儿童骨骼特征的组织学研究

目的研究儿童骨骼的组织学特征,为儿童骨骼残片的法医学鉴定提供科学依据。方法提取儿童四肢长骨骨片,制作骨骼的组织切片,在显微镜下观察内、外环骨板,骨单位,骨细胞的组织学结构,比较儿童骨骼与动物及成人骨骼的组织学区别。结果儿童骨骼的骨单位形态与成人相似,骨单位间存在大量的内层骨板,与动物的骨组织特征相似。结论根据骨组织学特征,可以确定儿童的骨骼残片。     

法医骨组织学研究

在实际检案中 ,当现场发现的骨骼残片体积较小时 ,用解剖学观察无法进行骨骼残片的法医鉴定 ,需使用骨组织学的方法进行骨骼残片的个体识别。目前 ,这是法医人类学中一门较活跃的领域 ,即法医骨组织学。法医骨组织学的内容主要包括两个方面 :(1)骨骼残片是否属于人类骨骼 ,或属于何种动物骨骼。这方面的研究包括人类骨骼的组织学特征研究及不同动物的组织学特征研究。 (2 )人类骨骼个体识别的组织学研究。这方面的研究主要包括 ,人类骨骼的组织学特征的年龄判断 ,例如股骨、胫骨、肱骨、锁骨等 ,以及使用骨组织学方法 ,进行人类骨骼的年龄评价的准确性研究。本文对上述内容进行了综述。     

人体骨骼上菜刀痕迹的检验及同一认定

目的 对人体骨骼上刀痕进行致伤工具同一认定的检验和研究.方法 用同一把菜刀的相同部位分别砍击骨骼与新鲜灌木,通过对骨骼上刀痕进行组织学处理以显现致伤工具的痕迹,并使用比对显微镜将骨骼与灌木上的砍痕进行比对,分析骨质断面的痕迹特征.结果 菜刀在骨骼上形成的砍切痕迹线条与比对样本的砍切痕迹线条可以完全拼接.结论 显微镜下可直观、清晰地观察到致伤工具在骨骼上留下的痕迹,为致伤工具的推断提供了新的方法.     

骨骼种属鉴定的组织学研究

目的 探求骨骼残渣的种属鉴定的组织学方法。方法 对人体不同部位骨骼,及常见动物骨骼的 77张骨组织学切片,在光镜下进行了骨组织学形态学研究。结果 不同动物骨组织学的形态学特征存在明显差异,其主要差别有：内、外环骨板的形态和相对厚度;哈氏系统之间的骨板的形态和哈氏系统的大小;哈氏环层骨板的数量及骨陷窝的数量等。结论 骨组织学的特征,不仅可以区分人与动物骨骼的残渣,也可以对不同动物的骨骼残渣进行区分。     

人与动物短骨的区别

白骨案件现场往往仅能找到少量骨碎片及小短骨,由于这类骨骼体积小,难与动物骨骼区别,因此白骨化残骸首先要确定骨骼是否为人骨,快速的判断骨骼种属是个体识别的基础。笔者通过1例白骨残骸的鉴定,讨论人与动物小短骨的形态学差异。     

烧骨残片种属鉴定的研究

为了找出常见动物骨骼焚烧残片的种属鉴定方法,笔者对猪、羊,股骨及肱骨的断端,猪、羊、牛颅骨的残片(额顶部),焚烧后进行了观察及测量,并与人类股骨、肱骨及焚烧的颅骨残片进行了比较.结果发现,长骨滋养孔的位置,骨干骨壁厚度,以及颅骨厚度,颅缝形态及内板表面特征等方面,是鉴定骨骼残片种属的有价值的特征.根据对常见动物长骨及颅骨残片的现察及研究,提出了骨骼残片种属鉴定的方法.     

根据股骨组织形态学变化进行骨骼种属鉴别

目的通过对成年人、成体黄牛、马、家猪、山羊、绵羊、狗、猫、长毛兔、鹅、鸭、鸡共12个种属动物股骨组织形态学结构特征的研究,建立一个有效的各类动物间种属鉴别的方法。方法在征得家属同意后,在尸检中取成人(20岁以上)右股骨中段约4cm,同时,收集黄牛、马、家猪、山羊、绵羊、狗、猫、长毛兔、鹅、鸭、鸡共11种常见动物右腿股骨,取中段约4cm,脱钙后制作成骨组织切片,在光学显微镜下观察,将显微镜下的图像录入电脑,选取24个指标进行分析。结果人与其他动物、以及各被检动物之间在骨单位数量等13个指标上具有显著差异,用这些指标建立种属判别数学模型,结果这些动物之间的判别率也可达89.4%。结论股骨中段骨密质的组织学结构具有明显的种属特征,且骨单位形态和数量呈现明显的生物进化趋势。根据这些特征可以有效地进行种属鉴别。     

