中HbCO浓度检测,并结合火场勘验资料综合分析,其死因鉴定和死亡方式推断结论方能准确。     

The forensic medical expertise of the victims of large-scale fires]

The difficulties of present-day forensic medical expert evaluation of poisonings in fires are explained by exposure of man to highly toxic compounds that form during burning of polymers. Analyzing forensic medical expert evaluations of a large number of victims dead in a large-scale fire, the authors emphasize the necessity of measuring not only dead people's blood levels of HbCO, but of some other toxic combustion products that may exert combined effects on human body. The authors think it desirable that criteria of forensic medical evaluation of combined poisoning in fire be defined.     

Significance of skin metallization in the diagnosis of electrocution

The differentiation of minute current marks from the faint traces of burns may offer some difficulties. Marcinkowski and Wojciechowski (1973) treated the skin of corpses with the same metal objects either heated to a high temperature or exposed to 250 V of alternating current, and determined (by an electrographic method) that metallization appeared only after applying the electric current.The continuation of these observations is linked with the actual experimental studies of Pankowski. By treating the skin of corpses with alternating and direct current of 10, 50, 100 and 250 V for 0.3 sec, 1 sec, 30 sec and 1 min passing through a radioactive electrode of ⁶⁰Co, he has shown that the radioactivity of the skin at the site of electrode contact increases with the elevation of the voltage and its duration. In the case of direct current the rise was 630 – 54000-fold at the site of the positive electrode.Using electrodes of copper, aluminium and iron (not radioactive) it has also been shown (by an electrographic method) that metallization intensifies under the same conditions of time and voltage.Metallization could be detected even when no current marks on the skin were evident. Electrography appears to be extremely useful in the detection of metallization. No metallization was detected at the site of the negative electrode (as refers to direct current).     

Determination of Nitrite in Whole Blood by High‐Performance Liquid Chromatography with Electrochemical Detection and a Case of Nitrite Poisoning

Although nitrite is widely used in meat processing, it is a major toxicity hazard to children and is responsible for the blue‐baby syndrome. A simple and effective method to determine nitrite in whole blood has been devised using ion chromatography with suppressed conductivity detection. The blood sample was deproteinized by adding acetonitrile and purified with mini‐cartridges to remove hydrophobic compounds, chloride ions, and metal ions. An aliquot of the filtrate was injected onto the ion chromatography. The retention time for nitrite was 13.8 min and the detection limit of nitrite in whole blood was 0.4 μmol/L. The calibration curve was linear (r² = 0.9999) over the concentration working range. The blood nitrite concentration of a victim who attempted suicide by ingesting sodium nitrite powder was determined using the present method. The basal levels for nitrite in human blood was determined with 7.1 ± 0.9 μmol/L (n = 12).     

An ELISA using avidin-biotin complex for the determination of ABH group from saliva

The ABH group in a trace amount of saliva could be determined by an enzyme-linked immunosorbent assay (ELISA) using an avidin-biotin-peroxidase complex (ABC) technique. In this method ABH blood group substances as a solid phase are adsorbed to wells of a microtiter plate made of polystyrene. The primary antibody corresponding to the blood antigen adheres onto the wells, and reacts with the biotinylated secondary antibody. The previously formed ABC reagent is then added to the above wells, and finally the absorbance produced by the interaction of the peroxidase activity with a chromogenic substance is measured at 492 nm. This method proved to be clearly more sensitive for the detection of ABH blood groups in secretor-saliva than the conventional hemagglutination inhibition test. Also the ABH group of non-secretor-saliva could be easily determined by this method.     

A fatality caused by accidental production of hydrogen sulfide.

A 55-year-old male Caucasian truck driver was dead at the scene after breathing hydrogen sulfide (H(2)S) produced by an accidental transfer of sodium hydrogen sulfide (NaHS) from a tanker truck to a tank containing 4% sulfuric acid (H(2)SO(4)) and iron(II) sulfate (FeSO(4)). Autopsy of the decedent's body revealed pulmonary edema and passive congestion in lungs, spleen, kidneys, and adrenal glands. Postmortem biological samples were analyzed for carbon monoxide, cyanide, ethanol, and drugs. Since a potential exposure to H(2)S was involved, blood was also analyzed for sulfide (S(2-)). The analysis entailed isolating S(2-) from blood as H(2)S using 0.5M H(3)PO(4), trapping the gas in 0.1M NaOH, and determining the electromotive force using a sulfide ion specific electrode. Acetaminophen at a concentration of 14.3 microg/ml was found in blood, and metoprolol was detected in the blood, liver, and kidney samples. The blood S(2-) level was determined to be 1.68 microg/ml. It is concluded that the cause of death was H(2)S poisoning associated with a hazardous material accident in an industrial situation.     

Oral fluid results compared to self reports of recent cocaine and heroin use by methadone maintenance patients

A novel breath-alcohol analyzer based on the standardization of the breath alcohol concentration (BrAC) to the alveolar-air water vapour concentration has been developed and evaluated. The present study compares results with this particular breath analyzer with arterial blood alcohol concentrations (ABAC), the most relevant quantitative measure of brain alcohol exposure. The precision of analysis of alcohol in arterial blood and breath were determined as well as the agreement between ABAC and BrAC over time post-dosing. Twelve healthy volunteers were administered 0.6g alcohol/kg bodyweight via an orogastric tube. Duplicate breath and arterial blood samples were obtained simultaneously during the absorption, distribution and elimination phases of the alcohol metabolism with particular emphasis on the absorption phase. The precision of the breath analyzer was similar to the determination of blood alcohol concentration by headspace gas chromatography (CV 2.40 vs. 2.38%, p=0.43). The ABAC/BrAC ratio stabilized 30min post-dosing (2089±99; mean±SD). Before this the BrAC tended to underestimate the coexisting ABAC. In conclusion, breath alcohol analysis utilizing standardization of alcohol to water vapour was as precise as blood alcohol analysis, the present "gold standard" method. The BrAC reliably predicted the coexisting ABAC from 30min onwards after the intake of alcohol.