恒河猴在生殖生物学中的应用进展

目的非人灵长类动物在生殖生物学研究领域是一种非常重要的实验动物。人类利用非人灵长类动物与人的生物学等方面相似的特征,开展了生殖生物学、生理学、药理学、毒理学以及生育调节等方面的研究工作,为生殖生物学基础研究以及人类健康和疾病问题的基础研究和临床前研究提供了理想的动物模型。随着生命科学的发展,对非人灵长类实验动物质量提出了更高的要求,人们认识到实验时,应用健康的优质非人灵长类动物的重要性。本文简要概括了非人灵长类动物恒河猴的生物学特性,阐述了非人灵长类动物恒河猴在生殖生物学中的应用研究。     

阿尔茨海默病转基因小鼠的特点和应用

建立动物模型的目的是在实验动物身上复制人类疾病的模型,用于研究人类疾病的病因、发病、病理变化以及疾病的预防和治疗。目前尚无理想的阿尔茨海默病（Alzheimer’s disease,AD）动物模型,AD实验动物模型的滞后在很大程度上制约了AD治疗药物的筛选。随着AD病因和发病机制研究的不断深入,更完善的AD动物模型也在陆续出现。近年来出现的转基因动物模型属于AD的病因模型,但也不能完整复制出AD的所有特征。最大的缺憾在于缺乏神经原纤维缠结（neurofibrillary tangles,NFTs）和在某些转基因模型中（尤其是单转基因模型）无广泛的神经元丢失。虽然用免疫组化方法检测到tau蛋白,但从未发现成对螺旋纤丝（paired helical filaments,PHF）。     

综述与专论: 灵长类动物在人类神经系统疾病动物模型中的应用

灵长类动物遗传、行为、认知、生理、生化和解剖结构等生物学特性更接近人类,具有其他实验动物无法替代的高级脑功能结构及神经活动的优势,是研究人类神经系统疾病理想的模式动物,研究的结果更容易推广应用到人类。常被用来建立神经退行性疾病、精神性疾病等疾病的动物模型,研究其发病机制、病程的发生发展及治疗药物等,为人类神经科学及相关医学研究做出了不可替代的贡献。本文综述了近年来国内外灵长类动物在人类神经系统疾病动物模型研究中的应用进展,分析了该领域目前存在的困难和问题,探讨了未来的一些研究方向,以期为神系统经疾病的深入研究提供思路。     

树鼩资源的开发利用与标准化研究——我国实验动物资源建设发展战略探讨

树鼩（Tupaia belangeri）作为人类疾病动物模型,被应用于人类医学实验研究的多个领域,如各种类型的病毒性肝炎模型,流感病毒、登革热病毒、轮状病毒、疱疹病毒模型,糖尿病、胆结石、癌症病模型。但是,目前我国用于实验研究的树鼩几乎全都来自野外,对它们的微生物学、寄生虫学、遗传学、环境学等质量标准没有进行控制,它们本身携带的许多病原体会对实验结果的准确性造成影响,这既不符合国家对实验动物许可证管理的要求,也不利于我国实验动物科技工作与国际接轨的发展要求。因此,应该同步开展树鼩资源的开发利用和标准研究,使之纳入实验动物许可证的有效监控和管理,改变目前使用在前、质量控制标准研究在后的被动局面。     

人干细胞实验动物嵌合体模型的研究进展

动物模型是疾病研究、发病机制、药物治疗的必要工具,目前一些困扰人类健康的重大疾病如艾滋病、乙型肝炎等因为还没有能反映人类疾病发病机理的理想动物模型。人干细胞是能在体外长期培养的、高度未分化的全能细胞系,亚全能细胞系和分化的干细胞等。如果能将人的干细胞成功移植入实验动物体内形成人源化嵌合体动物,有希望为艾滋病、肝炎等的研究制备适当的模型。人类干细胞在动物中的移植研究中主要的实验动物是绵羊,小鼠等,本文介绍了人干细胞在动物体内移植的研究进展。     

小型猪在肾脏疾病研究中的应用

随着对小型猪研究的不断深入,其作为人类疾病模型的优势日益明显,在生物医学研究中的应用也日趋增多。比较解剖学和生理学研究表明,小型猪的诸多生物学特性均与人类极为相似,尤其在肾脏的解剖和功能方面几乎是人类的复制品,使其在复制肾脏疾病模型,研究疾病发病机制和评估治疗策略等中具有无可替代的作用。本文将综述小型猪作为疾病动物模型在肾脏疾病研究中的应用。     

实验动物树鼩和人类疾病的树鼩模型研究概述

动物模型在生物医学领域(如回答人体各种重大生物学问题、解析人类疾病机理和新药研发等方面)已经做出了不可替代的巨大贡献。转化医学存在的问题使得树鼩(Tupaia belangeri chinensis)实验动物重新得到重视;人类疾病的树鼩模型也再次受到越来越多的关注。该文综述了国内外特别是近年来我国树鼩研究进展,包括树鼩基础生物学及动物模型方面取得的成绩,并分析了该领域目前存在的困难和问题,探讨了未来的一些研究方向。     

