不同条件下Percoll密度梯度离心分离组织细胞浮游生物的比较

目的实验评估不同条件下Percoll密度梯度离心分离组织中浮游生物的效果。方法大白兔肝组织匀浆后与3种藻类混合物混匀,分为混匀高速分离组、混匀低速分离组、叠加高速分离组、叠加低速分离组和未分离组(对照组)进行Percoll密度梯度离心分离浮游生物,镜检并提取其DNA,用PCR技术分别检测浮游生物16S rDNA和叶绿素基因特异性片段。结果混匀高速分离组有较多浮游生物呈分层条纹状分布于离心管中部,叠加高速分离组浮游生物紧邻组织细胞层下,低速分离组见较少浮游生物紧邻于组织细胞层之下,未分离组见浮游生物和组织细胞混杂沉于管底;经DNA检测,各分离组组织细胞层下液体均可检出浮游生物的1条447bp 16S rDNA片段及1条194bp叶绿体/叶绿素脱辅基蛋白基因片段,未分离组均未检出扩增产物且背景较深。结论混匀加样方式进行高速Percoll密度梯度离心,合并收集组织细胞层下所有液体,是分离浮游生物的最有效方法。     

溺死法医学鉴定的研究新进展

综述了近年来在硅藻检验、水中浮游生物叶绿素（A）检测、血液化学和组织化学检验等方面的最新文献报道,并对各种溺死检验方法的优缺点进行了评价：在硅藻检验中,硝酸乙醇法、破机罐法及微波消解法,可缩短检验时间,提高办案效率;酶消化法及PCR法硅藻检出率高,适用于可疑水样中硅藻密度低等情况。早期器官组织中浮游生物叶绿素（A）、血液和组织中其他生化指标,可作为鉴定溺死的重要参考。微量元素锶检测可用于鉴定海水中溺死。另外,硅藻及其他浮游生物遗传多态性片断PCR,可望成为新的、灵敏的溺死检测方法。     

溺死法医学检验鉴定方法评估与展望

综述近年来在硅藻检验、水中浮游生物叶绿素（A）检测、血液化学和组织化学检验等方面的最新文献报道,并对各种溺死检验方法的优缺点进行了评价：在硅藻检验中,硝酸乙醇法、破机罐法及微波消解法,可缩短检验时间,提高办案效率;酶消化法及PCR法硅藻检出率高,适用于可疑水样中硅藻密度低样品的检测。早期器官组织中浮游生物叶绿素（A）、血液和组织中其他生化指标,可作为鉴定溺死的重要参考;微量元素锶检测可用于鉴定海水中溺死;另外,硅藻及其他浮游生物遗传多态性片断PCR,可望成为新的、灵敏的溺死检测方法。     

检测浮游生物叶绿素相关基因诊断溺死的实验研究

目的评估浮游生物叶绿素相关基因检测用于溺死诊断的价值。方法将18只大白兔随机分为溺死组（n=10）、死后抛尸组（n=6）和对照组（n=2）,各组分别取心血及肺、肝、肾、脑组织,分离浮游生物并提取其DNA,用PCR技术检测叶绿素相关基因EG（EG1和EG2）及SK（SK1和SK2）。同时用硝酸消化法检验肺和肝组织中的硅藻。结果溺死组心血及肺、肝、肾、脑组织中EG1分别检出9、10、9、7和8例阳性,EG2分别检出8、10、7、5和7例阳性;死后抛尸组仅在心血和肺组织中各检出1例EG1阳性;对照组各组织均未检出EG1和EG2。SK1、SK2除在溺死组心血、肺和肾有少数检出外（≤2例）,在其他组未检出扩增产物。硝酸消化法从溺死组肺、肝组织中分别有9例及3例检出硅藻,死后抛尸组仅在1例肺组织中检出。结论浮游生物叶绿素相关基因EG用于溺死诊断的阳性检出率要高于硝酸消化法,在溺死诊断中具有较高的应用价值。     

溺死诊断中浮游生物检验方法的研究现状及进展

法医学实践中,判断是否为生前溺死是法医学尸检及鉴定工作中的一个重点和难点,目前尚无能明确诊断溺死的生物学和法庭化学指标。在溺死案件的诊断中,浮游生物检验是常见的方法。尽管目前还存在一些争议,但国内法医工作者认为,器官组织中浮游生物的存在仍然是判断生前溺死的重要证据之一。本文就国内外有关浮游生物的检验方法、检验标准及检验结果的判定等研究现状作一综述,旨在使人们更加清晰地认识浮游生物检验在溺死诊断中的作用。     

