Example automated storage modules for analyzer liquids are described herein. An example apparatus includes a refrigerated storage module having a plurality of shelves (to store a plurality of carriers) and a loading bay having an array of slots to receive one or more of the carriers. The loading bay is accessible by a user for manual loading or unloading of the carriers. The example apparatus includes a first carrier transporter coupled to the storage module to transfer the carriers between the shelves and a first transfer location and a second carrier transporter movable along a track connecting the storage module to an automated diagnostic analyzer. The second carrier transporter is to transfer a first carrier between the first transfer location and a slot in the loading bay and a second carrier between the first transfer location and a second transfer location accessible by the automated diagnostic analyzer.

The present invention is directed to a system and method for load balancing specimen containers between a plurality of automated detection apparatuses. The method may include receiving a specimen container at a container pick-up station in a first automated detection apparatus; determining loading ability, transfer status, and cell availability of the first automated detection apparatus and one or more downstream automated detection apparatuses; and transferring the specimen container from the first automated detection apparatus to a downstream automated detection apparatus when a first ratio of effective available cell count to effective capacity in the first automated detection apparatus is less than a second ratio of total effective available cell count to total effective capacity of a sum of the first automated detection apparatus and the one or more downstream automated detection apparatuses.

A sample analysis system includes a first measurement unit, a second measurement unit arranged to a downstream side of the first measurement unit, and an information processing section which obtains a measurement result of a sample. The information processing section determines, based on the measurement result of the sample measured by the first measurement unit, whether or not a retest of the sample by the first measurement unit is necessary. When the retest by the first measurement unit is necessary, the information processing section causes the sample container to be transported to a first sample supply position for the first measurement unit and causes the first measurement unit to perform measurement of the sample.

The present invention is directed generally to devices and methods for manipulating laboratory pipettes in a programmable manner. The present invention is directed to an apparatus and methods for allowing a user to instruct the device to perform a specific process; identifying the type, location and identity of the consumables to be used; manipulating a plurality of pipettes for performing the liquid handling; monitoring the process during and after its execution; generating a detailed report for the plurality of actions. Other aspects of this invention include optimization of the liquid dispensing performances of a pipette; monitoring and controlling individual actions by means of vision; virtualization of the protocol definition by means of a reality augmented software interface; integration of the system in a conventional laboratory environment workflow.

The purpose of the present invention is to provide an automatic analysis device capable of efficiently performing a plurality of analyses, while reducing the footprint and cost of the device. Provided is an automatic analysis device characterized by being provided with containers for containing samples, one rack for placing the containers thereon, and a control unit, the control unit generating, with respect to the one rack, a plurality of registration patterns in which information of the positions where the containers are disposed, and information of the samples contained in the containers are correlated with each other, storing the registration patterns thus generated, applying, to the one rack, one registration pattern selected from among the registration patterns thus stored, and analyzing the samples. Also provided is an analysis method using the device.

An analyzer is disclosed. The analyzer comprises a rack slot configured to receive at least one rack, wherein the rack slot comprises a front end, at which the rack is manually loadable into the rack slot, and a rear end, which is opposite to the front end and at which the rack is fully receivable in the rack slot, and a spring device arranged at the rear end, wherein the spring device is configured to provide a biasing force towards the front end, wherein the biasing force is adapted to move the rack towards the front end if not fully received in the rack slot, wherein the spring device is configured to fix the rack in a final position if the rack is fully received in the rack slot. Further, a method for loading a rack into a rack slot of an analyzer and a system comprising an analyzer and a computer controller are disclosed.

Automatic analyzers, in which the liquids to be analyzed are in so-called reaction vessels, simultaneously acting as optically high-quality cuvettes (10), are used in laboratories for analyzing various liquids. Further described is a handling package for cuvettes (10). A removable bonding strip (100) is fastened on the rows of cuvettes (10), the strip (100) binding the rows of cuvettes (10) during transport, and being easily removable when the cuvettes (10) are loaded into the instrument. The cuvettes (10) are loaded into the instrument by supporting the package in its place from the brackets (24) located in the ends of the cuvettes (10), so that the strip (100) can be pulled off the supported package of cuvettes (10).

A measurement system according to one or more embodiments may include a measurement unit that measures a sample contained in a sample container; a transport unit including a first transporter that transports a rack holding sample containers in a longitudinal direction of the rack to the measurement unit, and a second transporter that transports the rack from the measurement unit; and a rack export-import unit that sets racks thereon, that is capable of transferring each of the set racks in a lateral direction of the rack, that exports the rack to the first transporter from one end side of the rack export-import unit, and that imports the rack transported by the second transporter from another end side of the rack export-import unit. The rack export-import unit includes a transfer prevention section that prevents the rack imported from the other end side from being transferred from the one end side.

A sample analysis system includes one or more sets. Each of the one or more sets include includes a measurement block including measurement units configured to test a sample contained in a sample container, and a transport unit disposed corresponding to the measurement block. The transport unit includes a first transport path along which a sample rack is transported from an upstream side to a downstream side and a second transport path along which the sample rack received from the first transport path is transported to the measurement units in the measurement block. The second transport path is configured to move the sample rack back and forth between the measurement units to distribute the sample containers held on the sample rack to the measurement units.

A system for placing sample tubes into tube receptacles includes a sample handling device that includes an electrical signal, relating to an operating condition, such as a position error, a tube receptacle, and a processor configured to control the sample handling device in response to the electrical signal. The processor observes the operating condition for signal artifacts that indicate that a sample vessel being placed has encountered a holding spring and subsequently the bottom of the tube receptacle. The processor provides substantially real-time control of the motion of the sample handling device in response.