There is provided an automated analysis device capable of transferring a rack to a predetermined instrument extraction position efficiently and rapidly, the rack being loaded with instruments to be used for an analysis process. An automated analysis device of the invention includes a conveyance unit to raise and lower a plurality of racks in a vertically stacked state to convey the racks into an analyte processing space, the racks being loaded with instruments to be used for analyte processing. The conveyance unit includes a movement mechanism to move an uppermost rack from a rack standby position to an extraction position with guidance of a protrusion and a recess while maintaining a state of slidable protrusion and recess engagement between the uppermost rack and a rack below the uppermost rack.

The present invention describes an integrated incubator and image capture module that regulates the incubator atmosphere and obtains high-resolution digital images of sample specimens. The incubator has a cabinet type enclosure that enables the provision of a controlled environment to the contents of the incubator by having at least three ports on one face of the cabinet for the passage of sample containers. Additionally, an image capture module is located immediately adjacent to the incubator. In this regard, using at least three separate access/egress points for the sample containers streamlines operation of the system and enhances preservation of the incubator environment. Furthermore, locating the image capture module directly adjacent to the incubator reduces the amount of time a sample container is exposed to the external environment, thereby reducing the extent to which samples are exposed to potential contaminants and reducing the exchange of the lab and ambient atmospheres.

A positioning system for positioning a consumable rack in a diagnostic system is disclosed. The positioning system comprises a rack comprising an upper surface comprising holding positions and a receiving compartment comprising a rectangular chassis comprising front, rear, and two lateral sides. The receiving compartment comprises a holding structure coupled to the chassis to move between first and second positions. The rack comprises sidewalls. At least three sidewalls have a center alignment element. The chassis comprises three chassis alignment elements on the rear and two lateral sides. The holding structure comprises a corner push element between the chassis front and lateral sides to push against a side edge of the rack between two sidewalls when the holding structure is moved from the first position towards the second position forcing the three alignment elements against a chassis alignment element and laterally holding the rack in position by the chassis alignment elements.

The present invention describes an automated platform for inoculating a variety of receptacles with biological samples for testing and analysis. The lab automation system includes a plurality of modules used to automate the inoculation of media for subsequent analysis. In this regard, the lab automation system has one module to enter specimen/order information and store an inventory of petri dishes. Another module is used to label the sample receptacles with a unique identifier that associates the receptacles with the sample. Yet another module includes a robot for retrieving sample and inoculating the receptacles. The sample inoculation module also includes an apparatus that will receive slides, inoculate those slides, and further process the slides for analysis. Finally, the lab automation system includes a module that streaks the culture media with the sample. Thus, the automated lab system described herein provides consistent samples with minimal input from a lab operator.

The present invention relates to an extraction apparatus capable of simultaneously extracting target materials from multiple biological samples and, more particularly, to a target material extraction apparatus in which magnetic bar blocks can be replaced according to kinds of multi-well plates to be inserted into a cartridge. When used, the target material extraction apparatus of the present invention is operated in such a manner that among various multi-well plates having different numbers of wells, multi-well plates suitable for a use purpose are loaded into a cartridge within the apparatus and magnetic bar blocks equipped with magnetic bars suitable therefor are selected and loaded. Thus, the apparatus has the advantage of selectively applying various multi-well plates to one installment according to the number of samples from which a target material is extracted or to the amount of the target material to be extracted.

The present invention describes an integrated incubator and image capture module that regulates the incubator atmosphere and obtains high-resolution digital images of sample specimens. The incubator has a cabinet type enclosure that enables the provision of a controlled environment to the contents of the incubator by having at least three ports on one face of the cabinet for the passage of sample containers. Additionally, an image capture module is located immediately adjacent to the incubator. In this regard, using at least three separate access/egress points for the sample containers streamlines operation of the system and enhances preservation of the incubator environment. Furthermore, locating the image capture module directly adjacent to the incubator reduces the amount of time a sample container is exposed to the external environment, thereby reducing the extent to which samples are exposed to potential contaminants and reducing the exchange of the lab and ambient atmospheres.

A reagent management apparatus according to the present disclosure includes a communicator configured to communicate with an automatic analyzer to acquire reagent information on reagents in the automatic analyzer, a memory configured to store stored reagent information on reagents in a reagent storage and the reagent information on the reagents in the automatic analyzer, and a stored reagent manger to manage the stored reagent information on the reagents in the reagent storage and the reagent information on the reagents in the automatic analyzer stored in the memory.

The present invention describes an automated platform for inoculating a variety of receptacles with biological samples for testing and analysis. The lab automation system includes a plurality of modules used to automate the inoculation of media for subsequent analysis. In this regard, the lab automation system has one module to enter specimen/order information and store an inventory of petri dishes. Another module is used to label the sample receptacles with a unique identifier that associates the receptacles with the sample. Yet another module includes a robot for retrieving sample and inoculating the receptacles. The sample inoculation module also includes an apparatus that will receive slides, inoculate those slides, and further process the slides for analysis. Finally, the lab automation system includes a module that streaks the culture media with the sample. Thus, the automated lab system described herein provides consistent samples with minimal input from a lab operator.

An apparatus for cup loading and unloading and a thromboelastography machine are provided. The apparatus for cup loading and unloading includes a base, a shaft, a movable cover, and a cup holder. The shaft is rotatably connected to the base about an axis of the shaft and has an end configured to engage with an inner cup. The movable cover is disposed around the shaft and slidably connected to the base along the axis of the shaft. The movable cover is provided with an elastic member therein. The cup holder is slidably connected to the base along the axis of the shaft and disposed below the base and the shaft. The cup holder has a cavity configured to engage with an outer cup, and the cavity has an open directed upward.