PCR-DGGE法检测浮游生物16S rDNA在溺死鉴定中的应用

目的建立并评估PCR-DGGE法检测浮游生物对溺死鉴定的应用价值。方法大白兔30只随机分为3组:溺死组(n=12),死后抛尸组(n=12)和对照组(n=6);溺死组和死后抛尸组又分为2个亚组:东湖水域组(n=6)和墨水湖水域组(n=6)。死后提取心血和肺、肝、肾、脑等组织,匀浆后,采用Percoll密度梯度离心法分离浮游生物并提取其DNA,PCR扩增浮游生物特异的16S rDNA片段后分别用琼脂糖凝胶电泳及DGGE检测分析。2个溺死案例检材同法检验。结果溺死组各组织器官中浮游生物检测多呈阳性:肺(100%)、肝(83%)、肾(75%)、心血(83%)、脑(42%);死后抛尸组仅2例肺组织(16.7%)检出阳性;对照组全部阴性。溺尸肺组织DGGE分型图谱与相应溺死点水样分型图谱相似,而与非溺死点水样分型结果差异显著。2实际案例均呈阳性。结论本方法不仅有助于定性诊断溺死,而且通过比较产物的多样性可以推断溺死地点,在法医学溺死鉴定中具有较大实用价值。     

胶体金标记苯丙胺单克隆抗体免疫试剂盒研究

目的建立一种准确、快速、简便的检测尿液中苯丙胺(AMP)的胶体金免疫层析技术。方法采用柠檬酸三钠还原法制备胶体金颗粒,标记抗AMP单抗,将AMP—BSA抗原固相于硝酸纤维素膜上,制备胶体金免疫层析测试条。通过尿液、血液和唾液中的可能存在的苯丙胺成分与测试条上的苯丙胺-BSA完全抗原竞争结合有限的单抗结合位点,来判定检测结果。结果用ICT法和GC/MS检测217份尿样,本法检测阈值为1000ng/mL,特异性为99.17%,准确性为99.54%。结论ICT法检测尿液中的AMP特异性强,灵敏度高、简便快速、无需特殊仪器设备,具有广泛应用价值。     

溺死诊断中浮游生物检验方法的研究现状及进展

法医学实践中,判断是否为“生前溺死”是法医学尸检及鉴定工作中的一个重点和难点,目前尚无能明确诊断溺死的生物学和法庭化学指标。在溺死案件的诊断中,浮游生物检验是常见的方法。尽管目前还存在一些争议,但国内法医工作者认为,器官组织中浮游生物的存在仍然是判断生前溺死的重要证据之一。本文就国内外有关浮游生物的检验方法、检验标准及...     

浮游生物16S rDNA检测在大鼠溺死鉴定中的价值

目的建立浮游生物16S rDNA PCR检脸法应用于溺死的鉴定。方法将15只SD大鼠随机分为溺死组、死后抛尸组和正常对照组,死后分别取脑、肝、肾和肺等脏器,提取DNA.用特异性引物扩增浮游生物16S rDNA第三和第四可变区特异片段。结果溺死组5例,肺全部检出(100%)浮游生物16S rDNA;肝、肾分别检出4例(80%);脑检出3例(75%)。死后抛尸组仅1例在肺中检出浮游生物(20%)。正常对照组均未检出。苗论浮游生物16S rDNA PCR检验法可用于溺死的鉴定。     

