Methods in vascular infusion biotechnology in research with rodents

Infusion of experimental compounds into the vascular system of rodents and the need to collect blood and other biological fluids from small animals comprise an area of emerging importance to biomedical research and drug discovery and development. The advances in the development of transgenic rodents coupled with technical progress in the manufacture and commercial availability of various catheters, swivels, tethers, infusion pumps, and sample collection systems that are described have enabled biomedical scientists to miniaturize vascular infusion and sample collection systems previously used in animal species larger than the rat or mouse. Use of these advanced, miniature vascular infusion systems in rodents is possible only when careful planning of experimental design, expert surgical technique, adequate postoperative care, and fundamental animal welfare considerations are meticulously taken into consideration. Use of these vascular infusion systems in rodents promotes animal welfare and scientific progress through the reduction and refinement of animal models.     

The Nile grass rat as a laboratory animal

Rodents are the subjects of the overwhelming majority of laboratory animal studies, and most laboratory rodents are nocturnal. The availability of a suitable diurnal rodent would provide a more effective animal model for biomedical research applicable to humans. The author describes several characteristics of the Nile grass rat that make this diurnal murid rodent an attractive laboratory animal.     

Red-carpet rodent care: making the most of dollars and sense in the animal facility

Cutting-edge biomedical research programs have entered an era in which phenotypic characterizations for genetically altered rodents can facilitate appropriate care. The veterinary care requirements necessary to support such animal models can include the procedures already adapted as standard practice in companion animal hospitals, and can decrease data variability while increasing survival rates.     

Transgenic Modifications of the Rat Genome

The laboratory rat (R. norvegicus) is a very important experimental animal in several fields of biomedical research. This review describes the various techniques that have been used to generate transgenic rats: classical DNA microinjection and more recently described techniques such as lentiviral vector-mediated DNA transfer into early embryos, sperm-mediated transgenesis, embryo cloning by nuclear transfer and germline mutagenesis. It will also cover techniques associated to transgenesis such as sperm cryopreservation, embryo freezing and determination of zygosity. The availability of several technologies allowing genetic manipulation in the rat coupled to genomic data will allow biomedical research to fully benefit from the rat as an experimental animal.     

Intestinal microflora functions in laboratory mice claimed to harbor a “normal” intestinal microflora. Is the SPF concept running out of date?

For many years, laboratory animal breeders have used a mixture of eight bacterial strains, the so-called Altered Schaedler Flora (ASF) to inoculate Caesarian derived offspring when establishing colonies of Specific Pathogen Free (SPF) rodents fulfilling the criteria worked out by regulatory agencies as AALAS, FELASA, etc. However, recently it was shown in this journal that such SPF animals harbored a fecal flora far different from that of feral mice.Over the years, we have worked with functional aspects of host-microbe interactions(s) and the aim of the present study was to analyze some intestinal microbial biochemical activities in mice harboring an ASF flora. In the five parameter studied, the ASF mice showed a pattern similar to what is found in germfree mice and rats, demonstrating an absence of microorganisms capable of performing these reactions. These findings call for a re-considering of the SPF concept. Presence of important microbiological functions should be taken into consideration when rodents are used in biomedical research.     

Alternatives to the use of mammals for pain research.

The study of pain and analgesia is an important area of biomedical research which has led to a number of significant advances in the treatment of acute and chronic pain in the clinic. This area of research examines the physiology of pain transmission and the pharmacology of analgesic drugs by employing a variety of in vitro and in vivo animal models. To date, the vast majority of in vivo models for pain research have used mammalian species, primarily rodents and, to a lesser extent, canines, felines, and primates. The present review summarizes the special considerations of animal use in pain research and the philosophic and scientific basis for developing adjunct models using lower vertebrates. Existent literature on pain research using non-mammalian vertebrates is reviewed, with a special focus on amphibian species. Given the ethical concerns of experimental animal use and the importance of a comparative approach to the basic understanding of pain-processing, the further development of non-mammalian models for pain research should be encouraged.     

非人灵长类肿瘤模型研究进展(英文)

癌症是人类第二大致死的疾病。将体外细胞模型获得的癌症研究结果向临床转化过程中,动物活体实验是必不可少的一个环节。现在的肿瘤活体实验绝大部分采用啮齿类实验动物如小鼠和大鼠,这是因为它们具有个体小、繁殖迅速、遗传背景清楚、转基因技术成熟等优势。但是啮齿类和人的亲缘关系比较远,许多从啮齿类动物模型获得的研究结果不能在人体重现。非人灵长类动物在遗传进化、免疫、生理和代谢等诸多方面与人类高度近似,理论上更加适合癌症研究。本文对现有的非人灵长类肿瘤研究做一综述,主要集中介绍用化学和生物致癌剂在不同的非人灵长类动物诱导肿瘤的研究,为将来用非人灵长类动物研究人类癌症奠定基础。     

