A biological analysis system comprising at least one inlet and one outlet, at least two biological analysis devices connected to one another by a conveyor defining a closed circuit, each biological analysis device comprising a region for the exchange of tube holding racks with the conveyor. The conveyor and the at least one inlet of the biological analysis system comprise a reader of an identifier of a tube holding rack which reader is designed to communicate an identifier it has read to a controller of the biological analysis system, which controller is designed to apply a specific treatment to a tube holding rack identified by the reader of the conveyor and the identifier of which has not previously been read by the reader of the at least one inlet of the biological analysis system.

The present invention is provided with: an automatic analysis device 200 for performing an analysis process to analyze a specimen that is to be analyzed; a specimen pre-processing module 100 for performing pre-processing to cause the specimen to enter a state in which the analysis process can be performed; a main conveyance line 161 for conveying a specimen container carrier 10 which accommodates the specimen that is to be analyzed and in which at least one specimen container can be mounted; and annular conveyance lines 111, 121, 131, 141, 151, 411 that are disposed adjacent to the main conveyance line 161 and that are moreover disposed so as to be capable of transferring the specimen container carrier 10 to and from the main conveyance line 161, the annular conveyance lines 111, 121, 131, 141, 151, 411 being capable of circulating and conveying the specimen container carrier 10 separately without the use of another conveyance line (e.g., a return line 162). This makes it possible to maintain flexibility in conveyance of specimens while suppressing increases in device surface area.

Provided is a connection module with a high degree of freedom for an automatic analyzer which does not depend on a device as a discharge destination. For this purpose, a module to be connected to an automatic analyzer with a rack rotor mechanism includes: a rack discharge mechanism for moving a rack from the rack rotor mechanism to a rotation holder; a rack rotating mechanism for rotating the rack moved to the rotation holder; a conveyor mechanism for transporting the rack from the rack rotating mechanism to a discharge port; and a feeder mechanism for pushing the rack out of the rotation holder to the conveyor mechanism, in which the rack rotating mechanism rotates the rotation holder from a direction parallel to the rack discharge mechanism to a direction parallel to the feeder mechanism and the conveyor mechanism in the selected rotation direction.

A device includes sample tray units, a sample tray transporting unit, a sample tray handling unit, and a sample tray radiation stage unit. The sample tray units are configured to load samples. The sample tray transporting unit is configured to carry a sample tray unit to a radiation room. The sample tray handling unit is between the sample tray transporting unit and the sample tray radiation stage unit, and is configured to transfer the sample tray unit on the sample tray transporting unit to the sample tray radiation stage unit or return the sample tray unit on the sample tray radiation stage unit to the sample tray transporting unit. The sample tray radiation stage unit is configured to carry the sample tray unit and move the samples to be irradiated in the sample tray unit to a particle beam radiation area to receive radiation.

There is provided a technique that can efficiently control disposal and use of containers of an automatic analyzer. An automatic analyzer includes a controller, a container retaining mechanism (incubator), a dispensing mechanism, a detection mechanism, and a transfer mechanism. The dispensing mechanism includes a liquid surface detection mechanism. The controller uses the dispensing mechanism at a prescribed timing to detect the presence or absence of the liquid surface at a target position on the container retaining mechanism to determine a state including the presence or absence of the container accommodating a reaction solution. The controller performs control in which the operation of disposal using the transfer mechanism is performed at a position when a state is determined in which the container is present, and the operation of disposal using the transfer mechanism is not performed at the position when a state is determined in which the container is not present.

A fluid container holder includes a body having a receptacle configured to receive a container. The body has a conductive outer surface for connection to an electrical ground or voltage source, and the holder is not formed solely of an electrically conductive metal. A fluid container handling assembly includes a drawer having a holder supporting a fluid container, and a frame supporting the holder. The frame is movable between a first position providing access to the holder and a second position positioning the holder within the instrument. The assembly also includes a first lock securing the holder to the frame when the frame is at the first frame position and unlocking the holder from the frame when the frame is at the second frame position. The assembly also includes a holder transporter configured to move the holder between a first holder position and a second holder position within the instrument.

Disclosed are high-throughput vessel sorting systems and methods of sorting sample vessels, such as samples stored in test tubes. A system for sorting a plurality of individual vessels that each contains a sample is disclosed.

A laboratory sample distribution system is provided comprising: a number of container carriers, wherein the container carriers each comprise a magnetically active device and are adapted to carry a sample container; at least one fan being adapted to cause an airflow; and a number of transport modules, the transport modules being arrangeable adjacent to one another and respectively comprising: a transport surface being adapted to carry the container carriers; a number of heat dissipating electromagnetic actuators being stationary arranged below the transport surface, the electromagnetic actuators being adapted to move container carriers placed on top of the transport surface by applying magnetic forces to the container carriers; and an air guiding element being adapted to guide the airflow first towards an underside of the transport surface and afterwards towards the electromagnetic actuators.

An automated analyzer capable of continuously performing supply of consumables is realized while continuing measurement is performed, by a simple and small amount of mechanism. An automated analyzer includes a unit that executes processing necessary for sample analysis; a consumable supply unit that supplies consumables necessary for the sample analysis to the unit; and a control device that controls operations of the unit and the consumable supply unit, in which the consumable supply unit includes a consumable container holding portion that holds a consumable storage container in which consumables is aligned and accommodated, a preliminary storage portion that temporarily holds the consumables taken out from the consumable storage container, and a transport mechanism that transports the consumables to the unit, and in which the control device transports and stores at least a portion of the consumables taken out from the consumable storage container in the preliminary storage portion.

The present disclosure provides cryogenic storage systems and methods of using the cryogenic storage systems. A cryogenic storage system of the present disclosure may comprise a cryogenic tank with an inner door and an outer door, and a robot apparatus located adjacent to the cryogenic tank. The cryogenic tank may store multiple racks such that at most a single rack is removable through the inner door or the outer door. The cryogenic tank may store the multiple racks in multiple groups of racks comprising a first group of racks located at a first radial distance and a second group of racks located at a second radial distance that is greater than the first radial distance. The robot apparatus may selectively open and close the inner or outer doors, and insert or withdraw the single rack into or out of the cryogenic tank through the inner door or the outer door.