A sample examination automation system includes a conveyance line, a large-scale sample carrier buffer, an analyzer coupling unit, and a conveyance managing unit. The conveyance line conveys a sample carrier. One or a plurality of sample containers is mountable on the sample carrier. The large-scale sample carrier buffer stores a plurality of the sample carriers. The analyzer coupling unit, which is couplable to an analyzer, incorporates a sample carrier sub-buffer capable of storing the sample carriers by an amount smaller than an amount of the large-scale sample carrier buffer. The conveyance managing unit has a function of controlling a sample carrier conveyance destination. The conveyance managing unit is configured to determine an amount of the sample carriers supplied to the sample carrier sub-buffer via the large-scale sample carrier buffer according to a storage situation of the sample carriers in the sample carrier sub-buffer.

A seed sampling system is provided comprising an automated seed loading assembly operable to singulate seeds from a plurality of seeds or enable loading of individually stored seeds and an automated seed sampling assembly comprising at least one sampling module operable to remove tissue samples from one of the singulated seeds. The system also includes an automated seed transport assembly comprising at least one retention member operable to transfer the singulated seeds from at least one elevator unit of the seed loading assembly to the at least one sampling module of the seed sampling assembly. In connection therewith, the at least one sampling module includes multiple sampling locations, each associated with a sampler, where the at least one sampling module is operable to remove tissue samples from seeds at one of sampling locations while another one of the sampling locations is cleaned to remove residual seed tissue therefrom.

The present invention is provided with a sample rack insertion unit 12 that is capable of holding one or more sample racks 5 having mounted therein one or more sample containers 6 accommodating a sample to be analyzed, one or more analysis devices 2, 3 for analyzing the sample accommodated in the sample containers 6, a sample rack conveyance unit 14 for conveying the sample racks 5 from the sample rack insertion unit 12 to the analysis devices 2, 3, and a control device 4 for acquiring, for each analysis device 2, 3, load information that is information expressing an operating condition of the analysis device 2, 3, and, if there is an analysis device 2, 3 for which the load information is larger than a predetermined conveyance permission value, carrying out control so as to stop the conveyance of the sample racks 5 from the sample rack insertion unit 12 to the analysis device(s) 2, 3. As a result of this configuration, it is possible to mitigate in-device sample conveyance congestion occurring as a result of the insertion of many samples and keep the sample environment and analysis processing power at high levels.

Provided is an automatic analyzer capable of reducing risks such as infection, injury, and damage to the device caused by manual operation of a user. In the automatic analyzer according to the present disclosure, an unused vessel holding unit is configured to be able to hold a cleaning member that cleans a hole for mounting a reaction vessel, and a reaction vessel transport unit or a specimen probe picks up the cleaning member from the unused vessel holding unit, transports the cleaning member to the reaction vessel mounting unit, and inserts and removes the cleaning member into and from the hole, thereby cleaning the inner surface of the hole.

In order to provide a biological sample analysis apparatus capable of preventing a container storing a sample from being charged and of measuring only a luminescence intensity of light emitted from the sample accurately, a biological sample analysis apparatus for rapid microbiological test analyzes light generated from a biological origin substance contained in a sample, and includes a holder that holds a plurality of containers storing the sample, a photodetector fixed at a predetermined position, a holder drive mechanism that drives the holder and sequentially positions each of the containers held by the holder at a detection position detected by the photodetector, and a neutralizer that neutralizes the containers held by the holder.

An automatic analyzer with high processing capacity is capable of immediately measuring an emergency specimen rack. The automatic analyzer includes a conveying line for conveying a specimen rack, and an analysis unit which has a dispensing line in which a plurality of specimen racks are arranged for waiting until sample dispensing, and a sampling area for dispensing the sample to the analysis unit. A rack save area is provided in the dispensing line and at a position adjacent to the upstream side of the sampling area. When a specimen rack exists in the sampling area at the time of measuring an emergency specimen rack, a controller moves the specimen rack to the save area and positions the emergency specimen rack to be moved from a downstream side of the sampling area to the sampling area.

The present disclosure relates to a laboratory system to monitor reference points of laboratory devices. The laboratory system comprises a first laboratory device comprising a first reference point, a second laboratory device comprising a second reference point, and a coupling element. The coupling element couples the first reference point and the second reference point. The coupling element comprises a detectable part adapted to be moved between a starting position and at least one detection position when the relative position of the first reference point and the second reference point to each other changes. The laboratory system further comprises a sensor configured to detect the detectable part of the coupling element in the at least one detection position. In addition, a method of operating the laboratory system as described 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.

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.