中国树鼩实验动物化研究进展和展望

该文回顾了我国树鼩驯养繁殖和研究的发展历史,介绍了树鼩实验动物化研究的最新进展,并结合我国目前的状况,提出了今后的工作建议:加强实验树鼩标准化(包括地方和国家标准)的研究、近交系动物的研制、达到商业化树鼩的基础分子与细胞生物学研究工具的研制、人类重大疾病树鼩动物模型研究和建设国家实验树鼩种源基地等。     

人类疾病动物模型在生物技术研发中的应用

人类疾病动物模型具有与人类疾病相似的症状或病理变化。应用动物模型是现代医学认识生命科学客观规律的重要实验方法。用实验结果推测人类疾病的发生和发展规律,研究有效的防治措施。本主要介绍在生物技术的开发中实验动物的选择和传染性疾病的动物模型。     

综述与专论: 树鼩病毒感染模型的研究新进展

病毒感染引起的疾病接近中国主要传染病发病率的一半,也是传染病致死的主要病因。建立与人类亲缘关系较近、方便有效的感染人类病毒的动物模型,对了解病毒的生物学特性、感染致病机理及制定有效防控措施具有重要意义。树鼩作为灵长类动物的近亲,与人类在生理生化、基因组学等方面的相似性远高于大鼠、小鼠等常用啮齿类实验动物,并具有个体小、便于实验操作、饲养成本低、能感染多种人类病毒等特点,作为动物模型在病毒感染性疾病研究中突显优势和潜能。本文从地区分布、进化、生物学特性等方面,阐述了树鼩作为动物模型应用于病毒感染性疾病研究的优势,包括在乙型肝炎病毒、甲型肝炎病毒,及其他病毒感染疾病研究中的进展。     

结核病动物模型研究进展

结核病是由结核分枝杆菌感染引起的传染病,是危害人类健康的主要传染病之一。动物模型已经成为研究人类传染病的标准化工具。虽然对于结核分枝杆菌而言并没有真正意义的动物资源,但由于不同种类的动物,对分枝杆菌的敏感性不一样,因此可以成为结核病研究的有利工具。结核病最常用的实验动物模型包括小鼠、兔和豚鼠。每种动物有其自身特点,但并不能完全模拟人类疾病。通过建立结核病的动物模型,可以大大增加我们对疾病的病因、毒力和发病机制的理解。除了这三种模型外,非人灵长类也常被用于结核病的研究。本文总结了这几种结核病模型的研究状况。     

Expanding the three Rs to meet new challenges in humane animal experimentation

The Three Rs are the main principles used by Animal Ethics Committees in the governance of animal experimentation, but they appear not to cover some ethical issues that arise today. These include: a) claims that certain species should be exempted on principle from harmful research; b) increased emphasis on enhancing quality of life of research animals; c) research involving genetically modified (GM) animals; and d) animals bred as models of disease. In some cases, the Three Rs can be extended to cover these developments. The burgeoning use of GM animals in science calls for new forms of reduction through improved genetic modification technology, plus continued attention to alternative approaches and cost-benefit analyses that include the large numbers of animals involved indirectly. The adoption of more expanded definitions of refinement that go beyond minimising distress will capture concerns for enhancing the quality of life of animals through improved husbandry and handling. Targeting refinement to the unpredictable effects of gene modification may be difficult; in these cases, careful attention to monitoring and endpoints are the obvious options. Refinement can also include sharing data about the welfare impacts of gene modifications, and modelling earlier stages of disease, in order to reduce the potential suffering caused to disease models. Other issues may require a move beyond the Three Rs. Certain levels of harm, or numbers and use of certain species, may be unacceptable, regardless of potential benefits. This can be addressed by supplementing the utilitarian basis of the Three Rs with principles based on deontological and relational ethics. The Three Rs remain very useful, but they require thoughtful interpretation and expansion in order for Animal Ethics Committees to address the full range of issues in animal-based research.     

Review of colorectal cancer and its metastases in rodent models: comparative aspects with those in humans

BACKGROUND AND PURPOSE: Colorectal cancer (CRC) remains one of the most common cancer forms developing in industrialized countries, and its incidence appears to be rising. Studies of human population groups provide insufficient information about carcinogenesis, pathogenesis, and treatment of CRC. To study these phenomena in detail, a number of animal models of human CRC have been developed. The hypothetical ideal animal model should mimic the human disease in terms of morphology, biochemical alterations, and biological behavior. No existing model replicates the disease as an entity, but available models approximate many of the characteristics of human colonic carcinogenesis and metastasis. So far few comparative evaluations of the various animal models of CRC have been made. CONCLUSION: Animal studies cannot replace human clinical trials, but they can be used as a pre-screening tool, so that human trials become more directed, with greater chances of success. The orthotopic transplantation of colon cancer cells into the cecum of syngeneic animals or intraportal inoculation appears to resemble the human metastatic disease most closely, providing a model for study of the treatment of metastases. Which model(s) to choose depends on the goal(s) of the experiment(s). The review published here can provide help in selecting the most optimal CRC model(s) for a certain purpose and in preventing unnecessary duplication of animal experimentation.     