基于股骨组织形态学变化进行种属鉴别CSCD

目的研究成年人,成年黄牛、马、家猪、山羊、绵羊、狗、猫、长毛兔、鹅、鸭、鸡共11种动物股骨组织形态学结构,建立有效的种属鉴别方法。方法取进行尸体检验的成人(20周岁以上)右股骨中段约4 cm,同时取11种常见动物右腿股骨中段约4 cm,脱钙后制作成骨组织切片,在光学显微镜下观察,选取25个指标按人与哺乳动物、人与家禽、人与11种动物进行逐步判别分析。结果股骨中段骨密质的组织学结构具有明显的种属特征,且骨单位形态和数量呈现明显的生物进化趋势。选出11项指标建立人与11种动物的种属判别方程,人与哺乳动物的正确判别率可达96.3%,人与家禽的正确判别率可达100%,人与11种动物的正确判别率可达89.4%。结论本研究建立的人与其他种属动物的判别方程具有较高的正确判别率,可以用于实际检案中的种属鉴别。     

骨密度检测在野生动物司法鉴定领域的应用前景

脊椎动物的体内存在着骨骼,骨密度代表了骨骼中骨矿物质的含量.通过对骨密度测量的多种方法及其基本原理进行介绍.因不同种属动物骨骼存在着差异,通过实验验证测量“面密度”的骨密度检测方法在动物骨骼检测时存在着很大的局限性,定量CT法（Qcantitative computed Tomography,QCT）测量的是“体密度”,能够避免各种“面密度”检测方法的缺陷,在动物骨密度检测时应当作为首选.最终提出骨密度检测方法可应用于动物司法鉴定领域.     

基于股骨组织形态学变化进行种属鉴别

目的研究成年人,成年黄牛、马、家猪、山羊、绵羊、狗、猫、长毛兔、鹅、鸭、鸡共11种动物股骨组织形态学结构,建立有效的种属鉴别方法。方法取进行尸体检验的成人(20周岁以上)右股骨中段约4 cm,同时取11种常见动物右腿股骨中段约4 cm,脱钙后制作成骨组织切片,在光学显微镜下观察,选取25个指标按人与哺乳动物、人与家禽、人与11种动物进行逐步判别分析。结果股骨中段骨密质的组织学结构具有明显的种属特征,且骨单位形态和数量呈现明显的生物进化趋势。选出11项指标建立人与11种动物的种属判别方程,人与哺乳动物的正确判别率可达96.3%,人与家禽的正确判别率可达100%,人与11种动物的正确判别率可达89.4%。结论本研究建立的人与其他种属动物的判别方程具有较高的正确判别率,可以用于实际检案中的种属鉴别。     

人与狗、猪、牛、羊长骨哈氏系统图像分析的比较

目的探讨人与狗、猪、牛、羊长骨的哈氏系统的形态特点、图像分析特点及其鉴别要点。方法制作人与狗、猪、牛、羊长骨中段横切磨片35张,光镜下观察比较哈氏系统,并在研究型显微镜下进行图像分析。结果人骨无丛状骨和骨单位带;人与狗、猪、牛、羊骨的哈氏系统在形状、大小、分布位置、均匀程度等方面存在明显差异;人骨哈佛骨板层数最多,哈氏系统直径最大;中央管直径和面积百分比的图像分析结果显示人与动物骨的差异均有显著意义。结论(1)丛状骨、骨单位带在种属鉴定中可作为人骨的排除指标;(2)人骨与狗、猪、牛、羊骨在哈氏系统结构方面有明显区别;(3)利用图像分析进行种属鉴定,中央管面积百分比是区别人骨与动物骨的重要参考指标。     

丛状骨和骨单位带的种属特征及法医学应用价值

目的 探讨丛状骨和骨单位带的种属特征及其法医学应用价值。方法 人及猪、牛、羊、狗长骨中段横切磨片35张，在光学显微镜下观察骨组织中丛状骨和骨单位带的形态学特征。结果 丛状骨和骨单位带在猪、牛、羊、狗的密质骨中广泛存在，人骨组织中几乎不见；同种动物不同个体之间骨组织学结构也存在差异。结论 观察丛状骨和骨单位带是根据人骨鉴别种属的重要排除指标。     

Validity of the use of porcine bone in forensic cut mark studies

Porcine bone is often used as a substitute for human bone in forensic trauma studies, but little has been published on its comparative mechanical behavior. The factors affecting mechanical properties and therefore selection of bone models are complex and include the age of the animal at death, and physiological loading conditions, the latter being of particular relevance when using a quadrupedal animal as a human substitute. The regional variation in hardness of adult and infant porcine bones was investigated using Vickers’ indentation tests and compared to published data for human limb bones to relate differences to inherent genetic effects and loading influences, and to examine the validity of the porcine‐human model. Significant differences in hardness were observed both along and around the adult porcine humerus and femur, but no significant differences were found along the length of the infant bones. Significant differences were found between the forelimb and hindlimb, but only in the infant specimens. The hardness values for porcine adult cortical bone from the femur (52.23 ± 1.00 kg mm^?2) were comparable to those reported in the literature for adult human cortical bone from the fibula, ilium, and calcaneus. These data will help inform subject selection in terms of both species and bone type for use in future trauma studies.     

