A microplate processing device having at least one carriage with a first receptacle for microplates where the at least one carriage is movable in a first horizontal direction, and having at least one lift that is movable in a vertical direction, where the microplates can be removed from and supplied to the carriage, the carriage has a through-opening, the periphery, in the vertical projection, can at least in part be situated horizontally within the periphery of a microplate held in the carriage, and the lift has a second receptacle for microplates, the periphery, in the vertical projection, is situated within the periphery of the through-opening, where the second receptacle can be moved unhindered through the through-opening in the vertical direction.

The present disclosure relates to a laboratory sample container carrier handling apparatus comprising a revolving device, being adapted to move a sample container carrier supplied to the revolving device along a circular path P, and wherein the circular path P has at least one ascending ramp. The present disclosure relates further to a laboratory sample distribution system comprising such a laboratory sample container carrier handling apparatus.

Provided are a sample container gripping device capable of gripping a sample container without allowing foreign matter to be mixed into a sample, a sample conveyance device comprising the sample container gripping device, and a connection device. This sample container gripping device for gripping a sample container accommodating a sample is characterized by comprising a pair of clamps that are kept outside of a conveyance path, which is for conveying a sample carrier upon which the sample container is placed, until the sample carrier is conveyed to a prescribed position and, when the sample carrier is conveyed to the prescribed position, move horizontally toward the conveyance path so as to grip the sample container from the horizontal direction at the prescribed position.

A transport system includes a sample rack configured to hold a sample and comprising a notch; a rack storage unit in which the sample rack is stored; a transport path arranged to transport the sample rack moved from the rack storage unit; and a regulating member configured to regulate movement of the sample rack from the rack storage unit toward the transport path, wherein the regulating member is provided at a position corresponding to the notch provided in the sample rack, and enters an interior of the sample rack from the notch and abuts an interior wall of the sample rack as the sample rack moves from the rack storage unit toward the transport path.

The present invention relates to a horizontal-flow-type apparatus for automatically transporting reagent cartridges. The apparatus includes: a magazine (110) in which a plurality of reagent cartridges (1) is stacked; a conveyer belt (120) having a plurality of separating projections (121) arranged in a conveying direction to horizontally separately convey the reagent cartridges (1); a driving motor (130) for driving the conveyer belt (120); a feeding unit (140) for feeding the reagent cartridges (1) stacked in the magazine (110) onto the conveyer belt (120); an examining unit (150) disposed over the front end of the conveyer belt (120) to examine the reagent cartridges (1); and reagent cartridge aligning members (161, 162) disposed in the conveying line of the conveyer belt (120), opposite to the examining unit (150), to align the reagent cartridges (1) in position.

A stall detection system is provided that determines if a glass slide in motion during an automated process is at risk for being damaged and stops motion in the event of an unacceptable risk of damage. The system includes one or more motors configured to move a glass slide (directly or indirectly). The motors are configured to generate a load resistance value. The system includes one or more processors that monitor the load resistance value of a motor during motion and compares the load resistance value to a predetermined threshold resistance value to determine the risk of a glass slide being damaged. The predetermined threshold resistance value may correspond to a risk of slide breakage in response to a force applied to any surface of the slide, or a risk of losing a controlling grip on a slide rack, or a risk of a motor skipping a motor step.

A biological sample test system and method includes a remote sample delivery system, configured to secure a container for a biological sample, the container including a sample identifier. A sample receiving station is configured to receive the container from the remote sample delivery system based on the sample identifier. The remote sample delivery system is configured to automatically navigate to the sample receiving station upon the container being secured to the remote sample delivery system. A sample test track, comprising a plurality of test stations and a container conveyance system configured to sequentially deliver the container to individual ones of the plurality of test stations based, at least in part, on sample identifier.

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.

When the consumable is to be conveyed by a reagent gripping mechanism 110 and a reagent conveyance mechanism 111 during analysis of the sample, a control unit operates such that an operation of a device to access the storage unit is stopped, and makes a plan of operation of the reagent gripping mechanism 110 and a reagent conveyance mechanism 111 such that the consumable is conveyed also at a timing at which an operation of the device is stopped, the timing inevitably occurring after the former stop. Accordingly, an automatic analyzer is provided in which occurrence of an unnecessary empty cycle caused when plural consumables are replaced during analysis can be suppressed compared to a prior art.

A process and system for handling biological tissue samples through work stations in which at least one work stations includes a plurality of independent work locations. The handling system includes a main transport apparatus operatively connected to input and output stations and to the work stations for moving bidirectionally the samples among these; a plurality of secondary transport apparatuses operatively connected to the main transport apparatus and each respectively operatively connected to independent work locations of one of the work stations and configured to move bidirectionally the samples among these; and a control arrangement of the transport apparatuses for managing routing and handling of the samples in the work stations according to a work protocol associated with the samples and for managing routing and handling of the samples in the work locations according to a workload of the work locations and the work protocol associated with the samples.