An animal isolation and caging system which maximizes cage density within a ventilated rack is provided. The rack includes at least one air exhaust plenum, and at least one canopy disposed within the rack for ventilation of the cages housed in a rack system. The rack is capable of supporting a first cage within the rack below a first canopy, and also positioning a second cage below a second canopy. The filter top of the first cage provided by the invention also provides a filter retainer having a filter top retainer wall designed to be in contact with a first canopy unit forming an enclosed space so configured as to create an enclosed space from which the animal isolation and caging system of the invention creates a zone of negative pressure so as to permit air to be drawn into an air exhaust plenum or duct from the interior of the first cage through the top of the first cage.

An in-wall display assembly is provided for mounting in a passage extending at least partway through a wall. The display assembly has a chamber with opposite front and rear walls, opposite end walls extending between the front and rear walls, an open top defined by the front, rear and end walls and a bottom opposite the top. At least one of the front and rear walls is transparent. The display assembly includes a mounting assembly securable to opposite sides of the passage for mounting the chamber to the opposite sides of the passage. The mounting assembly is movable between an in-wall configuration wherein the chamber is disposed in the passage and an access position wherein at least the top of the vessel extends from the wall to provide access to its interior.

A ventilated cage and rack system. An embodiment of the invention may comprise a ventilated rack, the rack including at least one air exhaust plenum and at least one canopy disposed within the rack, the canopy being adapted to position a cage assembly below the canopy while maintaining a gap between the top of the cage assembly so as to permit air to be drawn into the air exhaust plenum from the interior of the cage assembly through the top of the cage assembly and to also permit ambient air to be drawn across the top of the cage assembly into the air exhaust plenum. The cage assembly comprises one of a first cage having a first width and a plurality of second cages having a second width, the second width being less than the first width.

A ventilated animal habitat in the form of a frame having at least one shelf supporting an animal enclosure with a ventilation control region including an ambient air inlet and exhaust air outlet and a ducting system also supported by the frame with an exhaust air collection chamber having a mouth abutting the enclosure around the exhaust air outlet to capture exiting habitat air drawn under negative pressure by a remote vacuum source and direct the captured air through a carry way duct while fresh ambient air is introduced into the enclosure.

The present invention is an animal cage adapted for providing supply air to the cage by either static or forced ventilation, comprising, a cage receptacle and ventilation distribution means integral to said cage receptacle for distributing supply air to an interior space of said cage receptacle. A ventilation air supply system that provides air to the entire cage receptacle and allows the air to leave the cage receptacle in the same manner without the need for a filter cap or bonnet. The ventilation system creates an even flow of air along the side of the cage receptacle thus providing an even air flow across the bottom of the cage, and therefore providing a better environment for the animal. The present invention also provides a an animal cage with biological barrier means integral to said cage receptacle for precipitating microparticles and/or contaminants in the supply air out of suspension due to the low velocity of the supply air during static ventilation.