Radiological, forensic, and anthropological studies of a concrete block containing bones

Multidisciplinary forensic, anthropological, and radiological studies of bone fragments encased in a concrete block were carried out to determine whether or not the bones were human. Multislice computed tomography (MSCT) investigation was performed before the bones were removed from the concrete. MSCT study pinpointed the location of the bone fragments within the concrete block, which was helpful for their extraction and recovery, and identified most of their types and nature. Osteological study on dry bones provided more accurate identification of the bones and of their side. According to both methods, the human skeletal remains were compatible with those of a child, aged 8-13 years old, with a minimum height of 128 cm. Neither investigation identified sex or racial phenotype. Both studies identified the skeletal remains as consisting of two animal and five human bones. Furthermore, both methods revealed that the concrete completely encased bones, suggesting a secondary burial.     

Effect of Temperature on Bone Tissue: Histological Changes

The analysis of burned human remains has been of great interest among forensic anthropologists largely due to the difficulty that their recovery, classification, reconstruction, and identification present. The main purpose of this analysis is to present histological methodology for the interpretation of bones altered by thermal processes. We include analyses of the microscopic changes among bones exposed to different temperatures, with the goal of establishing categories of histological morphology in relation to fire temperature. Samples of bone (ilium) were exposed systematically to controlled temperatures. Analysis of the resulting histological changes has allowed the formation of a clear four‐stage classification of the alterations observed. This classification should prove useful in assessing bone changes in relation to temperature of exposure, particularly in cases where this temperature was previously not known.     

Histological Determination of the Human Origin of Bone Fragments

Abstract:  A frequently encountered task in the forensic scenario is verification of the human origin of severely degraded fragments of bone. In these cases histological methods which consider osteon size and morphology can prove to be useful. The authors in the present study verify the applicability of published algorithms to flat and subadult bones from human, dog, cat, cow, rabbit, sheep, pig, chicken, quail, and turkey samples. Metric analysis was performed on 2031 Haversian canals. Analyses carried out on human samples confirmed a success rate of around 70% on long adult bones; however the percentage of wrong answers was particularly high in the case of newborns and older subadults as well as on flat bones in general. Results therefore suggest that such regression equations should be limited only to bone fragments from long adult bones.     

Determining the human origin of fragments of burnt bone: a comparative study of histological, immunological and DNA techniques.

In situations where badly burnt fragments of bone are found, identification of their human or non-human origin may be impossible by gross morphology alone and other techniques have to be employed. In order to determine whether histological methods were redundant and should be superseded by biomolecular analyses, small fragments of artificially burnt bone (human and non-human) were examined by quantitative and standard light microscopy, and the findings compared with newer biomolecular analyses based on identifying specific human albumin by ELISA and amplifying human mitochondrial DNA by PCR. For quantitative microscopy, reference data were first created using burnt bones from 15 human and 20 common domestic and farm animals. Measured osteon and Haversian canal parameters were analysed using multivariate statistical methods. Highly significant differences were found between values for human and non-human bone, and a canonical discriminant function equation was derived, giving a predicted correct classification of 79%. For the main study, samples of cortical bone were taken from three fresh cadavers, six human skeletons and ten freshly slaughtered animals and burnt by exposure to temperatures ranging from 800 to 1200 degrees C; charred fragments of human cortical bone from two forensic cases were also tested. Quantitative microscopy and canonical discriminant function gave the correct origin of every sample. Standard microscopy falsely assigned burnt bone from one human skeleton and one forensic case to a non-human source, but otherwise gave correct results. Human albumin was identified in five individuals, including one of the forensic cases, but mitochondrial DNA could not be amplified from any of the human bone. No false positive test results were seen with either biomolecular method; and human albumin and mitochondrial DNA were correctly identified in all unburnt control specimens. It was concluded that histological methods were not redundant and that quantitative microscopy provided an accurate and consistent means of determining the human or non-human origin of burnt bone and was more reliable than standard microscopy or the newer immunological and DNA techniques tested here.     

Interindividual variability, pathological changes and decomposition as an impediment to the morphological determination of human specificity of bone finds

Playing children discovered several teeth close to the wall surrounding a village church. A subsequent police search yielded further teeth, three neurocranial fragments, a metacarpal bone and the fragment of a long tubular bone. The circumstances along with the results of the investigation and the morphological findings suggested historical bones from a former graveyard. However, a large fragment of bone shaft from a long bone could not definitely be classified as being of human origin. The tibia of a deer was amongst the possibilities considered. Comparative tests run at the Institute of Veterinary Anatomy of the University of Giessen in addition to histological examinations, however, ultimately established the human specificity. Interindividual variability and decomoositional changes were determined as causes for the conspicuous macroscopic and microscopic findings for the tibia fragment. Pathological changes could not be demonstrated.