强奸致孕形成部分性葡萄胎的检验分析

目的探讨强奸致孕案葡萄胎组织的DNA检验和STR结果分析。方法用DNA Typer TM15试剂盒对犯罪嫌疑人、受害人血样和流产胚胎组织进行荧光复合STR基因座扩增检测。结果检测的一例流产胚胎组织DNA的STR峰谱表现出部分3条带,且3条带中有两个等位基因来源于犯罪嫌疑人,另外一个来源于受害人,推断为单卵双精子受精的部分性葡萄胎。结论应用STR分型技术可以推断葡萄胎的DNA来源和受精类型,为亲缘关系鉴定提供依据。     

葡萄胎的DNA检验

本文利用STR复合扩增技术对1例强奸致孕案件中的胚胎组织进行了检验,结果获得了一种罕见的DNA分型（见图1）,其15个STR基因座均表现为纯合子。结合临床与病理检验结果,确定为葡萄胎。     

烟蒂DNA分型的研究

目的 研究烟蒂中DNA提取及其检验。方法 用Chelex-100法提取170枚烟蒂样本的DNA,进行PCR扩增及STR检验。结果 除1名志愿者提供的21枚烟蒂外层纸未能检出STR基因分型外,其余烟蒂外层纸均得到分型结果。加入少许烟丝的样本未能检出STR分型,与口唇接触的海绵有时可检出基因型,6个月内的烟蒂可检出小片段基因座。结论 烟蒂能进行DNA分型,在法医检案中具有应用价值。     

荧光STR复合扩增试剂盒的评估过程探索

STR复合扩增检验技术是目前法医DNA检验技术中最重要也是最常用的技术种类之一，随着荧光检测技术和毛细管电泳技术的发展，特别是DNA数据库建设中丰要采用STR复合扩增技术进行基因分型，大大拓展了STR复合扩增检验应用范围。与此同时，STR复合扩增检验试剂成为影响检验质量的重要因素，关系到样本检验分型结果，而分型数据是为法庭提供证据的直接依据，     

环氧乙烷消杀DNA污染效果初探

目的初探环氧乙烷消杀DNA污染的效果。方法收集98例分别含有唾液、皮屑、汗斑、毛发、血斑、肋软骨的法医物证样本,分两组进行环氧乙烷灭菌6h和8h,提取DNA后扩增,使用3130XL或3500XL测序仪检测进行STR分型。结果 EO 6h组44例样本中有2例口腔拭子检出阳性结果,EO 8h组54例样本中有1例毛发检出阳性结果,阳性样本STR图谱表明仅有少量DNA残留,其余生物样本未检测到STR图谱。结论环氧乙烷能有效消杀DNA污染,可适用于DNA检验耗材的灭菌。     

运用酚-氯仿法结合磁珠法提取蝇蛆体内人类DNA

目的建立运用酚-氯仿法结合磁珠法从蝇蛆嗉囊内提取人类DNA的方法,从而提高STR分型检验的灵敏度。方法采用酚-氯仿法对蝇蛆嗉囊内容物中的人类DNA进行提取,提取产物经磁珠法纯化浓缩后用QuantifilerTM人类DNA定量试剂盒在7500型实时荧光定量PCR仪上进行PCR定量,再用AmpF■STR IndentifilerTM试剂盒在3130XL-Avant遗传分析仪上对这些DNA样本进行STR分型。结果本研究建立的方法可增加模板DNA浓度约为单独使用酚-氯仿法的2倍。用此方法提取到的DNA浓度[（0.218±0.041）ng/μL]可获得全部16个STR分型结果。结论酚-氯仿法结合磁珠法可以有效地提高提取到的人类DNA样本STR分型检验的灵敏度,对于从事法医昆虫学方面研究的工作者有较好的实用价值。     

改良IPEP法用于痕量DNA检测的实验研究

目的探讨改良扩增前引物延伸(IPEP)法对痕量DNA样本STR检测分型的效果。方法用改良IPEP法对痕量样品DNA进行全基因组扩增(WGA),扩增产物用实时荧光定量PCR技术定量、用AmpFLSTR~ Indentifiler~试剂盒作基因型检测。结果该方法可增加模板DNA约200~1100倍。基因组DNA不低于0.025ng时,可获得15个STR基因座和Amelogenin性别基因座的分型结果。基因组DNA0.01~0.025ng时,可获得9个以上基因座的分型结果。结论改良IPEP法可有效提高痕量DNA样本STR分型检验的灵敏度,有较好的实用价值。     