A Comparison of Methodologies for the Study of Functional Transmitter Neurochemistry in Human Brain

A number of different approaches to the study of functional neurochemistry in human brain are discussed. The advantages and disadvantages of three main techniques are contrasted: (i) using animal tissue preparations as models of the human brain; (ii) using human peripheral tissue preparations as models of dynamic CNS processes; and (iii) studying human tissue, obtained postmortem, directly. Animal models are often readily obtained and reliable, and the high degree of inbreeding of common laboratory animals ensures that they usually yield consistent results. However, there are a number of human disorders for which animal models are either poor or unavailable, and species differences make extrapolation from the animal to the human case difficult. Human peripheral tissue models rely on a degree of homology between peripheral and CNS processes; in most cases, the evidence for such homologies derives from animal, rather than human, studies. Moreover, several examples are known where a peripheral process mimics the equivalent glial cell activity more closely than the neuronal, which can be a serious drawback for studies of neurotransmission. The use of postmortem human brain tissue presents a number of obvious difficulties, resulting from variations in the patient's age, agonal state, sex, preterminal medication, postmortem delay, etc. Human beings are genetically and nutritionally heterogeneous, so that data variability is usually greater here than when using tissue from laboratory animals. However, it is possible to control for a number of these factors, for example, by matching samples for basal metabolic rate and tissue integrity, and recently developed tissue freezing and storage techniques permit the use of within-subject experimental designs to help reduce experimental variation. A range of neurotransmitter functions are well retained in such tissue samples, so that regional variations, differential transmitter activities, drug effects, etc., can be studied in normal tissue samples, as well as in samples taken from cases of neurological and psychiatric disease. This allows, for example, changes in neuroanatomical indices to be correlated with localised alterations in a specific neurotransmitter function. A systematic approach to the analysis and matching of tissue samples is advocated. The three approaches should be considered to be complementary, especially for the study of human brain diseases.     

实验动物饲养和运输的伦理与福利

本文提出实验动物福利是人类应当给予实验动物的良好条件（正面因素）,主要体现在动物的饲养和运输等过程,以“5F”为基本理论;伦理则是人类给予动物实验处理（负面因素）时应遵循的原则,主要体现在动物实验过程中,以“3R”为基本理论.同时总结了实验动物饲养和运输过程的实际经验,从环境、笼具、垫料、密度、饲料和饮水、社会和行为需要、安乐死、运输等方面,介绍了保障实验动物福利的具体做法.     

Animal model systems for the study of alcohol teratology

The incidence of fetal alcohol syndrome has not been declining even though alcohol has been established as a teratogen and significant efforts have been made to educate women not to abuse alcohol during pregnancy. In addition to further educational efforts, strategies to prevent or mitigate the damages of prenatal alcohol exposure are now under development. Animal models will play a significant role in the effort to develop these strategies. Because prenatal alcohol exposure causes damage by multiple mechanisms, depending on dose, pattern, and timing of exposure, and because no species of animal is the same as the human, the choice of which animal model to use is complicated. To choose the best animal model, it is necessary to consider the specific scientific question that is being addressed and which model system is best able to address the question. Animal models that are currently in use include nonhuman primates, rodents (rats, mice, guinea pigs), large animal models (pig and sheep), the chick, and simple animals, including fish, insects, and round worms. Each model system has strengths and weaknesses, depending on the question being addressed. Simple animal models are useful in exploring basic science questions that relate to molecular biology and genetics that cannot be explored in higher-order animals, whereas higher-order animal models are useful in studying complex behaviors and validating basic science findings in an animal that is more like the human. Substantial progress in this field will require the judicious use of multiple scientific approaches that use different animal model systems.     

人源化鼠嵌合肝动物模型研究进展

动物模型是人类疾病研究、发病机制、药物研发的重要工具,对于困扰人类健康的肝脏疾病还没有理想的动物模型能有效地反映出人类疾病发病的机制。建立人源化鼠嵌合肝动物模型,对于研究人类肝脏疾病的发病机制、疫苗和药物的研发及疾病的诊治等方面都具有十分广阔的应用前景。     

1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine-lesioned model of parkinson's disease, with emphasis on mice and nonhuman primates

Animal models play a critical role in our understanding of the cause of human diseases and provide an opportunity to evaluate new therapeutic treatments. The usefulness of an animal model is dependent, in part, on how closely it resembles neurochemical, neuropathologic, and behavioral features of the human condition. Other considerations that may enhance the value of a model include expense, availability, reproducibility, animal morbidity and mortality, and investigator experience. Parkinson's disease (PD) is a progressive neurodegenerative disorder characterized by slow movements, tremor, and walking impairment due to loss of midbrain nigrostriatal neurons and depletion of striatal dopamine. In the PD research field, a number of neurotoxic, pharmacologic, and transgenic animal models are available for research studies. We will focus on the advantages and disadvantages of the 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP)-lesioned mouse and nonhuman primate models of PD. Our goal is to guide researchers in the appropriateness of the MPTP models in their studies by balancing understanding of the models, objectives of the study, and health and safety of the animals. In addition, the technical use and safe handling of MPTP are discussed.