A safety cabinet has a second operation chamber in a first operation chamber and into which clean air is supplied, a second suction opening for sucking in air in the second operation chamber and a portion of the air in the first operation chamber, and a second operation opening part that is provided facing a first operation opening part and communicates the second operation chamber with the first operation chamber. Airflow containment (air barrier) is doubled with respect to the outside of a safety cabinet. In cases where decontamination and disinfection operations are carried out according to the changeover procedures, intensive decontamination and disinfection of the second operation chamber is sufficient, and decontamination and disinfection of the first operation chamber is hardly required. Decontamination and disinfection operations in the changeover procedures and the like can be carried out in a greatly reduced time.

An isolator system including: a box-shaped body case having, in an interior thereof, a work space for operation in a sterile environment and also having, in a front surface thereof, an insertion portion into which a worker's arm is inserted; and an air-conditioning portion configured to supply gas in the work space of the body case or to discharge gas in the work space, a bottom of the work space being configured with a work plate, a discharge path configured to discharge gas in the work space being formed below the work plate, the work plate being configured with first and second work plates obtained by dividing the work plate into right and left parts, a receiving portion being located below the first work plate, the receiving portion being arranged extending towards the second work plate on a side edge of the first work plate, the side edge of the first work plate being in contact with the second work plate, a side edge of the second work plate for being in contact with the first work plate being placed detachably on the receiving portion.

The present invention relates to a feedback mechanism for a biological safety cabinet comprising a glass window and a cover plate in front of the glass window, the feedback mechanism comprises a monitor control component comprising a roller element being fixedly disposed with respect to the cover plate and comprising a rollable roller, and a contact component being fixedly disposed relative to the glass window so that the contact component can move relative to the roller with movement of the glass window, the contact component comprising a recess for receiving the roller, wherein the contact component moves with the glass window to a position corresponding to the roller when the glass window moves relative to the cover plate, such that the roller rolls into the recess, allowing the feedback mechanism to generate tactile feedback.

A method for conditioning air in a test space of a test chamber which receives test material. A temperature in a range of −20° C. to +180° C. is established within the test space with a cooling device. The cooling device includes a cooling circuit with a refrigerant, a heat exchanger, a compressor, a condenser and an expansion element. An internal heat exchanger of the cooling circuit is connected to a high-pressure side of the cooling circuit upstream of the expansion element and downstream of the condenser and to a low-pressure side of the cooling circuit upstream of the compressor and downstream of the heat exchanger and is used to cool the refrigerant of the high-pressure side. A zeotropic refrigerant is used and the internal heat exchanger is used to cool the refrigerant of the high-pressure side to lower an evaporation temperature at the expansion element.

A shelf support for leveling a shelf of a laboratory climatic cabinet is provided. The shelf support includes a shelf support body configured to be secured to a wall of the laboratory climatic cabinet and to support the shelf and at least one shelf leveling mechanism associated with the shelf support body. When the shelf is supported by the shelf support, the at least one shelf leveling mechanism is configured to adjust a distance between the shelf and a floor of the laboratory climatic cabinet. A laboratory climatic cabinet is provided and includes a shelf support, which includes a shelf support body configured to support the shelf and a shelf leveling mechanism, secured to a first wall of the cabinet. When a shelf is supported by the shelf support, the shelf leveling mechanism is configured to adjust a distance between the shelf and a floor of the cabinet.

Provided herein are methods for processing and/or detecting a sample. A method can comprise providing a barrier between a first region and a second region, wherein the first region comprises the sample, wherein the barrier maintains the first region at a first atmosphere that is different than a second atmosphere of the second region, wherein a portion of the barrier comprises a fluid in coherent motion; and using a detector at least partially contained in the first region to detect one or more signals from the sample while the first region is maintained at the first atmosphere that is different than the second atmosphere of the second region. The portion of the barrier comprising fluid may have a pressure lower than the first atmosphere, the second atmosphere, or both.

The present invention relates to a device adapted to facilitate transport of a biopsy sample from a sterile extraction site to laboratory-type equipment by which the biopsy sample is processed, while maintaining the biopsy sample wetted and sterile and automatically transferring the biopsy sample from the device to the laboratory-type equipment.

There is provided an accommodation case (1) having a first wall part (33) in which a power supply unit (40) that transmits electric power to a power supply destination in a noncontact state is provided, a second wall part (34) in which a power reception unit (50) that receives electric power that is supplied from a power supply source in a noncontact state is provided, where the second wall part (34) faces the first wall part (33), and an accommodation space (35) that is surrounded by a plurality of wall parts including the first wall part (33) and the second wall part (34).

An incubator for cell and tissue culture under controlled atmospheric conditions has a primary air flow control device that forms a primary, preferably laminar flow, air veil across an opening that allows access to the cells or tissue cultures disposed within the incubator. Preferably, most if not all of the air in the primary (laminar flow) air veil is recirculated, and a secondary air flow control device is used that forms a secondary, preferably laminar flow, air veil between the primary (laminar flow) air veil and a user of the incubator.

A bypass flow monitoring chamber that may be retrofit onto the main chamber of an incubation chamber, for continuous collection of environmental samples. This allows for the measurement and correction of the environmental conditions within the chamber, and the return of the sample to the main chamber. Utilizing this sampling method, the separable bypass flow monitoring chamber may be isolated from the main chamber by a set of valves during a period of high-heat decontamination of the incubator therein protecting the sensors and contents of this separable chamber, as well as allowing the use of less expensive and lower temperature rated incubator sensors.