A stand-alone chamber or multi-chamber inhalation system has at least two alternative vaporized test liquid supply systems for passive or self-administered delivery of vaporized test fluid and air to one or more test chambers, which can be passive or restraint chambers, based on operator selection of delivery on and off times in a passive mode or actuation of an actuator in the chamber by a test animal in a self-administered mode. In one case, a multiple inhalation chamber system has two or more separate test fluid delivery systems and provides options for selective passive uniform drug delivery to multiple chambers or selective delivery of two or more different drugs to different groups of chambers from different delivery systems so that two different drugs or different concentrations of delivered drugs can be tested simultaneously.

A method and system for removably connecting the animal cage monitoring system to an animal rack. The monitoring system can include a data collection platform. Data from an RFID chipped animal within a cage can be wirelessly transmitted to the data collection platform. An individual chipped animal is associated with the data collection platform. The data collection platform and associated cage being removably received in a data collection rack. One or more removably mountable data collection processors can be attached to the data collection rack.

A collection system for monitoring conditions of a rack of animal cages. An animal caging system including a plurality of animal cages removably connected to an exhaust. A collection media cartridge is slidably received within an opening in a collection media housing dock. The collection media housing dock is positioned between an exhaust plenum of the rack an exhaust air inlet unit. Collection media is removably received in the collection media cartridge. Exhaust air dust clings to the collection media as exhaust from the animal cages flows along the length of the collection media. The collection media cartridge can be removed from the collection media housing dock and the collection media can be removed for sampling the exhaust.

The disclosure relates to an apparatus and a system for testing the cognitive ability of a rodent, comprising a testing chamber, a retarding zone connected to the entrance chamber and including at least one obstacle configured to slow down the rodent's movement to the entrance chamber, and an optional transfer chamber connected to the entrance chamber via the retarding zone for transfer of the rodent to and from an area external to the apparatus. The testing chamber comprises an entrance chamber, a plurality of corridors each connected to the entrance chamber via a corridor's first end portion, and at least one odor diffuser for diffusing odors in the plurality of corridors.

A rack-type mobile device for presenting parts of breeding cages for washing, the device being adapted to be inserted into a washing/rinsing machine for use in pharmaceutical preclinical research centres, the device including: a load-bearing structural frame for the parts of breeding cages; apparatus adapted for moving the mobile device, connected to the frame; one or more hooking and positioning elements for hooking and positioning the parts of breeding cages on the device, the hooking and positioning elements being located on at least one lateral face of the frame and being constrained to the load-bearing structural frame; the hooking and positioning elements being shaped as an open hook tilted downwards relative to the horizontal plane, with the hook bottom facing outwards from the lateral face of the mobile device, and the hook tip facing inwards, the open hook having such a width as to be able to internally house at least a part of the cage parts.

A growing system is described where plants are grown in containers and the containers are stored in stacks. Above the stacks runs a grid network of tracks on which load handling devices run. The load handling devices take containers from the stacks and deposit them at alternative locations in the stacks or deposit them at stations where goods may be picked out. The containers may be provided with one or more of the following services: power, power control, heating, lighting, cooling, sensing means, data logging means, growing means, water and nutrients.

A stand-alone chamber or multi-chamber inhalation system has at least two alternative vaporized test liquid supply systems for passive or self-administered delivery of vaporized test fluid and air to one or more test chambers, which can be passive or restraint chambers, based on operator selection of delivery on and off times in a passive mode or actuation of an actuator in the chamber by a test animal in a self-administered mode. In one case, a multiple inhalation chamber system has two or more separate test fluid delivery systems and provides options for selective passive uniform drug delivery to multiple chambers or selective delivery of two or more different drugs to different groups of chambers from different delivery systems so that two different drugs or different concentrations of delivered drugs can be tested simultaneously.

A generating device of simulating a particulate environment for an experimental animal includes an experimental chamber. An ultrasonic atomization device is installed at the bottom adjacent to the center of the experimental chamber. The upper side of the ultrasonic atomization device is connected to a guide device for guiding particles. The guide device includes an air seal cover, and a micro fan is installed inside the air seal cover to drive the movement of particles generated in the ultrasonic atomization device. Air guide pipes are fixedly connected to a side wall of the air seal cover. The generating device has good sealing performance, and can generate a variety of particle simulation environments to accurately and effectively simulate the biological effect of particles in the animal body. The generating device can improve the particle simulation environment, reduce the deviation of experimental data, and ensure the accuracy of the overall experimental data.

An electronic monitor can monitor experimental animals in a cage. The cage has one or more walls that enclose a living space for the experimental animals. The electronic monitor is coupled to the cage. The electronic monitor may include a housing adapted to be mechanically coupled to the cage in a predefined position relative to the cage. A substantially sterile barrier is provided between the living space and the external environment in this coupled state. The walls of the cage may include a signal-interface section. An electromagnetic detector may be coupled to the housing to have a line-of-sight through the signal-interface section and into the living space of the cage. The electromagnetic detector is adapted to detect electromagnetic radiation that is transmitted through the signal-interface section. A controller processes a signal received from the electromagnetic detector to determine a status of the experimental animals or the living space.

A device may identify, in a first frame of a video feed captured by a camera and using a first computer vision technique, a first subject based on a plurality of reference points of the first subject. The device may determine whether the first subject is merged with a second subject in a second frame of the video feed. The device may selectively identify the first subject in the second frame using the first computer vision technique, or using a second computer vision technique, based on whether the first subject is merged with the second subject in the second frame, wherein the second computer vision technique is based on a shape context of the first subject. The device may determine log information based on identifying the first subject in the first frame and the second frame. The device may store or provide the log information.