A portable temperature-controlled container for receiving and housing one or more handheld carriers, each handheld carrier configured to transfer samples to and from a temperature-controlled storage environment, the handheld carrier including a handle and a tray portion, the tray portion configured to be slid into a port of a rack or tower provided in the temperature-controlled storage environment in order to withdraw a sample located in the port, the portable temperature-controlled container including a housing having an opening forming an internal cavity configured to receive one or more handheld carriers, and a lid configured to substantially close the opening, where the housing includes a recess configured to receive the handle of the handheld carrier such that closing of the lid substantially seals the internal cavity when the one or more handheld carriers are placed in the housing.

An accommodation unit includes a plurality of accommodation positions, each of the plurality of accommodation positions being capable of accommodating one of the plurality of samples. A detection unit detects identification information of each of the plurality of samples in the accommodation unit. A control unit holds the identification information of each of the plurality of samples received from the detection unit as detected identification information. The control unit is configured to receive identification information of each of a plurality of samples designated as analysis targets, and hold the received identification information as designated identification information. The control unit includes a notification means configured to output a warning before analysis is started by the analysis unit, when the control unit makes a comparison between the designated identification information and the detected identification information and determines that there is a mismatch therebetween.

An automated pre-analytical processing method and an apparatus for pre-analytical processing of samples to be forwarded to an adjacent analyzer for analysis. Rack label information is read and communicated to a processor. From the rack label information, the processor determines where to route the rack. The pre-analytical system has a rack robot that conveys racks to discrete locations depending upon the routing information assigned to the rack by the processor. The pre-analytical system has an automated station that reads the labels of individual sample containers in the rack that are brought to the automated station on instructions from the processor. Depending on the type of sample container and the type of sample disposed therein, the samples are either prepared for analysis by the automated station or the sample containers are directly passed through the automated station. Prepared samples and passed through samples are passed individually to a batching rack.

Since the measurement start timings for a plurality of specimens in different test fields deviate from one another, the measurement results are not coordinated, leading to a delay in reporting. When determining an order for measuring a newly recognized specimen using an automated analysis device capable of performing measurements in a plurality of test fields, the measurement order for specimens waiting to be measured is changed to minimize the time difference between measurement result output timings for a plurality of specimens for the same patient, with reference to specimen information such as urgent test information, a measurement completion time, and an earliest measurement completion time for other specimens, relating to the patient's other specimens having the same patient number in the specimen information.

A reagent analyzer comprising an imaging system having a first field of view of a reagent test device and a second field of view of a fluid sample information indicator, and configured to capture a first image depicting the reagent test device and a second image depicting the information indicator; a mirror moveable between a first position outside the first field of view and a second position inside the first field of view and located between the imaging system and the reagent test device, the mirror in the second position reflecting light to produce the second field of view; and a processor executing instructions to: receive the first and second images; analyze the first image to determine calibration information from the information indicator; and analyze the second image to determine constituent presence/absence in the fluid sample applied to the reagent test device, using, in part, the determined calibration information.

A sample processing station includes two or more container holders on a platform that is rotatable about a central axis of rotation. Each holder is configured to rotate about a secondary axis of rotation. The station includes a capping/decapping mechanism to cap or decap a container held in one of the container holders and an elevator with a chuck guide that contact the container holder as the chuck is lowered by the elevator to positon the chuck with respect to the cap of the container held in the holder and to hold jaws of the container holder in a closed position. In embodiment, the chuck guide includes a yoke with opposed arms and spindles located near distal ends of the arms that engage beveled shoulders of the container holder.

Method and associated system for reading machine-readable labels on a plurality of sample receptacles held by a sample rack. In the method, a machine-readable label associated each of the plurality of sample receptacles is read with a first label reader when the rack is at a first location. The sample rack is then moved from the first location to a second location, where a rack identifier on the sample rack is sensed with a sensor separate from the first label reader. Finally, the rack identifier is associated with the machine-readable labels of the plurality of sample receptacles.

Apparatus and method for acquiring and analyzing biological samples are provided. The apparatus may be in the form of a free-standing apparatus, and include: means for receipt of identifying data of the individual; means for receiving the biological sample for the individual; means for providing a unique identifier for the biological sample and association with the individual; and means for conducting an analysis of the biological sample and generating a report of analysis results; wherein all of the foregoing means are under control of a microprocessor located in the apparatus. The apparatus and method allow fast processing of samples.

A sample group forming section 24 classifies samples derived from microorganisms into groups according to empirical information showing the species or strain of each sample. A differential analysis section 27 performs a differential analysis using a peak matrix created based on the result of the grouping. An operator enters group rearrangement conditions concerning the drug resistance of microorganisms. Under the entered conditions, a sample group rearranging/rearrangement-cancelling section 25 rearranges the already formed groups by selecting or merging groups using another kind of previously registered empirical information which shows the drug resistance of each group. The differential analysis section 27 performs a differential analysis using a peak matrix newly created based on the result of the rearrangement of the groups. Thus, differential analysis results concerning the resistance to different drugs can be sequentially acquired as the group rearrangement condition is successively changed.

A method to store sample tubes in a laboratory storage and retrieval system is presented. The laboratory storage and retrieval system comprises a storage section, a database comprising a sample tube inventory of the storage section, a control device, and at least one sample tube transport system. The storage section comprises at least two storage subsections. In a first step of the method, the control device identifies at least two sample tubes with at least one substantially identical sample tube attribute and distributed over the at least two storage subsections. In a second step of the method, the at least one sample tube transport system consolidates the at least two sample tubes in at least one storage subsection, wherein the control device further determines in which of the at least two storage subsections the identified sample tubes are consolidated.