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。     

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。     

宁波甬江水域夏冬季节溺死兔内脏硅藻16SrDNA的鉴定

目的采用PCR法检测夏季7月和冬季12月宁波甬江水域溺死家兔内脏组织中硅藻16SrDNA,评估其在夏季7月和冬季12月溺死鉴定中的应用价值。方法于夏季7月和冬季12月分别选取30只大白兔,总计60只大白兔,随机分为溺死组(n=10)、死后入水组(n=10)、空气栓塞组(n=10)。各组分别提取心、肝、肺、肾组织,应用PCR技术检测上述兔内脏硅藻16SrDNA。结果与死后入水组比较,夏季7月兔溺死组心、肝、肺、肾组织中硅藻16SrDNA检出率明显增高(P<0.05);而冬季12月溺死组仅心、肺组织中检见硅藻16SrDNA,与死后入水组比较无明显差异(P>0.05);夏季7月溺死兔组心、肝、肺、肾组织中硅藻16SrDNA检出率明显高于冬季季12月溺死兔组(P<0.05);夏季7月和冬季12月空气栓塞组心、肝、肺、肾组织中硅藻16SrDNA均未检出。结论宁波甬江水域夏季溺死兔中硅藻16SrDNA检出率高,PCR技术可用于溺死诊断;而冬季硅藻16SrDNA检出率低,运用该技术诊断溺死应慎重。     

溺死大鼠肺组织AQP-1、AQP-4的表达

目的观测生前溺死与死后抛入河水中大鼠肺组织水通道蛋白-1(aquaporin-1,AQP-1)、AQP-4的表达变化。方法将30只健康雄性Wistar大鼠随机分为河水溺死组、抛尸入水组及脱颈致死组。HE染色观察各组大鼠肺组织形态学变化,实时荧光定量PCR法检测各组大鼠肺组织AQP-1、AQP-4 m RNA的表达,免疫组织化学、Western印迹法检测其蛋白表达。结果免疫组织化学法和Western印迹法检测河水溺死组AQP-1蛋白的表达高于抛尸入水组和脱颈致死组(P0.05)。免疫组织化学法显示河水溺死组AQP-4蛋白的表达高于抛尸入水组和脱颈致死组(P0.05),而Western印迹法未检测出三者的差别(P0.05)。河水溺死组大鼠肺组织的AQP-1、AQP-4 m RNA表达高于抛尸入水组(P0.05)。结论河水溺死组的大鼠在急性肺损伤时肺组织AQP-1、AQP-4 mRNA及蛋白表达增高可能对生前溺死与死后抛尸的鉴别有一定意义。     

Micro-XRF法检测肺内抗酸性硅质颗粒及其在溺死诊断中的应用

目的利用微束X射线荧光光谱（microbeam X-ray fluorescence,Micro-XRF）分析技术检测肺内抗酸性硅质颗粒,并探讨其在法医学溺死诊断中的应用价值。方法将32只大白兔随机分为溺死组（n=12）、死后入水组（n=10）和对照组（n=10）,分别提取现场水样和各组肺组织。采用Micro-XRF法测定现场水样和肺组织中抗酸性硅质颗粒的面积含量。结果现场水样中抗酸性硅质颗粒面积含量为4.4mm^2/mL;溺死组、死后入水组、对照组肺组织中抗酸性硅质颗粒面积含量分别为（25.30&#177;10.95）mm^2/g、（1.68&#177;0.63）mm^2/g、（1.65&#177;0.85）mm^2/g;溺死组肺组织中抗酸性硅质颗粒面积含量较死后入水组、对照组差异有统计学意义。结论肺内抗酸性硅质颗粒面积含量可作为一种溺死诊断的指标,Micro-XRF测定法灵敏度高、分析速度快,在法医学溺死诊断中具有潜在的应用价值。     

