Systems and methods for refrigerated storage of controls and calibrators utilize a refrigerant storage assembly having an insulated housing and door assembly, thermoelectric coolers, and the refrigerated base assembly having a metal plate thermally coupled to coolers, one or more sensors, and a plurality of receptacles to receive fluid tubes. Refrigerated storage provides a refrigerated environment suitable for multi-day storage of control and calibrator fluids.

An automatic analyzer disclosed herein includes a first calibration curve generator configured to generate a first calibration curve indicating a relationship between a concentration and an absorbance based on a result of an optical measurement of a reaction solution obtained by adding a reagent to a reference sample including a known concentration of an object to be detected; and a corrected calibration curve generator configured to generate, after the first calibration curve is generated, a corrected calibration curve based on a result of an optical measurement of a mixed reaction solution obtained by mixing the reagent and the reference sample or water, or an optical measurement of the reagent, and data relating to the first calibration curve.

A reader for a lateral flow test device includes a tray or drawer, extendable from the reader, which receives the test device. The tray includes a calibration test pattern affixed or printed thereon placed proximate to the test device and in alignment with the axis of the test device. As the tray is closed and the test device is inserted to the reader, the calibration test pattern is first read by an optics unit including a photodiode. The resulting photodiode output provides a calibration curve S that the reader then uses to correct for any non-linear response of the reader's optical or electronic systems, thus insuring that every reader will yield the same readout for a given test cartridge, despite reader-to-reader variations or reader degradation with time. One use of the reader is for detection of SARS-CoV-2 infection.

A computer-implemented method for calibrating a photometer in an in-vitro diagnostics analyzer includes generating a cuvette map of a reaction ring identifying a plurality of cuvette locations. The cuvette map is used to identify a plurality of reference measurement areas between the plurality of cuvette locations. A plurality of reference measurements are acquired in the reference measurement areas using the photometer. The photometer is automatically calibrated based on a comparison of the reference measurements to a predetermined standard setup of the photometer.

An automatic analysis device is provided with: a sample disk for holding a sample container that accommodates a sample; a reagent disk for holding a reagent container that accommodates a reagent; at least two different measuring units that respectively perform different types of analyses; a control part that controls the measuring units; and a display part that displays: a work flow area in which the flow of operation of the two or more measuring units is displayed; and an overview area in which the usable or unusable states of the respective measuring units are displayed, wherein the overview area has a unit necessity-of-use selection part that can select whether using each of the measuring units is necessary, and the control part controls the display part so as to change the display of the work flow area on the basis of the information set in the unit necessity-of-use selection part.

In conventional automatic analyzers, there have been instances where, when a plurality of associated items are analyzed as a set item, there is high variation in the analysis data obtained using the set item, leading to a need for improvement of analysis precision. The present invention comprises performing, in mutual association, a set of preparation steps to carry out until it is time to analyze an unknown sample, the set of preparation steps including a pre-preparation step in which stirring, etc., is performed when an analysis reagent kit is mounted on the analyzer, and a step for correcting a standard curve in which correction samples that correspond to analysis items are used. This makes it possible to perform analysis after the preparation states of a plurality of analysis reagent kits are collected as needed, enabling high-precision analysis of a set item.

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.

Systems and methods for performing simultaneous nucleic acid amplification and detection. The systems and methods comprise methods for managing a plurality of protocols in conjunction with directing a sensor array across each of a plurality of reaction chambers. In certain embodiments, the protocols comprise thermocycling profiles and the methods may introduce offsets and duration extensions into the thermocycling profiles to achieve more efficient detection behavior.

A blood analyzing method includes optically measuring a first calibration sample prepared from a fibrin/fibrinogen degradation product (FDP) measurement reagent and a first calibrator containing D-dimer (DD) and having a first value relating to the ratio of the content of FDP to the content of DD, acquiring first calculation data based on temporal change of optical information of the first calibration measurement sample, performing optical measurement of a second calibration measurement sample prepared from FDP measurement reagent and a second calibrator containing DD and having a second value that is different from the first value, acquiring second calculated data based on a temporal change in optical information of the second calibration measurement sample, and acquiring calibration curve information indicating the relationship between the calculation data and the value relating to the amount of DD.

An analysis system includes: a collection unit configured to collect soluble iron contained in a sample; a reaction unit configured to produce a reaction solution; a detection unit configured to detect an absorbance of the reaction solution; and a supply control unit configured to supply the soluble iron collected in the collection unit and a reagent to the reaction unit.