Preparing chimpanzees for laboratory research

The chimpanzee is the only representative of the Great Apes that is extensively involved in biomedical research in primate laboratories. These apes are used as animal models in a variety of studies, including research on infectious disease, parasitic disease, pharmacokinetic studies, neuroscience, cognition, and behavior. Chimpanzees used in biomedical research in the United States reside largely in six specialized research and holding facilities, and most of the research with them is conducted at these sites. Given the relatively small population of chimpanzees and its importance to biomedical research, it is imperative that we carefully manage the care, production, and use of these animals in biomedical research studies. Selection criteria and preparation techniques are reviewed in this article in an effort to begin a discussion on best practices for choosing and handling chimpanzees participating in biomedical research. The use of routine health assessment information is described for subject selection, as are behavioral issues to be considered. Due to the relatively small number of chimpanzees available, issues related to experimental design and multiple uses of chimpanzees are discussed. Practices related to the transportation and acclimation of chimpanzees are described. Finally, behavioral conditioning procedures are discussed, including habituation, desensitization, and positive reinforcement training that have been applied to reduce animal distress and improve the quality of the science being conducted with chimpanzee subjects.     

Evaluating the effectiveness of training strategies: performance goals and testing

The Public Health Service policy, Animal Welfare Act regulations, and the Guide for the Care and Use of Laboratory Animals all require that institutions provide training for personnel engaged in animal research. Most research facilities have developed training programs to meet these requirements but may not have developed ways of assessing the effectiveness of these programs. Omission of this critical activity often leads to training that is ineffective, inefficient, or unnecessary. Evaluating the effectiveness of biomedical research and animal care training should involve a combination of assessments of performance, competence and knowledge, and appropriate tests for each type of knowledge, used at appropriate time intervals. In this article, the hierarchical relationship between performance, competence, and knowledge is described. The discussion of cognitive and psychomotor knowledge includes the important distinction between declarative and procedural knowledge. Measurement of performance is described and can include a variety of indirect and direct measurement techniques. Each measurement option has its own profile of strengths and weaknesses in terms of measurement validity, reliability, and costs of development and delivery. It is important to understand the tradeoffs associated with each measurement option, and to make appropriate choices of measurement strategy based on these tradeoffs arrayed against considerations of frequency, criticality, difficulty of learning, logistics, and budget. The article concludes with an example of how these measurement strategies can be combined into a cost-effective assessment plan for a biomedical research facility.     

CONTEMPORARY MEDICAL ETHICS: AN OVERVIEW FROM IRAN

The growing potential of biomedical technologies has increasingly been associated with discussions surrounding the ethical aspects of the new technologies in different societies. Advances in genetics, stem cell research and organ transplantation are some of the medical issues that have raised important ethical and social issues. Special attention has been paid towards moral ethics in Islam and medical and religious professions in Iran have voiced the requirement for an emphasis on ethics. In the last decade, great strides have been made in biomedical ethics, especially in the field of education, research and legislation. In this article, contemporary medical ethics in Iran, and the related moral philosophy, have been reviewed in brief and we have discussed some of the activities in the field of medical ethics that have been carried out in our country within recent years. These activities have included the establishment of the National and Regional Committees for Medical Research Ethics and the production of national codes of ethics in biomedical research in the 1990s and the introduction of a comprehensive strategic plan for medical ethics at the national level in 2002. This paper will discuss these issues, along with the production, in 2005, of the Specific National Ethical Guidelines for Biomedical Research.     

Applying the "3 Rs": training course in surgical techniques

As the use of surgical procedures in rodents becomes increasingly common in biomedical research, institutions face the challenge of ensuring that personnel are properly trained to perform these procedures. The author describes a microsurgery training course in use at Columbia University.     

Opportunistic infections of mice and rats: Jacoby and Lindsey revisited

Adventitious infections among rodents used in biomedical research and teaching continue to be problematic even with improved housing and disease-deterrent methodologies. In addition to well-documented viral diseases (e.g., mouse hepatitis virus and rodent parvoviruses) and parasites (mites and pinworms), new pathogens such as murine norovirus have emerged in recent years. Infectious agents can enter colonies via incoming rodent shipments, in unscreened biological materials, on people (especially husbandry or investigative staff) who move from a location where animals have a lower health status to an area where health status is higher and operational procedures are more stringent, or by introduction of contaminated food, bedding material, or other fomites. These factors, coupled with the very high volume of movement of rodents within and between institutions, increase the risk of spreading infectious agents. The challenge to the laboratory animal community is to implement control measures that halt the passage of these organisms from one location to another while still enabling collaborative scientific discovery to proceed with minimal disruption. It is therefore critical to make appropriate decisions about identifying outbreaks in a timely fashion and controlling the spread of infection once identified. Such efforts should be practical, reproducible, and cost-effective.     

