Controlling exposure to laboratory animal allergens

Laboratory animal allergy (LAA) is a significant occupational disease that may affect up to one third of personnel exposed to laboratory animals. Research has characterized the relative risks of exposure, in terms of intensity, frequency, and duration, associated with given tasks and work areas in the animal facility. Studies have shown that reduced exposure to animal allergens can reduce the incidence of LAA and relieve symptoms among affected workers. A combination of measures to eliminate or control allergen exposure, including engineering and administrative controls and personal protective equipment, have been integral components of effective LAA management programs. The author provides a comprehensive review of exposure control options, considerations, and " best practices" relative to laboratory animal allergen in the context of traditional industrial hygiene methods.     

Laboratory animal allergens

Allergic sensitivity to laboratory animals can pose a significant occupational hazard to anyone with regular animal contact. Reactions to mice and rats are most common although all furred animals produce allergens that can lead to sensitization and disease. Most of the relevant allergens of laboratory animals have been defined and characterized, which has revealed that these allergens are typically small, acidic glycoproteins and that many of them are members of a superfamily of extracellular proteins called lipocalins. In addition to understanding their molecular characteristics, the identification of these allergens has also made it possible to measure their distribution in laboratory environments and to relate exposure levels to sensitization and symptoms. These studies have shown that the major laboratory animal allergens are carried on small particles that are both capable of remaining airborne for extended periods and penetrating into the lower airways of exposed workers. These advances in the understanding of these important occupational allergens will allow for the development of better methods of diagnosis and avoidance for affected workers and others who may be at risk for future difficulties.     

Contribution of pathology to laboratory animal welfare

To promote experimental animal welfare, several countries are engaged in establishing local animal research review committees and appointing supervising veterinarians or other experts. However, a number of adverse conditions leading to intercurrent illness or death remains unnoticed or unidentified. Pathological investigation of unexpectedly ill or dead animals proved to be very useful in indicating conditions compromising animal welfare. In addition, such post-mortem findings may be instructive, with respect to welfare, for those involved in experiments with animals.     

Indoor air quality in schools: exposure to fungal allergens

This study examined indoor air quality within schools in Kansas City, Spokane, Santa Fe, and Orlando. Air sampling was undertaken with both Andersen Single Stage Samplers and Burkard Personal Air Samplers. The data show a wide range of indoor exposures ranging from less than 100 colony forming units (CFU/m³) for viable fungi and 100 spores/m³ for total spores in Spokane and Santa Fe to concentrations over 6000 CFU/m³ for viable fungi and 15 000 spores/m³ for total fungi in Orlando and Kansas City, respectively. In the majority of sites the indoor airspora reflected the outdoor taxa withCladosporium the most abundant genus identified; however, several indoor locations had elevated levels ofPenicillium andAspergillus indicating possible sources of indoor contamination. Airborne basidiospores and smut spores were also fairly abundant in the schools and were among the top five taxa identified. The data also indicated that the airborne concentrations vary significantly during the day and between classrooms within each school. Continued studies in schools are needed to fully assess both the exposure levels and the clinical significance to atopic children allergic to these spores.     

An interdisciplinary performance-based approach to training laboratory animal technicians

Experience has proven that comprehensive training and education make it easier to attract and retain highly qualified animal care technicians, as well as to ensure that research facilities reach maximum performance. The authors outline the training approach used at SoBran, Inc., by describing the subject matter covered in their initial orientation period and in ongoing training sessions. The authors also address recordkeeping methods and training-program assessment.     

Master of laboratory animal science program: teaching the science of laboratory animal science

The administrators of the only program of its kind in the US explain the demand for a Master's degree in Laboratory Animal Science, the value of the degree, and plans to expand the program to make it available for distance learning.     

Degrees in laboratory animal science

The unique and challenging nature of work with animals requires special animal care and use training at all levels. Degree programs, certification boards, and continuing education programs ensure that those who work with animals have the knowledge and skills necessary to provide the best care possible.     

Consistency of laboratory animal food following incubation prior to autoclaving

In this study the conventional autoclaving technique was modified by incubating the food overnight prior to autoclaving. This treatment resulted in a markedly improved consistency of the food pellets, comparable with that of untreated food. The modified autoclaved food did not adhere to the walls of feeders or clog the transport passage. Furthermore, the losses in thermolabile vitamins resulting from this treatment were the same as those resulting from conventional autoclaving.     