尿液及尿斑DNA分型的研究

目的研究尿液及尿斑的DNA提取及其检验。方法用Chelex100法及QIAampMiniKit提取尿液及尿斑样本中的DNA,进行PCR扩增及STR检验。结果新鲜的及存放时间在12h以内的尿液样本能得到较好的分型结果;存放2d左右的尿液样本有50%能检出基因型;存放7d及更长时间的尿液样本全部不能检出基因型;尿斑样本的分型成功率很低。结论较新鲜的尿液样本均能进行DNA分型,在法医检案中具有应用价值。     

DNA IQ^TM SYSTEM在疑难指甲DNA检验中的应用

目的探索DNA IQTMSYSTEM在疑难指甲DNA提取中的应用。方法 15份疑难指甲采用Chelex方法检验没有成功获得STR分型图谱,采用DNA IQTMSYSTEM提取法并纯化,采用Identifiler PLUS试剂盒进行复合扩增,产物经ABI3130XL型DNA基因分析仪检测。结果成功获得15例疑难指甲的STR基因座DNA分型。结论 DNA IQTMSYSTEM方法能快速、有效提取疑难指甲DNA进行STR分型。     

不同分型方法的STR分型差异

目的调查不同的STR分型系统之间分型的一致性。方法 10 0例不同个体的DNA样本分别用单位点聚丙烯酰胺凝胶银染法和PowerPlex16System试剂盒对 13个法医学常用STR位点进行基因分型 ,并比较两种不同分型系统间的分型结果。结果 1例样本在D8S1179位点出现了分型不一致的结果 :银染法的基因型为 12 / 14 ,而用PowerPlex16System试剂盒的分型则为 12 / 15。结论不同的STR分型系统可导致不同的基因分型     

指甲DNA的STR分型研究

目的 研究尸体所处环境、指甲DNA提取部位及提取方法对STR分型的影响。方法 对案件中不同条件腐败尸体指甲,使用不同部位、不同体系和时间消化,酚-氯仿法提取指甲核DNA,进行PCR扩增及STR分型。结果 提取指甲甲体、甲根部位均可获得STR分型。结论 指甲是法医检案中一类具有实用价值的检材。     

DNA typing of human remains found in damp environments

DNA typing is often used to determine identity from human remains. The environment to which the material has been exposed, however, is crucial for the success of the investigation. Damp conditions in particular can cause a rapid degradation of DNA, even in bone and teeth, and thus reduce the chances of successful typing. Here, we present the results of investigations performed on four skulls that had been lying in a damp environment for periods ranging from almost 1 year to about 45 years. In none of these cases was DNA typing successful on bone or, where present, on teeth. Where remnants of brain tissue were used, however, complete STR typing was possible in one case, partial STR typing in another, and mtDNA sequencing could be carried out in three cases. These findings suggest that brain tissue is relatively resistant to putrefaction in damp environments and, unlike bone, appears to exhibit a certain degree of protection against DNA degradation.     

Validation and casework application of a Y chromosome specific STR multiplex

A series of validation experiments was performed for a Y chromosome specific STR multiplex system following the suggestions made by the Technical Working Group DNA Analysis Methods (TWGDAM). The multiplex PCR products were detected on Perkin-Elmer 373 and 377 automated sequencers using two labeling colors. No problems regarding the stability, robustness and sensitivity of the Y STR multiplex were observed. Mixture studies revealed a cut off rate similar to autosomal STRs for mixtures of male DNAs and no interference of any female admixture. The comparison of the Y STR results to the autosomal typing results for 56 nonprobative semen stains and swabs, showed a slightly higher success rate in detecting the semen donor's alleles for the Y STR multiplex. Two examples are shown to illustrate the usefulness of Y STR typing for DNA mixtures. In one case the Y STR results confirmed an isolated exclusion; in the other case, the interpretation of a mixture was clarified since the Y STR results proved the presence of DNA from at least two semen donors. Y STR typing is a valuable addition to the forensic DNA testing panel.     