溺死相关浮游生物基因座的复合扩增体系

目的构建溺死相关浮游生物基因座的复合扩增体系,验证体系特异性并评估其在法医溺死诊断中的应用价值。方法针对溺死相关浮游生物同源基因序列,设计特异性引物,并用FAM、HEX、TAMRA、ROX、SIZ荧光染料分组标记,构建复合扩增体系;进行体系特异性验证;以16例实验猪样本评估体系检验效能;复合扩增体系、硅藻形态学MD-VF-Auto SEM检测法及硅藻rbc L基因PCR-CE检测法分别检测28例案件样本,比较分析应用效果。结果该复合扩增体系共包含14个基因座,可特异性扩增35种浮游藻类和3种浮游细菌,人、3种人体共生菌及8种浮游细菌均为阴性。以该体系检测溺死实验猪,阳性率为90%,非溺死实验猪均未检出;检测溺死案件样本,阳性率为96%,非溺死案件均未检出。复合扩增体系与MD-VF-Auto SEM法检测案件尸体肺、肝和肾的阳性率均不具有统计学差异(P>0.05),但其与硅藻rbcL基因PCR-CE法检测案件肝和肾的阳性率均具有统计学差异(P<0.05)。结论本文针对多种溺死相关浮游生物14个基因建立的复合扩增体系,具备多种靶物种的特异性遗传标记,且所需检材量小,提高了检测效能,在法医溺死鉴定中具有良好的应用前景。     

测定血锶含量鉴定溺死的法医学意义

为评价血锶含量测定对诊断鉴定溺死的实用价值,作者用家兔进行实验,分别测定溺死与死后入水家兔左心血中锶含量。结果证实:1.死后较短时间内血锶含量测定确可鉴定溺死;2、死后24小时内仅可帮助鉴定溺死。实验表明水中浸泡时间因素对血锶含量确有显著影响。两例实际检案的应用观察,较实验性研究为佳,值得进一步研究。     

测定肺锶含量鉴定溺死的研究

作者借助ICP 检测溺死和死后沉入水中,浸泡不同时间家兔及对照组肺腮含量。结果表明,溺死组肺锶含量显著高于死后入水组和对照组(P<0. 01) ;无论溺死或死后沉入水中浸泡不同时间,家兔肺锶含量之间无明显差异(P>0. 05) ,提示肺锶含量受水中浸泡时间或腐败因素的影响并不显著。2例实际案例的肺锶含量测定支持实验性研究结果,说明肺锶含量测定可用于鉴定溺死,具有实用价值。     

硅藻定量检验和种属鉴定的实验研究

本实验用家兔18只,分为溺死组、死后(抛尸)入水组及对照组,每组各6只。采用消化—光镜法作肺、肝、肾硅藻计数(定量)及种属鉴定检验,同时作水样检验及空白对照。结果:(一)进一步证实生前硅藻可经空气源性进入肺脏并存积于大循环内脏(肝、肾)的概念;(二)提示水中尸体肺脏如有大量硅藻检出,仅此即可作为诊断溺死的可靠依据;空气源性吸入及检验过程中的污染并不影响该检验结果对鉴定溺死的判断。种属分析溺死组肺与水样的主要硅藻种属相符,而肝、肾中硅藻计数及种属分析均无诊断意义。     

A promising microbiological test for the diagnosis of drowning

A number of biological and chemical tests have been developed over the years to determine whether a person was drowned. This study focuses on the potential of a microbiological test for detecting common bacterial markers of water faecal pollution such as faecal coliforms (FC) and faecal streptococci (FS) as possible indicators of drowning. A promising previous study was carried out on central and peripheral blood samples of 42 drowned victims (20 cases in saltwater and 22 cases in freshwater) and 30 not-drowned bodies. To improve the accuracy of our previous results and also in order to investigate a possible cause of a false positive due to pulmonary passive diffusion and subsequently endogenous or exogenous bacterial invasion of the blood in the post-mortem interval (PMI), the FC and FS test was applied to bodies submerged in water but died from causes other than drowning. In the present study, blood samples collected from the left ventricle (LV), right ventricle (RV), femoral artery (FA) and, femoral vein (FV) of 10 drowned victims (5 cases in freshwater and 5 cases in seawater) and 3 not-drowned individuals with bodies submerged in water for a while after death have been analysed. Preliminary results are in agreement with other reports dealing with diatoms and marine bacteria that suggest to exclude the hypothesis of a passive penetration of sufficient quantities of drowning medium into circulation after death or during the agonal period. Based on our results there is also no evidence of a relevant dissemination of endogenous micro-flora from the gastrointestinal tract affecting the FS and FC test. There are still several other factors that could influence the applicability of post-mortem FS and FC cultures for the diagnosis of drowning and they need further investigations. The present article provides only a glimpse of the potential of the FS and FC test as bacteriological method for the diagnosis of drowning.     

