Systems and related temperature calibration methods. In accordance with a first implementation, an apparatus includes a flow cell interface, a temperature control device, an infrared sensor, and a controller. The flow cell interface includes a flow cell support and the temperature control device is for the flow cell support. The controller is to command the temperature control device to cause the flow cell support to achieve a temperature value, cause the infrared sensor to measure an actual temperature value of the flow cell support, and calibrate the temperature control device based on a difference between the commanded temperature value and the actual temperature value.

The present disclosure is directed to opposables including a body having a plurality of cavities disposed therein. Each cavity can be designed to contain one or more reagents, liquids, or fluids which may be applied to a specimen-bearing surface. In some embodiments, the cavities include one or more reagent chambers, the reagent chambers can have one or more seals such that the reagents, liquids, or fluids contained therein may be stored and released to the specimen-bearing surface.

An ergonomic vial and tube rack is disclosed for retaining a plurality of vials or tubes containing fluid therein in inclined or vertical upright positions, features of which a mechanism for a variable incline angle; lid/cap receptacles positioned either on a shelf above the vial holders or inside the cover when in an open position; an ice or heat pack compartment or a sealed compartment underneath the vials and/or behind the vials for the limited temperature control; rack to rack pin-to-hole locators for stackability, ease of transportation, and storage; color-coding of vial racks for convenience and work-flow assistance; a transparent front panel or an opening in front of each vial receptacle for additional verification of reagent labels; a rack cover with rows of circular indentations, with or without a disposable lining, for use as shallow reaction dishes for qualitative or quantitative chemical assays, such as pH testing.

The disclosure provides processes for temperature and pressure controlled cryopreservation of samples by using isochoric systems.

A system and method facilitates transfers of specimen containers (e.g., vials with caps) between storage cassettes and carrier cassettes. The storage cassettes are designed to be stored in cryogenic refrigerators while the carrier cassettes are designed to be temporarily stored in a portable carrier. Identification information is read from wireless transponders carried by the specimen containers. Visual mappings of the positions of the specimen container in the cassettes is provided. Presence and position of the specimen containers in the cassettes is verified, and alerts of inconsistencies provided along with corrective commands. Inventories of specimen container and even specific specimen holders are provided.

An apparatus for preparing samples for chemical analysis includes a container receptacle for receiving a sample container having a crucible portion and an expansion portion. The container receptacle includes a heating compartment and a cooling compartment spaced apart from the heating compartment. The heating compartment is shaped to receive the crucible portion of the sample container, and the cooling compartment is shaped to receive the expansion portion of the sample container. The apparatus also includes a heating mechanism for heating the sample within the crucible portion of the sample container, a first cooling mechanism for cooling the expansion portion of the sample container, and a second cooling mechanism for cooling the crucible portion of the sample container.

A laboratory sample/specimen temperature control device, specifically a metal bead bath that has its metal bead temperature controlled by a continuous flow of air into the bed of beads that is heated or cooled by a Peltier device that the air flows over. This provides great thermal uniformity across the bed of beads and constantly monitors and regulates the heat or cooling input rather than utilizing an on/off modulation temperature input approach.

A compact sorting flow cytometer system is disclosed. The system includes a fluidics system having a flow cell and a deflection chamber in communication with the flow cell to receive drops in a stream of a sample biological fluid with one or more biological cells or particles and selectively deflect the drops in the stream of the sample biological fluid with the one or more biological cells or particles; and a droplet deposition unit (DDU) system in communication with the deflection chamber to receive the selectively deflected drops in the stream of the sample biological fluid with the one or more biological cells or particles into one or more containers. The DDU system includes a case or a housing with an open face surround by edges of the case, the case forming a portion of a containment chamber, the case having a top side opening aligned with the deflection chamber to receive the selectively deflected drops in the stream of the sample biological fluid into one or more containers in the containment chamber, a seal mounted around edges of the case, one or more hinges coupled to a bottom portion of the case, and a door coupled to the one or more hinges to pivot the door about the one or more hinges, the door when closed to press against the seal and close off the containment chamber from an external environment.

A method for evacuation of air in a containment chamber of a flow cytometer is disclosed. The method includes turning off a return fan in a first tunnel between an air conditioning chamber and a containment chamber; turning on an evacuation fan in a second tunnel between the air conditioning chamber and the containment chamber, the evacuation fan pulling air out of the containment chamber into the air conditioning chamber, opening a valve in an evacuation vent, the evacuation fan pushing air out of the air conditioning chamber through the evacuation vent into the environment; and continuously running the evacuation fan for a predetermined period of time to evacuate air out of the containment chamber.

A centrifuge tube holding assembly includes a body having a front side, a back side, a top edge, a bottom edge, a first lateral edge and a second lateral edge. The top edge has a plurality of apertures extending downwardly therein and each of the apertures may be used for removably receiving an ultracentrifuge tube. The front wall has an opening therein for viewing an open space positioned below the top edge. A panel is positioned over the opening. The panel is transparent to allow viewing through the panel.

The panel has measurement indicia thereon configured to be positioned to be alignable with the ultracentrifuge tube.

The invention relates to a temperature-control element (4) for a multiwell plate (1), which comprises a plurality of cavities (2) arranged in rows and columns for freezing and/or thawing biological samples. The temperature-control element (4) comprises a base body (6) which is made of a thermally conductive material and is flown through by a temperature-control fluid; and a plurality of protruding temperature-control fingers (5) arranged in rows and columns on an upper side of the base body (6), which are connected in a thermally conductive manner to the base body (6), wherein a grid spacing of the temperature control fingers (5) corresponds to a grid spacing of the cavities (2) of the multiwell plate (1). The invention further relates to a device and method for freezing biological samples, in particular for cryopreservation, and/or thawing biological samples, in particular a cryopreserved sample.