Identification of gestational trophoblastic disease in a sexual assault case

In this study, gestational trophoblastic disease (GTD) was observed by short tandem repeat (STR) typing from the aborted tissues in a sexual assault case. By histological screening, the fetal tissue could not be distinguished from the maternal tissue in this case. Therefore, five specimens were collected randomly from the aborted tissues for DNA analysis. STR typing was performed by the commercial ABI Identifiler kit. The results showed that three specimens were of the maternal origin, one was a mixture of the mother and male fetus, and the other one was of male fetal origin with partial triploid. Three alleles were identified in each locus of D8S1179, D7S820 and VWA for the fetal specimen. For these three alleles, one matched the maternal origin and the others matched the putative paternal origin (suspect). Analysis of the Y-STR by using the commercial ABI Y-Filer kit, the fetal types matched the types of the suspect. We reported the case of partial mole on forensic evidence and gave the valuable information from its identification.     

Validation and casework application of a Y chromosome specific STR multiplex

A series of validation experiments was performed for a Y chromosome specific STR multiplex system following the suggestions made by the Technical Working Group DNA Analysis Methods (TWGDAM). The multiplex PCR products were detected on Perkin-Elmer 373 and 377 automated sequencers using two labeling colors. No problems regarding the stability, robustness and sensitivity of the Y STR multiplex were observed. Mixture studies revealed a cut off rate similar to autosomal STRs for mixtures of male DNAs and no interference of any female admixture. The comparison of the Y STR results to the autosomal typing results for 56 nonprobative semen stains and swabs, showed a slightly higher success rate in detecting the semen donor’s alleles for the Y STR multiplex. Two examples are shown to illustrate the usefulness of Y STR typing for DNA mixtures. In one case the Y STR results confirmed an isolated exclusion; in the other case, the interpretation of a mixture was clarified since the Y STR results proved the presence of DNA from at least two semen donors. Y STR typing is a valuable addition to the forensic DNA testing panel.     

The personal identification of many samples recovered from under the sea

An automatic and rapid DNA typing system was employed for personal identification, using fragmentary tissue samples from victims in an airplane accident. Two victims were crushed into small pieces, and 33 samples suspected to belong to them were recovered from under the sea. From each sample, 10 mg was used for testing. The parents' bloods of two presumptive victims were also examined. DNA extraction from samples was performed by the NaI method, and the obtained DNA samples were analyzed with the ABI PRISM system. Among 33 samples, 31 samples were identified to be human tissues, possibly from two victims. The other two samples seemed to be parts of marine animals. ABO blood group, STR polymorphism, and mitochondrial DNA polymorphism typing were possible in every examined human sample. Two victims' fragmentary tissues were identified by determining ABO genotype, STR type and mitochondrial DNA type. The system we employed enabled an accurate typing of many fragmentary samples in a short time, thus contributing to the fast and secure identification of many victims in such cases as big air accidents.     

Analysis of mitochondrial SNPs in addition to conventional STR-typing in a case of aggravated theft

In the field of forensic DNA typing, the analysis of Short Tandem Repeats (STRs) can fail in cases of degraded DNA. The typing of coding region Single Nucleotide Polymorphisms (SNPs) of the mitochondrial genome provides an approach to acquire additional information. In the examined case of aggravated theft, both suspects could be excluded of having left the analyzed hair on the crime scene by SNP typing. This conclusion was not possible subsequent to STR typing. SNP typing of the trace on the torch light left on the crime scene increased the likelihood for suspect no. 2 to be the origin of this trace. This finding was already indicated by STR analysis. Suspect no. 1 was excluded for being the origin of this trace by SNP typing which was also indicated by STR analysis. A limiting factor for the analysis of SNPs is the maternal inheritance of mitochondrial DNA. Individualisation is not possible. In conclusion, it can be said that in the case of traces which cause problems with conventional STR typing the supplementary analysis of coding region SNPs from the mitochondrial genome is very reasonable and greatly contributes to the refinement of analysis methods in the field of forensic genetics.     

Estimating the probability of allelic drop-out of STR alleles in forensic genetics

In crime cases with available DNA evidence, the amount of DNA is often sparse due to the setting of the crime. In such cases, allelic drop-out of one or more true alleles in STR typing is possible. We present a statistical model for estimating the per locus and overall probability of allelic drop-out using the results of all STR loci in the case sample as reference. The methodology of logistic regression is appropriate for this analysis, and we demonstrate how to incorporate this in a forensic genetic framework.