Outlook for development of high-throughput cryopreservation for small-bodied biomedical model fishes

With the development of genomic research technologies, comparative genome studies among vertebrate species are becoming commonplace for human biomedical research. Fish offer unlimited versatility for biomedical research. Extensive studies are done using these fish models, yielding tens of thousands of specific strains and lines, and the number is increasing every day. Thus, high-throughput sperm cryopreservation is urgently needed to preserve these genetic resources. Although high-throughput processing has been widely applied for sperm cryopreservation in livestock for decades, application in biomedical model fishes is still in the concept-development stage because of the limited sample volumes and the biological characteristics of fish sperm. High-throughput processing in livestock was developed based on advances made in the laboratory and was scaled up for increased processing speed, capability for mass production, and uniformity and quality assurance. Cryopreserved germplasm combined with high-throughput processing constitutes an independent industry encompassing animal breeding, preservation of genetic diversity, and medical research. Currently, there is no specifically engineered system available for high-throughput of cryopreserved germplasm for aquatic species. This review is to discuss the concepts and needs for high-throughput technology for model fishes, propose approaches for technical development, and overview future directions of this approach.     

Reproductive biology in the era of genomics biology

Current and emerging technologies in reproductive biology, including assisted reproductive technologies and animal cloning, are discussed in the context of the impact of genomics era biology. The discussion focuses on the endocrinology associated with establishment and maintenance of pregnancy, fetal-placental development, lactation, and neonatal survival. Various aspects of uterine biology, including development during the neonatal period and function in adult females, are discussed with respect to reproductive efficiency. It is clear that combining strategies for use of conventional animal models for studying the reproductive system with new genomics technologies will provide exceptional opportunities in discovery research involving data integration and application of functional genomics to benefit animal agriculture and the biomedical community. New and emerging biotechnologies and comparative genomics approaches will greatly advance our understanding of genes that are critical to development of the reproductive system and to key events at each stage of the reproductive cycle of females and males.     

Outlook for development of high-throughput cryopreservation for small-bodied biomedical model fishes

With the development of genomic research technologies, comparative genome studies among vertebrate species are becoming commonplace for human biomedical research. Fish offer unlimited versatility for biomedical research. Extensive studies are done using these fish models, yielding tens of thousands of specific strains and lines, and the number is increasing every day. Thus, high-throughput sperm cryopreservation is urgently needed to preserve these genetic resources. Although high-throughput processing has been widely applied for sperm cryopreservation in livestock for decades, application in biomedical model fishes is still in the concept-development stage because of the limited sample volumes and the biological characteristics of fish sperm. High-throughput processing in livestock was developed based on advances made in the laboratory and was scaled up for increased processing speed, capability for mass production, and uniformity and quality assurance. Cryopreserved germplasm combined with high-throughput processing constitutes an independent industry encompassing animal breeding, preservation of genetic diversity, and medical research. Currently, there is no specifically engineered system available for high-throughput of cryopreserved germplasm for aquatic species. This review is to discuss the concepts and needs for high-throughput technology for model fishes, propose approaches for technical development, and overview future directions of this approach.     

Use of biophotonic imaging as a training aid for administration of substances in laboratory rodents

Dosing of experimental animals and the removal of blood are two of the most frequent procedures performed in biomedical research using live animals. Despite the apparently simple nature of these procedures, they can, if not correctly carried out, have significant effects on the welfare of the animals and the scientific value of the results. There are several methods by which research staff may obtain training in the administration of substances. These include practical demonstrations during teaching courses; observation of techniques; videos and educational computer programs and practising on recently killed animal cadavers or plastic animal models. Each method has its own advantages and disadvantages. A common factor encountered during training is the difficulty in assessing competency. This paper reports a pilot study on the use of bioluminescent imaging technology to assess competency in the administration of substances to rodents. Bioluminescence was rapidly detected after dosing of animals with a bioluminescent substance. However, living animals were required for a signal to be generated. The data presented suggest that this technology is ideal for use as a teaching aid and may also prove valuable in assessing the effectiveness of 'complex' and novel administration routes in 'realtime'.     

The construction of transgenic and gene knockout/knockin mouse models of human disease

The genetic and physiological similarities between mice and humans have focused considerable attention on rodents as potential models of human health and disease. Together with the wealth of resources, knowledge, and technologies surrounding the mouse as a model system, these similarities have propelled this species to the forefront of biomedical research. The advent of genomic manipulation has quickly led to the creation and use of genetically engineered mice as powerful tools for cutting edge studies of human disease research including the discovery, refinement, and utility of many currently available therapeutic regimes. In particular, the creation of genetically modified mice as models of human disease has remarkably changed our ability to understand the molecular mechanisms and cellular pathways underlying disease states. Moreover, the mouse models resulting from gene transfer technologies have been important components correlating an individual’s gene expression profile to the development of disease pathologies. The objective of this review is to provide physician-scientists with an expansive historical and logistical overview of the creation of mouse models of human disease through gene transfer technologies. Our expectation is that this will facilitate on-going disease research studies and may initiate new areas of translational research leading to enhanced patient care.     

USDA animal genomics program: the view from the chicken coop

In 2007, the USDA Animal Genomics Strategic Planning Task Force prepared a Blueprint to direct national needs for future research, education, and extension efforts in agricultural animal genomics. This plan is entitled "Blueprint for USDA Efforts in Agricultural Animal Genomics 2008–2017". The Blueprint is reviewed from the perspective of a molecular biologist working within the poultry breeding industry. The diverse species used in animal agriculture require different tools, resources and technologies for their improvement. The specific requirements for chickens are described in this report.