A sample container handling device is presented. The device comprises a linear transport unit and a release unit comprising a release blade segment. The release blade segment is rotated in a constant rotational direction.

Provided is a specimen treatment system that can detect whether a specimen container is uncapped by using a simple mechanism. The specimen treatment system comprises: an automatic analyzer that analyzes a specimen; a pretreatment device that performs a pretreatment on the specimen; and a conveyance passage that conveys, in the automatic analyzer or in the pretreatment device, a specimen container that houses the specimen. The specimen treatment system is characterized by further comprising a single sensor that is disposed so as to be orthogonal to the longitudinal direction of the specimen container and that detects whether the specimen container is uncapped.

A processing unit for automated preparation of biological samples included in specimen tubes is described herein. The processing unit includes a removable sample preparation component configured to receive specimen tubes, read identifiers associated with the biological samples contained in the specimen tubes, mix reagents included in the specimen tubes, and transfer the specimen tubes to at least one of a centrifuge or a storage compartment. The processing unit further includes a centrifuge loader for automatic loading and unloading of the specimen tubes onto a centrifuge. The automated centrifuge loader includes a magnetic brake that can stop the centrifuge rotor at a precise position to facilitate loading and unloading of a specimen tube. The centrifuge includes a swing bucket designed to pivot around an axis and slide vertically to enable moving the bucket to a position in which the swing bucket can engage with the port where the specimen tube resides.

A device for agitating and collecting biological liquid samples comprises an agitator of racks of tubes, a sampling apparatus capable of collecting a biological liquid sample in a tube, and a changer capable of gripping a tube on a rack received in the agitator and moving it to the sampling apparatus. The agitator is capable of agitating at least three racks simultaneously, and the device also comprises a scheduler capable of determining destination data for a tube and destination data for the rack which receives this tube, and of determining for each tube a final location based on the destination data of the tube and the destination data of the racks received in the device, which final location designates a rack, received on the agitator and a position on this rack and can be different from the location of the tube when the rack that received it has been introduced into the device, and arranged to control the changer in order to grip a tube, present it to the sampling apparatus and replace it after sampling at the final location.

A rack for holding samples and various reagents, wherein the rack may be used for loading the samples and reagents prior to using the reagents. The rack accepts complementary reagent holders, each of which contain a set of reagents for carrying out a predetermined processing operation, such as preparing biological samples for amplifying and detecting polynucleotides extracted from the samples.

A method of establishing a sample tube set which is adapted to be processed by a laboratory automation system. The method includes selecting a sample tube set comprising several sample tube types by selecting a plurality of different sample tube types from an assortment of available sample tube types; obtaining a parameter of distribution for at least one detection parameter of each sample tube type comprised in said sample tube set, wherein the parameter of distribution comprises information regarding a distribution of previously detected reference data values of the at least one detection parameter; determining whether the laboratory automation system is capable of correctly identifying each sample tube type comprised in said sample tube set by comparing the parameter of distribution for the at least one detection parameter of each sample tube type comprised in said sample tube set with the parameter of distribution for the at least one detection parameter of all the other sample tube types comprised in said sample tube set; and indicating that the selected sample tube set is approved for being processed by the laboratory automation system if it is determined that the laboratory automation system is capable of correctly identifying each sample tube type comprised in said sample tube set, or proposing at least one conflict remediation if it is determined that the laboratory automation system is not capable of correctly identifying each sample tube type comprised in said sample tube set.

In the past, when centering the center of a liquid surface and fixation thereof proved difficult during mounting a container into an automatic analytical apparatus, there was sometimes the possibility that the accuracy of checking the liquid surface conditions and the pipetting precision could not be ensured. When this problem occurred, there was the possibility that the reliability of the analysis results would be diminished. Accordingly, an automatic analytical apparatus is provided with a probe for suctioning a liquid to be used in analysis, wherein the apparatus is provided with a transport apparatus for transporting a container accommodating the liquid, and a container-clamping apparatus for clamping the container transported by the transport apparatus. The container-clamping apparatus has a vibration suppression mechanism for retaining the clamped container with an elastic body, and a centering retention mechanism with which centering of the container center can be fixed.

Systems, devices and methods are disclosed for collecting laboratory specimens from laboratory specimen boxes once a specimen has been placed inside a box.

A laboratory sample distribution system and a laboratory automation system comprising such a laboratory sample distribution system are presented. The laboratory sample distribution system comprises a number of sample container carriers adapted to move autonomously and to communicate with each other and with a central control unit.

A laboratory sample distribution system in which a sample container carrier can be centered at a specific position is presented. A laboratory automation system with such a laboratory sample distribution system is also presented.