微波消解-扫描电镜联用法在溺死诊断中的应用

目的探讨微波消解-扫描电镜联用法在溺死诊断中的应用价值。方法收集已知死因的尸体标本105例,其中水中尸体85例(生前溺死70例,死后抛尸入水15例),陆地自然死亡尸体20例。水中死亡案例同时收集落水处水样。分别用微波消解-扫描电镜联用法(方法 A)和硝酸破机-光镜联用法(方法 B)对上述尸体的离体肺、肝、肾、骨髓组织及水样进行硅藻定性、定量检测。结果①溺死尸体的肺、肝、肾、骨髓中及落水处水样硅藻检出率:A法分别为100%、94.3%、92.9%、82.9%、100%,硅藻检验阳性率为100%;B法分别为90%、62.9%、51.4%、28.6%、92.9%,硅藻检验阳性率为65.7%。②两种方法检出的硅藻种类与落水处水样中硅藻的种类均一致。③两种方法在死后入水尸体离体的肺中也检出少量硅藻(<3个/2g肺组织),但在死后入水尸体的其它脏器及陆地自然死亡尸体脏器中均未检出硅藻。结论微波消解-扫描电镜联用法较硝酸破机-光镜联用法对尸体离体组织脏器中的硅藻检出率高,方法灵敏,定性准确。     

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。     

微波消解-扫描电镜联用检测脏器内硅藻

目的介绍一种微波消解-扫描电镜联用检测脏器内硅藻的新方法。方法大白兔30只,随机分为生前溺死组（n=15）和死后溺尸组（n=15）。提取兔肺、肝、肾、股骨骨髓和现场珠江水样,采用建立的微波消解-扫描电镜联用法检测脏器组织和水样中的硅藻,并与硝酸乙醇消解-扫描电镜联用的方法进行比较。结果生前溺死组的兔肺、肝、肾、股骨骨髓组织中大多数观测到与现场珠江水样一致的硅藻,微波消解-扫描电镜联用法检测脏器内硅藻的平均含量分别为：2505.2个/2g肺,18.7个/10g肝,6.5个/10g肾,6.3个/0.5g骨髓;肺与肝、肾、骨髓检出硅藻的阳性比例为86.7%,脏器硅藻检出含量和硅藻检验阳性比例均明显高于硝酸乙醇消解-扫描电镜联用法所测值。死后溺尸组的兔脏器组织均未观测到硅藻。结论微波消解-扫描电镜联用法检测脏器内硅藻,高效、安全、环保,硅藻检验灵敏度高,降低了劳动强度,提高了定性定量分析准确度,且能有效避免污染,在法医学溺死鉴定中具有良好的应用价值。     

PCR-DHPLC法检测硅藻SSU基因在溺死鉴定中的应用

目的采用PCR-DHPLC法检测硅藻SSU基因,评估其在溺死鉴定中的应用价值。方法 60只实验兔随机分为生前溺死（水中溺毙）、死后入水（空气栓塞致死后入水）、对照组（空气栓塞致死后不做处理）;溺死人体脏器组织;取各组织检材提取硅藻DNA,PCR扩增硅藻特异的核糖体小亚基（SSU）片段,用琼脂糖凝胶电泳检测、DHPLC检测分析。结果 6份硝酸消化法检测阴性的溺死人体器官组织检材经PCR及琼脂糖凝胶电泳检出5例阳性。生前溺死组肺、肝、肾硅藻检出率分别为100%、90%、85%,死后入水组仅肺检出硅藻（15%）,对照组各组织均为阴性;生前溺死组检出率明显高于死后入水组（P〈0.05）。10份溺死人体器官组织检材采用DHPLC法检出硅藻种类明显多于微波消解-扫描电镜法（P〈0.05）。脏器检出硅藻种类与溺死点水样一致。结论采用PCR-DHPLC法检测硅藻SSU基因,有助于溺死鉴定和溺死地点的推断,具有法医学应用价值。     

溺死大鼠肺组织水通道蛋白1的表达

目的检测生前溺死与死后抛尸的肺组织水通道蛋白的表达。方法取2种死亡方式条件下大鼠肺组织,用免疫组织化学方法检测肺组织中水通道蛋白1表达的分布特征。结果两种死亡条件下肺泡间质和支气管周围的毛细血管内皮及肺泡上皮均有AQP1的阳性表达,但积分光密度值(intergratedopticaldensity,IOD)值有显著性差别。结论AQP1在大鼠两种溺死条件下表达差别有统计学意义。     

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。     

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。     

Microbiota Composition and Pulmonary Surfactant Protein Expression as Markers of Death by Drowning

Pathological diagnosis of drowning remains a challenge for forensic science, because of a lack of pathognomonic findings. We analyzed microbiota and surfactant protein in the lungs for a novel diagnosis of drowning. All rats were divided into drowning, postmortem submersion, and control groups. The water, lungs, closed organs (kidney and liver), and cardiac blood in rats were assayed by targeting 16S ribosomal RNA of Miseq sequencing. Lung samples were analyzed by immunohistochemical staining for surfactant protein A. The closed organs and cardiac blood of drowned group have a lot of aquatic microbes, which have not been detected in postmortem submersion group. Furthermore, intra‐alveolar granular staining of surfactant protein A (SP‐A) was severely observed in the drowned group than the postmortem submersion and control groups. The findings suggested that the presence of aquatic microbiota in the closed organs and increased expression of SP‐A could be markers for a diagnosis of drowning.     

