An analysis device for particle analysis, configured in such a manner that a reagent container is set in the device by inserting the reagent container from a side surface of the device toward the inside thereof, the reagent container having, near the forward end thereof, a suction pipe entrance portion into which a suction pipe can enter. The analysis device is provided with: a reagent container holding portion which holds the reagent container inserted from the suction pipe entrance portion side; and the suction pipe which enters, from above, the suction pipe entrance portion of the reagent container held by the reagent container holding portion and which sucks a reagent within the reagent container. The reagent container holding portion includes a guide member for guiding the insertion of the reagent container, which is inserted from the suction pipe entrance portion side, into the reagent container holding portion.

A display unit displays, on a single screen, a first display area configured from a first area corresponding to the position on a reagent disc at which a reagent container is disposed and a second display area configured from a second area corresponding to the position on a reagent loader at which a reagent container is disposed. A control unit changes the display state of the first area on the basis of whether a reagent container is placed at a position on the reagent disk corresponding to the first area and reagent information for the reagent accommodated in the placed reagent container and changes the display state of the second area on the basis of whether a reagent container is placed at a position on the reagent loader corresponding to the second area and reagent-container-conveyance-state information for the placed reagent container.

In an automated analyzing apparatus, problems arise when a reagent container is carried in during analysis, since it is necessary to stop all accesses of mechanisms etc. to a location of the apparatus where the reagent container is placed and, in a situation in which measurements have been already started, it is impossible to carry the reagent container after waiting about several minutes. To address the problems, when a remaining amount of a reagent corresponding to a predetermined item becomes equal to or less than a first threshold value, a pause cycle of reagent suction is generated in which the reagent dispensing mechanism does not suction the reagent from inside of a reagent container of a reagent disc at regular intervals, and a reagent container containing the same kind of reagent in the reagent disc by the reagent container carrying mechanism is automatically carried in the pause cycle.

The present disclosure provides methods for the automated control of aspects of slide preparation in an automated slide preparation instrument. Aspects of the methods include automated assessments of reagent amounts, quality and performance as well as automated adjustments of reagents based on such assessments, including the adjustment of reagent amounts, e.g., as present in reagent baths, the adjustment of reagent compositions and the replacement of reagents. Devices and systems useful in performing the described methods are also provided herein.

An automatic analyzer that allows appropriate setting of analytical parameters which incorporate batch-to-batch variations in reagents. The analytical parameters consist of fixed parameters and variable parameters. The fixed parameters include a reagent-dispensing quantity, a sample-dispensing quantity, measuring wavelength, and the like, each of which becomes a pivot for measurement of a sample, and parameters to be used are selected from an item code and bottle code assigned to a reagent bottle. The variable parameters include a linearity check value, a prozone check value, reaction limit absorbance, technical limits, first standard solution absorbance, variation allowable absorbance, and the like, each of which is associated with sample-measurement result checks. The automatic analyzer reads bar code information from the reagent bottle and adopts variable parameters of a corresponding version with the item code, the bottle code, and batch information relating to the reagent, as a key.

The present invention provides an automatic analyzer capable of reducing the time necessary for analysis processing by making various operations pertaining to the analysis processing more efficient. More specifically, the present invention is characterized in that, from among a plurality of ending operation items set as analysis ending operations to perform at the end of analysis operations for analyzing a sample under analysis, one or more ending operation items to be performed are selected, and on the basis of monitoring results of monitoring the status of an automatic analyzer during the period from the end of the analysis ending operations to the start of analysis preparation operations for preparing for the analysis operations, one or more preparation operation items to be performed are selected from among a plurality of preparation operation items set as analysis preparation operations.

One aspect relates to a method of calibrating event data. The method includes obtaining, via an electronic device including a processor, event data for an assay including a reagent. The reagent is associated with one of a plurality of manufacturing lots of the reagent. The method includes receiving one or more calibration factors for the reagent based on an identifier associated with the one of the plurality of manufacturing lots. The method further includes generating calibrated event data based on an application of the one or more calibration factors to the event data.

A computer-implemented method of automatically managing calibration of an in-vitro diagnostic system is provided comprising determining a lot calibration time period in which a lot calibration is applicable to reagent containers of the same lot, having a predefined time length starting from the time when the lot calibration becomes available, upon making a reagent container of the lot available to the system, determining whether a lot calibration that has not exceeded the lot calibration time period is available and linking the reagent container to the available lot calibration or most recent available lot calibration if more than one lot calibration is available, wherein if a new lot calibration for the same lot becomes available the method comprises replacing the existing link to the previous lot calibration with a link to the new lot calibration.

An automatic authentication method includes an identification code reading step of reading an identification code assigned to an article from an apparatus side. The method includes a password part generation reproduction step of reproducing a procedure for generating a second password part according to a predetermined random character creation rule based on characters included in an identification information part and a first password part of the read identification code. The method includes a password collation step of collating the second password part generated by the reproduction with a second password part of the identification code of the article read by the identification code reading step. The method includes authentication steps of authenticating the article as a genuine product when the collated second password parts match each other.

An automatic analyzer which realizes stable reagent heating and high dispensing accuracy includes a thermostat bath for controlling a reagent or a reaction solution in reaction cells arranged on a circumference of a reaction disk to have a constant temperature; a first reagent dispensing mechanism dispenses a reagent into the reaction cells; a photometer detects transmitted light or scattered light in the reaction cell; and a disposable reaction container for allowing the sample and the reagent to mix and react with each other. The analyzer also includes a second reagent dispensing mechanism with a reagent heating function which dispenses the reagent into the disposable reaction container; a coagulation time detection section; a reaction container temperature control block; a reagent dispensing syringe which is connected to the second reagent dispensing mechanism; and a fluid temperature control mechanism which controls the temperature of an internal fluid of the reagent dispensing syringe.