检测肺锶含量鉴定溺死的进一步研究

探索检测肺锶含量鉴定溺死的法医学意义，及水中浸泡时间因素对肺锶含量的影响和本方法的实际应用价值，用ICP检测溺死及死后入水浸泡时间较久的不同时间组（48～96小时）的家兔肺锶含量。结果表明：溺死组肺锶含量显著高于死后入水组（P＜0．01），死后水中浸泡时间（4天）对肺锶含量无明显影响，3例实际检案检测结果证实，本研究具有良好的应用前景。     

血清氟含量测定在溺死诊断上的意义

考虑到广东的水含氟量高,本文测定了溺死兔的血清氟含量,并与缢死后入水浸泡兔的血清氟含量进行对比。水中氟含量大约比正常人和动物血清氟高15倍。溺死后兔血清氟含量明显高于溺死前。相反,在对照的死后浸泡兔的血清氟含量稍低于死前。人与兔的血清氟含量相近。这提示,血清氟含量测定对高氟区的溺死诊断是有价值的。     

A study on the diagnosis of drowning by examination of lung chlorophyll(a) of planktons with a spectrofluorophotometer.

An investigation on the diagnosis of drowning by analysis of chlorophyll(a) (Chl.(a)) of planktons in the lung sample with a spectrofluorophotometer (SFPM) is reported. The diagnostic criteria or main points of death by drowning are suggested are according to our experimental studies. Meanwhile two cases of submersion in water were investigated and the causes of death were diagnosed correctly. It is concluded that examination of lung Chl.(a) of planktons could be used as a reliable diagnostic method in forensic practice.     

The Diagnostic Value of Quantitative Assessment of Diatom Test for Drowning: An Analysis of 128 Water‐related Death Cases using Microwave Digestion‐Vacuum Filtration‐Automated Scanning Electron Microscopy

The value of diatom test for the diagnosis of drowning remains controversial. The conventional forensic diatom test with low sensitivity is not a useful tool to provide accurate information about diatom in the tissues and organs. To improve the sensitivity of the diatom test, we developed a novel method called the Microwave Digestion‐Vacuum Filtration‐Automated Scanning Electron Microscopy (MD‐VF‐Auto SEM) method which resulted in a high recovery of diatoms. In this article, we analyzed 128 water‐related death cases. Our results showed that the MD‐VF‐Auto SEM method could achieve a much higher positive rate (0.97) in drowning cases. Large amounts of diatoms are retained, even concentrated, in the lung tissues during the intense breathing movement in drowning process. This might be useful for the diagnosis of drowning. Our research indicates that the MD‐VF‐Auto SEM method would be a valuable methodology in the study of diatom test for the forensic community.     

非溺死尸体肺脏硅藻最大值在溺死鉴定中的应用初探

探讨非溺死尸体肺脏硅藻最大值（即空气吸入与检验污染之和的最大值）在溺死鉴定中的应用价值。用硝化-光镜法检测贵阳地区40例非溺死尸体肺脏硅藻含量的最大值，同时作了8例溺死尸体肺脏硅藻检验。非溺死组肺脏硅藻最大值2个／5g；溺死组有7例为56～463个／5g，1例是2个／5g。表明（1）水中尸体肺脏硅藻检验值大于最大值（2个／5g），可考虑为溺死；显著大于最大值（本文溺死组7例56～463个／5g）则可鉴定为溺死；（2）等于或小于最大值，提示干性溺死或抛尸入水，可结合尸检发现及案情鉴别。     

Comparison between Temperature Gradient Gel Electrophoresis of Bacterial 16S rDNA and Diatom Test for Diagnosis of Drowning

When a body is discovered in water, it is difficult to conclude whether the cause of death was drowning, even today. Although diatom testing by the digestive method is classical, we hypothesized that aquatic bacteria, as well as diatoms, might be detected in drowned bodies, and conducted temperature gradient gel electrophoresis (TGGE)‐targeting 16S rDNA. DNA was extracted from the site water, and from heart blood and liver samples from 27 bodies concluded as drowning deaths by autopsy and subjected to TGGE after amplification of 16S rDNA by polymerase chain reaction. We observed whether the feature point of each 16S rDNA from the site water and blood or liver samples matched. Considerably higher correspondence was observed in drowned bodies, and the rate was higher than that achieved with the digestive method. Moreover, TGGE is safer than the digestive method. Our study suggests that this method can aid diagnosis of drowning.