Investigation of appropriate sanitization frequency for rodent caging accessories: evidence supporting less-frequent cleaning.

The Guide for the Care and Use of Laboratory Animals states that sanitization of caging accessories (for example, filter tops and wire-bar lids) should be done every 2 wk. In this study we tested the hypothesis that organic contamination measured by the presence of ATP associated with organic material (measured with luciferase test swabs) and the number of bacterial colony-forming units (as determined by use of replicate organism detection and counting plates) on caging accessories did not differ significantly at 2 wk versus several months of use. The study evaluated 4 groups: mouse and rat ventilated and static wire-bar cages with or without filter tops (n = 10 per group). The cages were evaluated at several time points from 2 wk to 6 mo. For every cage type, ATP levels did not differ significantly between 14 and 90 d and, in most cases, between 14 and 180 d. In addition the number of bacterial colonies did not differ significantly between 14 and 120 d (and, in some cases, between 14 and 180 d). This study provides data relevant to establishing a validated frequency for sanitization of rodent caging accessories while controlling, and potentially decreasing, costs associated with sanitization.

Cross-fostering in combination with ivermectin therapy: a method to eradicate murine fur mites.

A colony of mutant mice with sickle cell anemia was infested with the fur mites Myocoptes musculinus and Myobia musculi. Pups of sickle-cell phenotype obtained by cesarean section prior to natural birth were of such poor vigor that none survived the combined insults of delivery by hysterectomy and cross-fostering. Consequently, surgical rederivation, the most reliable means of mite eradication, was not an option. Because furless mice are not susceptible to mite infestation and because neonates putatively remain free of mites until 4 to 5 days after birth, pups born by natural delivery were cross-fostered within 0 to 36 h to outbred lactating females treated once with ivermectin (2 mg/kg topically) at the time of transfer and housed in filter-top cages. Cross-fostering in conjunction with topical ivermectin administered to weaned mice one or more times at approximate 9-day intervals beginning on the day of weaning was successful in reliably eradicating mites. In addition, the 58% postnatal survivability of pups cross-fostered to dams given ivermectin was equivalent to that of natural-born pups that were reared by their untreated biological mothers.

Long-term results of dietary fenbendazole to eradicate Syphacia muris from rat colonies.

The pinworm Syphacia muris was eradicated from rats after treatment with fenbendazole-medicated chow (150 ppm) and without environmental decontamination for > 54 months. However, this regimen was successful only when the treatment was delivered and efficacy monitoring was done by personnel of the institutional animal resources program. The same pinworm elimination program failed 7 to 24 months after the cessation of treatment in a satellite colony in which animal care, including provision of medicated diet and sample collection for efficacy monitoring, was provided by research personnel. A failure to uniformly deliver adequate therapeutic doses or reinoculation of rats with pinworm eggs from the contaminated environment could not be excluded as causes of the failure. However, there were risk factors, and animal care practices unique to the satellite colony that may have facilitated the re-emergence of pinworms. These risk factors included hand-washing of cages, storage of contact bedding in areas that were not vermin-proof, and animal care provided by personnel having contact with rodents of pet-store origin.

High Mortality in Zebrafish (Danio rerio).

A group of 100 adult zebrafish were housed in a new system at a stocking density of 20 fish per tank. Four weeks after arrival, 15 fish presented with petechial hemorrhages and ulceration on the surfaces of the skin. Samples of the fish were collected for histopathology, fungal culture, and bacterial culture and sensitivity. Water samples were analyzed for pH, ammonia, nitrite, and submitted for bacterial and fungal culture. Histologically, the epidermis had multiple areas of ulceration and mononuclear cell infiltrate. Gram-positive bacteria were observed beneath the surface of the skin and surrounding the outer aspect of the spinal cord. Both Aeromonas hydrophila and A. sobria were isolated from the affected fish, and a diagnosis of motile aeromonad septicemia (MAS) was made. Water from the tanks had a nitrite level of 1-5 ppm, a toxic concentration that indicated poor water quality. Because the housing system had been seeded with Nitrobacter spp. and Nitrosomonas spp. only 2 weeks prior to the arrival of the fish, a lack of colonizing nitrifying bacteria was deemed to be the cause of the high nitrite level, which, along with over-crowding, stressed the fish and increased their susceptibility to MAS. No further cases of septicemia were observed once the nitrite level and stocking density were reduced.