A sample transfer device has sample container transfer mechanisms which are arranged between a conveyance path for conveying a sample container holder to one of plural analysis devices. A sample container housing a sample is mounted in the sample container holder. The sample container transfer mechanisms transfer the sample container between the sample container holder and a sample container rack, which is used for mounting the sample container in the analysis device and for conveyance. The sample transfer device determines whether or not an analysis device is in a state suitable for receiving the sample container, and if the analysis device is determined not to be in a state suitable for receiving, controls the sample container transfer mechanism to convey the sample container to the other analysis device via the conveyance path. In this way, it is possible to suppress delays in analysis processing and decreases in throughput.

A method of operating a laboratory sample distribution system is presented. The system comprises sample container carriers comprising a magnetically active device and configured to carry a sample container, interconnected transport plane modules configured to support carriers, and electro-magnetic actuators arranged in rows and columns below each transport plane module and configured to move a carrier on top of the transport plane modules by applying a magnetic force to the carrier. The method comprises assigning transport plane modules to a route category. At least two traffic lanes are formed on the route categorized transport plane module. The carriers are moved within each traffic lane in a transport direction. The transport directions are opposite to each other. The method also comprises assigning another transport plane module to a waypoint category. A change from one transport direction to the opposite transport direction is possible on the waypoint categorized transport plane module.

An automatic analyzing apparatus capable of obtaining an analysis result of a specimen high in urgency in a shorter time is provided. When a first rack 50 is present in a sampling line 103 and an analysis request for a second rack higher in the degree of urgency for analysis than the first rack 50 is detected, a control unit unloads the first rack 50 onto a transport line 100 through a return line 102, allows the first rack 50 to stand by at a rack standby position 120 on a transport line 101 between a loading line 101 and the return line 102 under control, and loads the second rack from the transport line 101 onto the sampling line 103 through the loading line 101 and transports the second rack to the dispensing position 111 under control while allowing the first rack 50 to stand by.

An analyzer for use with in vitro diagnostics includes an automation system to move a plurality of sample carriers within the system. At least some carriers include a plurality of slots. Each slot is configured to hold one of a plurality of fluid containers. The system also includes a place and pick device configured to place the plurality of fluid containers into the plurality of slots and remove the plurality of fluid containers from the plurality of slots. The system further includes a controller configured to place mother sample tubes along with empty sample tubes into the same carrier and move the carrier to an existing pipettor within the analyzer to aliquot a sample portion of the mother sample into the empty daughter tubes to create aliquots for certain samples without requiring a standalone aliquoting station or substantially disrupting the normal flow of sample tubes within the automation system.

A sample-processing system that improves total system processing efficiency, and reduces a sample-processing time, by establishing a functionally independent relationship between a rack conveyance block with rack supply, conveyance, and recovery functions, and a processing block with sample preprocessing, analysis, and other functions. A buffer unit with random accessibility to multiple racks standing by for processing is combined with each of multiple processing units to form a pair, and the system is constructed to load and unload racks into and from the buffer unit through the rack conveyance block so that one unprocessed rack is loaded into the buffer unit and then upon completion of process steps up to automatic retesting, unloaded from the buffer unit. Functional dependence between any processing unit and a conveyance unit is thus eliminated.

A sample-processing system that improves total system processing efficiency, and reduces a sample-processing time, by establishing a functionally independent relationship between a rack conveyance block with rack supply, conveyance, and recovery functions, and a processing block with sample preprocessing, analysis, and other functions. A buffer unit with random accessibility to multiple racks standing by for processing is combined with each of multiple processing units to form a pair, and the system is constructed to load and unload racks into and from the buffer unit through the rack conveyance block so that one unprocessed rack is loaded into the buffer unit and then upon completion of process steps up to automatic retesting, unloaded from the buffer unit. Functional dependence between any processing unit and a conveyance unit is thus eliminated.

In determining whether a rack inputted to the automatic analyzer by the user is to be transferred to an analysis section or not, samples existing in a route from a buffer to a sample dispensing position in the analysis section are identified, and the number of items in which suction by a nozzle has not been completed in analysis items requested for the samples is managed. When the number of items is reduced to be smaller than a given number, the conveyance of a next rack from the buffer to the analysis section is controlled, thereby limiting the number of analysis items requested for samples in a waiting state for analysis in the analysis section constantly to be smaller than a fixed number. As a result, a period of time until a measurement result of emergency samples is outputted can be reduced even when emergency samples are newly inputted.

Disclosed is a specimen analyzer that uses a specimen rack in which a plurality of specimen containers can be held to analyze a specimen in each of the specimen containers, and the specimen analyzer includes: a measurement unit configured to measure the specimen; and a transport unit comprising a first placement region which is disposed in front of the measurement unit and in which a plurality of the specimen racks can be placed, and a second placement region which is disposed in a left-right direction relative to the first placement region and in which a plurality of the specimen racks can be placed, the transport unit configured to transport the specimen racks placed in the first placement region and the second placement region to a start position at which the measurement unit starts measurement.

This specimen inspection automation system is provided with: a processing unit which processes a specimen; a conveying line which conveys carriers; a control device which controls the conveying of the carriers; and external connection modules which deliver the carriers to and from external devices. The control device controls the number of carriers in the specimen inspection automation system within a fixed range on the basis of the number of carriers conveyed into and out of the system by the external connection modules.

A sample container cap is disclosed. The sample cap container includes a sample cap body capable of covering an opening of a sample container and a centrifugation status indicator device in the top of the sample cap body. The centrifugation status indicator device includes: a first substance having a first density and a first color, and a second substance having a second density and a second color. The centrifugation status indicator device displays the first substance when the sample container has been centrifuged. The first substance can be a gel, and the second substance can include a plurality of particles. The second density is higher than the first density and the second color is different from the first color.