A user-friendly approach to cost accounting in laboratory animal facilities

Cost accounting is an essential management activity for laboratory animal facility management. In this report, the author describes basic principles of cost accounting and outlines steps for carrying out cost accounting in laboratory animal facilities. Methods of post hoc cost accounting analysis for maximizing the efficiency of facility operations are also described.     

Methods for exposure of laboratory animals to ultraviolet radiation

Two different sources of ultraviolet B (UVB) radiation, an electronically controlled UVB exposure unit, containing FS40 tubes, and a hand-held Kromayer lamp, were evaluated for actual irradiance in W/m2 and spectra (physical dosimetry and biological dosimetry (skin effects in rodents)). The technical studies of the FS40 sources demonstrated that the flux intensity of the lamps could be changed electronically, without affecting the spectrum. Thus it was possible to standardize UVB exposure electronically. The biologically effective doses of these sources were analysed in RIV-Tox Wistar rats and BALB/c mice. After low doses of UVB radiation, histopathological changes such as acanthosis, hyperkeratosis and dermal inflammation were observed in the skin without the presence of major side effects such as erythema and oedema. After higher doses of UVB radiation erythema and oedema were clearly visible. Quantitative studies showed that the minimal erythema dose, as a biological parameter, correlated well to the emission in J/m2. In addition, biological parameters such as acanthosis and inflammation in the skin correlated well to the actual exposure in J/m2 and were sensitive biomarkers for UVB-induced skin toxicity. Thus, in addition to minimal erythemal doses, acanthosis and inflammation may also be applied as biologically relevant doses for studies of the biological effects of UVB radiation.     

Microbe hunting in laboratory animal research

Recent advances in nucleic acid diagnostic technologies have revolutionized microbiology by facilitating rapid, sensitive pathogen surveillance and differential diagnosis of infectious diseases. With the expansion and dissemination of genomic sequencing technology scientists are discovering new microbes at an accelerating pace. In this article we review recent progress in the field of pathogen surveillance and discovery with a specific focus on applications in the field of laboratory animal research. We discuss the challenges in proving a causal relationship between the presence of a candidate organism and disease. We also discuss the strengths and limitations of various assay platforms and describe a staged strategy for viral diagnostics. To illustrate the complexity of pursuing pathogen discovery research, we include examples from our own work that are intended to provide insights into the process that led to the selection of particular strategies.     

Email lists in laboratory animal science

Email lists can be invaluable for acquiring information that may not be easily accessible in the published literature. The author discusses the general format and functioning of email lists and describes six lists that can be valuable tools for education, training, and information exchange in the field of laboratory animal science.     

The laboratory animal management system--an animal housing management data-processing system]

The Laboratory Animal Management System (LAMS) is a flexible, multi-purpose animal house management tool. It has a decentralized structure and was developed using UNIFACE and Oracle-database software. The multiuser LAMS system runs on a Micro-Vax computer and can be accessed from several workstations. LAMS has been designed to manage the following functions: animal study details; animal procurement; book keeping and follow-up; amendments; update of data; inquiries; statistics and numerous additional tasks. LAMS is a user-friendly interactive system which does not allow input of incorrect data and can be operated by staff with very little computer experience. The system fully complies with German legal requirements and is becoming an increasingly important tool for routine management of animal house facilities and animal experimentation.     

Mechanism and epidemiology of laboratory animal allergy

Laboratory animal allergy (LAA) is a form of occupational allergic disease. The development of laboratory animal allergy is due to the presence of IgE antibodies directed against animal proteins. The process of sensitization (development of IgE antibodies) is a complex process which involves interaction of antigen presenting cells and lymphocytes of the Th-2 cell type. These cells generate a host of cytokines and other factors which lead to immediate hypersensitivity reactions and other factors which lead to immediate hypersensitivity reactions and the generation of allergic inflammation. Typical symptoms of laboratory animal allergy include nasal symptoms, such as sneezing, watery discharge, and congestion. Skin rashes are also common. Asthma, which produces symptoms of cough, wheezing, and shortness of breath, may affect 20-38% of workers who are sensitized to laboratory animal allergens. Rarely a generalized, life-threatening allergic reaction (anaphylaxis) may occur. The estimated prevalence of laboratory animal allergy is variable depending on the method used for diagnosis, but nonetheless may affect up to 46% of exposed workers. The presence of pre-existing allergies to non-work place allergens (e.g., dust mite, pollens, molds), exposure to laboratory animal allergens, and possibly tobacco smoking are risk factors for the development of laboratory animal allergy. Progress in the understanding of the mechanism and epidemiology of laboratory animal allergy will lead to improved methods for its prevention.