To suppress inflow of external air through a rack insertion opening while a sample rack is pulled out. An apparatus includes a housing, a temperature control space, and an air temperature control part. The housing has the rack insertion opening on one side surface for putting in and taking out the sample rack. The air temperature control part has an air intake portion for intake of air in the temperature control space, a fan for blowing air taken in from the air intake portion toward the sample rack accommodated in the temperature control space, and a cooling element provided to cool the air on a path of air taken in from the air intake portion. The air temperature control part is configured to reduce an amount of air flowing near the rack insertion opening while the sample rack is pulled out from the temperature control space as compared to while the sample rack is accommodated in the temperature control space, so as to suppress inflow of air through the rack insertion opening.

A storage module for a laboratory automation system, a method of operating a laboratory automation system, and a laboratory automation system are presented. Items used by laboratory stations are stored centrally in a storage module and can be transported to the laboratory stations using a laboratory sample distribution system.

A cuvette discarding unit includesa cuvette discarding container capable of discarding a cuvette from a top opening an accommodation frame capable of accommodating the cuvette discarding containerand a cuvette receiving part arranged at a top of the cuvette discarding container and having an input port into which a cuvette is charged. The cuvette receiving part has a movable cuvette receiving bottom part. The cuvette receiving bottom part is held in a retracted posture allowing the cuvette received from the input port to be charged into the cuvette discarding container at a lower position in a state in which the cuvette discarding container is accommodated in the accommodation frame, and held in a temporary receiving posture for receiving the cuvette received from the input port in a state in which the cuvette discarding container is not accommodated in the accommodation frame.

A laboratory module for storing and providing access to a plurality of samples, the laboratory module comprising a plurality of bays comprising a plurality of guiding rails and a plurality of rack tray bays for accommodating a plurality of rack trays, and a transport chamber for transporting at least one sample rack to a storage location and for delivering at least one sample rack at predetermined times to a processing system. The transport chamber is adapted to align with any one of the plurality of guiding rails, comprised in the bays and in the rack trays, for placing and moving on the guiding rails the at least one sample rack, and a sensor for sensing the presence and location of a sample rack on any one of the guiding rails, and a barcode scanner that identifies the sample rack and a storage device for storing data.

The present disclosure relates to a laboratory container storage system, a laboratory system comprising the laboratory container storage system, and a method of operating the laboratory system. The laboratory container storage system comprising one or more laboratory container storage devices. Each laboratory container storage device comprises a frame and a storage element comprising a holder configured to receive and release a laboratory container horizontally and to hold the laboratory container in a suspended position above a horizontal surface. The storage element is mounted movably on the frame and configured to be moved between a first transfer position and a storage position and between the storage position and a second transfer position. In the first and second transfer position, the holder is positioned to receive or release the laboratory container horizontally. The storage position is located between the first and second transfer position.

The invention is an improved multiplex capillary electrophoresis instrument or module with at least four and preferably six user-accessible vertically stacked drawers. An x-z stage moves samples from the user accessible drawers to the capillary array for analysis. An additional mechanical stage moves the array from side-to-side. The x-z stage, coupled with the additional array stage allows the system to sample all wells of a 384 well plate with a 96-capillary array. A computer program allows users to add capillary electrophoresis jobs to a queue corresponding to the analysis of rows or plates of samples without stopping or interrupting runs in progress.

An analyzer system for in vitro diagnostics includes a sample handler module having a robot arm that delivers samples from drawers into carriers on a linear synchronous motor automation track. Samples are delivered via the automation track to individual track sections associated with individual analyzer modules. Analyzer modules aspirate sample portions directly from the sample carriers and perform analysis thereon.

A liquid handling instrument and pipetting head for and method of aspirating and/or dispensing liquids is disclosed. Namely, an automated liquid handling instrument is provided for aspirating and/or dispensing liquids from source media to destination media using at least one pipetting head and by using a positive displacement pipette tip, wherein the positive displacement pipette tip includes a pipette tip and a pipette plunger. A pipetting head of the liquid handling instrument includes an arrangement of plates, threaded rods, motors, timing (or drive) belts, and custom timing pulleys/nuts. The pipetting head further includes an arrangement of pipette plunger clamping mechanisms and pipette tip clamping mechanisms that feature zero-insertion force clamping mechanisms.

A laboratory sample vessel distribution system is presented. The system comprises a cabinet, sample vessel carriers for receiving sample vessels, and a cabinet drawer for receiving a sample vessel carrier. The drawer is locatable in different positions: closed, opened, and fully opened. An actuator moves the sample vessels and the sample vessel carriers between different locations. An actuator driver drives the actuator and applies a first mode of operation with a first speed and a second mode of operation with a second reduced speed compared to the first speed. A sensor device detects between opened and closed positions and provides position signals. A control device is connected to the actuator driver and the sensor device. The control device provides control signals to the actuator driver instructing the actuator driver to apply either the first mode, if in the closed position, or the second mode, if in the opened position.

In a case where a dispensing tip is imaged from below, liquid attached to the tip falls downward and contaminates an imaging mechanism. An automatic analyzer includes: a buffer that has a hole for holding a tip for dispensing, the hole passing through the tip; a probe for dispensing having a tip to which the tip is attached; an imaging unit that images the tip; and a controller that controls the tip such that the tip is mounted on the probe by pressing the probe against the tip that passes through the hole to be held by the buffer, in which the imaging unit is disposed to image the tip from an upper side to a lower side in a gravity direction.