In an automatic analyzer including a plurality of analysis modules that are analyzable of different items in which the plurality of analysis modules are connected to each other with a transport module, there is provided an automatic analyzer that improves transport efficiency more than that of a conventional one and that can shorten time to completion of analysis. In a plurality of analysis modules, two or more analysis modules that analyze different analysis types form one group. A control module sets a transport destination after a sample dispensing process is completed the two or more analysis modules to the two or more analysis modules as transport destinations when the two or more analysis modules that are analyzable of an unmeasured analysis item in the one group, and the control module gives priority to the two or more analysis modules over another analysis module.

A sample analysis system includes a first measurement unit, a second measurement unit arranged to a downstream side of the first measurement unit, and an information processing section which obtains a measurement result of a sample. The information processing section determines, based on the measurement result of the sample measured by the first measurement unit, whether or not a retest of the sample by the first measurement unit is necessary. When the retest by the first measurement unit is necessary, the information processing section causes the sample container to be transported to a first sample supply position for the first measurement unit and causes the first measurement unit to perform measurement of the sample.

The present disclosure relates to systems and methods for facing a tissue block. In some embodiments, a method is provided for facing a tissue block that includes imaging a tissue block to generate imaging data of the tissue block, the tissue block comprising a tissue sample embedded in an embedding material, estimating, based on the imaging data, a depth profile of the tissue block, wherein the depth profile comprises a thickness of the embedding material to be removed to expose the tissue sample to a pre-determined criteria, and removing the thickness of the embedding material to expose the tissue to the pre-determined criteria.

A medical testing machine provides improved recall and display of the outcomes of tests performed by the machine. Test outcomes and other information are stored in mass storage directly accessible by the medical testing machine. In one aspect, outcomes of tests relating to a particular patient may be recalled. The system may be especially useful for tests that may be performed multiple times for a particular patient over a period of time, for example testing for HbA1c hemoglobin levels in diabetes patients. According to another aspect, the medical testing machine may store an accession number for each test outcome, and may enable a user to display as a group test outcomes having the same accession number. The system may store further information and associate it with particular test outcomes, for example calibration information. The system may also store a set of rules under which each test instance was run.

A sample analysis system includes one or more sets. Each of the one or more sets include includes a measurement block including measurement units configured to test a sample contained in a sample container, and a transport unit disposed corresponding to the measurement block. The transport unit includes a first transport path along which a sample rack is transported from an upstream side to a downstream side and a second transport path along which the sample rack received from the first transport path is transported to the measurement units in the measurement block. The second transport path is configured to move the sample rack back and forth between the measurement units to distribute the sample containers held on the sample rack to the measurement units.

The present disclosure relates to systems and methods for tracking and printing within a histology system. In some embodiments, a system is provided that includes an information reader configured to read identifying data associated with a tissue block, a microtome configured to cut one or more tissue sections from the tissue block, one or more slides for receiving the one or more tissue sections, and a printer configured to receive the identifying data and print, after the one or more tissue sections are cut from the tissue block, one or more labels for the one or more slides, the one or more labels comprising information associating the one more tissue sections on the one or more slides with the tissue block.

Systems and methods enable fully automated tissue processing using tissue processing components for producing tissue sections from a tissue sample block and to transfer the tissue sections to slides. A control device queries a Laboratory Information Management System (LIMS) with a sample identifier associated with the tissue sample block and receives tissue sample data from the LIMS. The control device generates tissue processing workflow parameters based on the tissue sample data for each tissue processing component to perform an automated tissue processing workflow. The control device automatically controls each tissue processing component according to the tissue processing workflow parameters to process the tissue sample block. The control device generates a block processing update message while the tissue sample block is processed and communicates the block processing update message to the LIMS to enable the LIMS to track the automated tissue processing workflow for the tissue sample block.

A sample rack transport apparatus for transporting a sample rack to a sample analyser, comprising: a bidirectional transmission track for bidirectionally transmitting a sample rack without passing through the sample analyser; a feed channel in parallel with the bidirectional transmission track, wherein the sample rack may be delivered from the bidirectional transmission track to the feed channel and to the sample analyser; an unloading cache region located between the bidirectional transmission track and the feed channel, the unloading cache region being used for storing the sample tack; and an unloading mechanism for delivering the sample rack in the feed channel to the unloading cache region for storage, or delivering the sample rack stored in the unloading cache region to the bidirectional transmission track. Also provided are a sample analysis device and a sample analysis system using the sample rack transport apparatus.

A sample analyzer comprising: a sample preparing section for preparing first and second measurement sample including reagent and sample; a first detector for detecting a predetermined component in the first measurement sample prepared by the sample preparing section; a second detector for detecting the predetermined component in the second measurement sample prepared by the sample preparing section; and a controller configured for performing operations, comprising: (a) controlling the first detector to detect the predetermined component in the first measurement sample prepared by the sample preparing section; (b) determining the reliability of the result detected by the first detector; (c) controlling the sample preparing section to prepare the second measurement sample from the same sample when the result has been determined to be unreliable; and (d) controlling the second detector to detect the predetermined component in the second measurement sample, is disclosed.

An automated analyzer includes two or more types of photometers to obtain suitable output of the measurement results of the plurality of photometers and suitable data alarm output even if there is an abnormality, or the like, at the time of measurement. The automated analyzer includes, for example, two types of photometers having different quantitative ranges and an analysis control unit for controlling analysis that includes measurement of a given sample using the two types of photometers. If two types of data alarms corresponding to abnormalities, or the like, during measurement have been added to the two types of measurement results from the two types of photometers, the analysis control unit selects measurement result and data alarm output corresponding to the combination of the two types of data alarms and outputs the same to a user as analysis results.