A specimen processing apparatus may include: an aspirating tube configured to aspirates a specimen in automatic aspiration and manual aspiration; an aspirating tube moving mechanism configured to move the aspirating tube between a first region in which the automatic aspiration is performed and a second region in which the manual aspiration is performed, the first region covered with a wall, the second region separated from the first region; and a processing unit that processes the specimen aspirated by the aspirating tube.

A system for processing a plurality of sample containers, each containing sample with at least one open assay associated therewith, includes two or more analyzers, each configured to perform at least one functional assay in receptacle apparatuses including a process number of two or more receptacle vessels, a conveyance for transporting containers to the analyzers, a buffer queue associated with each analyzer for holding containers to be processed by the associated analyzer, and a scanner associated with each analyzer. Each scanner scans machine-readable identification information associated with each container transported by the conveyance past the scanner and the open assay(s) for that container are identified based on the scanned information. The sample container is diverted into the associated buffer queue only if at least one open assay for that container matches at least one functional assay of the associated analyzer. The system attempts to accumulate at least the process number of sample containers with the same open assay so that the matching functional assay can be performed on the different samples in each of the process number of receptacle vessels of each receptacle apparatus.

In a case where plural measurement items that require different incubation times are simultaneously measured in an automatic analyzer, deterioration of the turnaround time of the measurement is minimized. The automatic analyzer receives a request of a sample, obtains a ratio of a short measurement item among examination items of the received analysis request, and a determines an empty cycle based on the ratio of the short measurement item and the number of schedules. When an empty cycle is necessary, the empty cycle is scheduled in a schedule of a sample that is requested to be measured first, for example, an empty cycle in a short measurement for making an incubator empty. As a result, this position can be used for a measurement of a short measurement item such that the wait time of the start of the measurement can be short.

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.

The invention relates to a transport unit for sample containers which enclose samples to be analysed by an automatic diagnosis unit, the unit comprising: a transportation route (10) of racks (3) of samples, said route (10) extending according to a first direction (A), said route comprising a first end (102) adapted to receive a rack of samples from a first device and comprising a second end (101) adapted to transmit a rack of samples to a second device; a mobile platter (15) comprising a positioning surface extending in a plane; an analysis zone (13) arranged inside the positioning surface, and a waiting zone (12) arranged inside the positioning surface, the analysis zone (13) and the waiting zone (12) being both adapted to receive a rack (3) of samples and being both offset from the transportation route (10); a rack slider (14) configured to move a rack (3) of samples between the transportation route (10) and the waiting zone (12).

A sample analyzer includes a suction unit configured to suction a sample in a sample container through a stopper installed in an opening of the sample container; a rack transport unit configured to transport a sample rack holding a sample container along a transport path, and position the sample container held by the sample rack at a suction position by the suction unit; a sample transport unit in which a sample container other than the sample container transported by the rack transport unit is installed and which is configured to transport the installed sample container to the suction position provided on the transport path; a measurement unit configured to measure a sample suctioned by the suction unit from the sample container positioned at the suction position; and an analysis unit configured to analyze the sample based on the measurement result of the measurement unit.

Systems and methods are described to determine a prioritization schedule for samples handled by a system with multiple remote sampling systems. A system embodiment includes, but is not limited to, an analysis system at a first location; one or more remote sampling systems at remote from the first location, the one or more remote sampling systems configured to receive a liquid segment and transfer a liquid sample to the analysis system via a transfer line; and a controller communicatively coupled with the analysis system and the one or more remote sampling systems, the controller configured to assign a priority value to a sample for analysis by the analysis system and to manage a queue of samples received from at the one or more remote sampling systems on the basis of the assigned priority value.

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.

The invention relates to a tissue processor (100) for automatically processing histological tissue specimens, the tissue processor (100) comprising a plurality of containers (1, 2, 3, 4, 5, 6, 7) each being provided for a respective histological process for processing at least one tissue carrier, a robotic arm (9) for handling a tissue carrier between the containers (1, 2, 3, 4, 5, 6, 7) for being processed in each of the containers (1, 2, 3, 4, 5, 6, 7), and a control unit for controlling the histological process in each of the containers (1, 2, 3, 4, 5, 6, 7) and for controlling the robotic arm (9), wherein the control unit is configured such that the robotic arm (9) handles a tissue carrier between the containers (1, 2, 3, 4, 5, 6, 7) while the histological process in each of the containers (1, 2, 3, 4, 5, 6, 7) continues in an uninterrupted fashion, so that the execution of the process for each tissue carrier is independent from the loading order and/or process duration of other tissue carriers being processed in the containers (1, 2, 3, 4, 5, 6, 7).

An inspection result of a specimen inspection automation system can be reported within a prescribed time, even if a large number of urgent specimens have been input. An instruction reception unit receives turn around time (TAT) information and a discharge instruction. The necessity of discharging a specimen for which the instruction was issued with the discharge instruction is determined and a discharge instruction unit creates a discharge destination and a conveyance route to the discharge destination for the specimen. A discharge mechanism discharges the specimen for which the instruction was issued. Even for a specimen which is caused to wait for processing due to the occurrence of specimen congestion and for which there is a risk of an inspection result reporting delay, an inspection result can be reported within a prescribed time by switching from automatic processing by the system to manual processing by an operator.