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。     

勒福特王水消解法检验动物器官硅藻的法医学应用

目的研究勒福特王水消解法对动物器官中硅藻检验的法医学应用。方法将勒福特王水消解-滤膜富集-扫描电镜观察法与传统强酸消解-离心富集-光学显微镜观察法比较,对生前入水和死后入水的实验动物肺、肝和肾组织中的硅藻数量、检验时间、检出率以及观察效果进行研究,并进行统计学分析。结果生前入水组用勒福特王水消解-滤膜富集-扫描电镜观察法检出肺、肝、肾组织中的硅藻数量均多于传统方法(P0.05),检验时间少于传统方法(P0.05),检出率无差异(P0.05),观察效果优于传统方法。结论勒福特王水消解-滤膜富集-扫描电镜观察法具有简单、高效、定性定量分析准确的特点,该方法成本低廉,操作简单,具有较好的实用价值。     

The usefulness of lung surfactant phospholipids (LSPs) in the diagnosis of drowning

The authors have studied the usefulness of some lung surfactant phospholipids (LSPs) isolated from lung tissues as markers of drowning. Two different groups of rabbits were sacrificed by drowning in fresh and salt water, and their phospholipid compositions were compared with those of a non-drowned control series. For the phospholipids studied in lung lavages (phosphatidyl choline, phosphatidyl ethanolamine, and phosphatidyl glycerol) the proportions differed between the control group and the drowned group, and between the fresh-water and salt-water drowned animals. According to these results, the lipids we have analyzed can be employed as markers in forensic autopsies, where it is necessary to differentiate between death by drowning and postmortem immersion and between fresh-water and salt-water drowning. In lung tissue, only phosphatidyl choline and phosphatidyl inositol showed significative differences. These results also confirm that LSPs are strongly affected in drowning.     

A sandwich enzyme immunoassay for pulmonary surfactant protein D and measurement of its blood levels in drowning victims

A sensitive sandwich enzyme immunoassay for human pulmonary surfactant protein D (SP-D) was developed and used to examine the blood SP-D levels of drowning victims. Human SP-D was purified from amniotic fluid by chromatographic methods, and an antibody against human SP-D was prepared. A polystyrene ball coated with anti-SP-D IgG was incubated with purified human SP-D, and then with anti-SP-D Fab'-peroxidase conjugate. Peroxidase activity bound to the polystyrene ball was assayed by fluorometry using 3-(4-hydroxyphenyl)propionic acid as the hydrogen donor. The detection limit of human SP-D was 5.2 pg per assay tube. Examination of cross-reactions of this sandwich enzyme immunoassay with proteins from other human organs showed it to be highly specific for lung, and Northern blot analysis detected specific SP-D mRNA expression only in lung. The SP-D concentration of normal human serum was 6.4+/-2.7 (mean+/-S.D.) ng ml(-1) (n=20). The recovery rates of 0.52 ng and 5.2 ng SP-D added to 5 microl normal human serum were 93.6+/-2.7% and 93.6+/-6.1%, respectively. Blood SP-D levels of victims from the saltwater drowning group (n=14) revealed higher concentrations (105.8+/-53.7 ng ml(-1)), while freshwater drowning victims (n=12) were estimated to be 74.1+/-43.9 ng ml(-1). The SP-D levels of 15 subjects who died of hemorrhage (n=5), heart failure (n=8), traumatic shock (n=1), and electrocution (n=1) were lower (22.0+/-8.5 ng ml(-1)), and those of asphyxia victims (n=10) were slightly higher (36.2+/-17.1 ng ml(-1)) than those of other causes of death, except for drowning. These results suggest that in drowning victims, SP-D flowed into the systemic circulation by physiological and physical mechanisms, and the differences of blood SP-D levels between saltwater drowning and freshwater drowning victims are presumed to be influenced by the type of agony and/or the length of survival time in water.