Microbiological monitoring in individually ventilated cage systems.

Housing rodents in IVC racks has many advantages over conventional cages but also presents unique challenges related to health monitoring. The authors review the issues to consider in design of a sentinel program using IVC systems.

Efficacy of three microbiological monitoring methods in a ventilated cage rack.

The use of individually ventilated caging (IVC) to house mice presents new challenges for effective microbiological monitoring. Methods that exploit the characteristics of IVC have been developed, but to the authors' knowledge, their efficacy has not been systematically investigated. Air exhausted from the IVC rack can be monitored, using sentinels housed in cages that receive rack exhaust air as their supply air, or using filters placed on the exhaust air port. To aid laboratory animal personnel in making informed decisions about effective methods for microbiological monitoring of mice in IVC, the efficacy of air monitoring methods was compared with that of contact and soiled bedding sentinel monitoring. Mice were infected with mouse hepatitis virus (MHV), mouse parvovirus (MPV), murine rotavirus (agent of epizootic diarrhea of mice [EDIM]), Sendai virus (SV), or Helicobacter spp. All agents were detected using contact sentinels. Mouse hepatitis virus was effectively detected in air and soiled bedding sentinels, and SV was detected in air sentinels only. Mouse parvovirus and Helicobacter spp. were transmitted in soiled bedding, but the efficacy of transfer was dependent on the frequency and dilution of soiled bedding transferred. Results were similar when the IVC rack was operated under positive or negative air pressure. Filters were more effective at detecting MHV and SV than they were at detecting MPV. Exposure of sentinels or filters to exhaust air was effective at detecting several infectious agents, and use of these methods could increase the efficacy of microbiological monitoring programs, especially if used with soiled bedding sentinels. In contemporary mouse colonies, a multi-faceted approach to microbiological monitoring is recommended.

Confirmed persistent mouse hepatitis virus infection and transmission by mice with a targeted null mutation of tumor necrosis factor to sentinel mice, using short-term exposure.

Mouse hepatitis virus (MHV) infection in immunocompetent mice is typically self limiting, and transmission is short lived. With the recent surge in the development of genetically engineered mutant mice with alterations in immune system components, however, MHV clearance may be disrupted. We report confirmed persistent transmission of MHV from tumor necrosis factor (TNF) knockout mice, B6.129S1-Tnftm1Lj (TNF -/-), to nude and immunocompetent sentinel mice over a period of five months. Infection with MHV was confirmed in nude sentinel mice by use of reverse transcriptase-polymerase chain reaction (RT-PCR) detection of viral RNA in ascending colon and feces. The RT-PCR-analyzed specimens recovered from sentinel animals were sequenced, and 92% homology to the N region of the MHV strain S genome was documented. In addition, immunocompetent mice had evidence of seroconversion to MHV infection and RT-PCR-positive fecal and ascending colon specimens after only 24 h of direct contact with the TNF -/- mice. To the authors' knowledge, this is the first reported experimental evidence that MHV transmission can occur for several months, from persistently infected mice to sentinel mice, over a short-term exposure period.

Rodent quality assurance testing: use of sentinel animal systems.

The ability to produce unique strains of genetically engineered mice has revolutionized biomedical research, but has also complicated the maintenance of "clean" facilities through an increase in the movement of animals between facilities and the production of immunodeficient strains. The authors discuss the use of sentinel and quarantine programs to minimize disease transmission between laboratory mice.