An automatic analyzing device according to an embodiment of the present disclosure includes a reagent cartridge and processing circuitry. The reagent cartridge includes a storing unit storing therein a reagent, a flow path for dispensing the reagent from the storing unit, and a dispensing mechanism configured to dispense the reagent into a reaction cuvette through the flow path. The processing circuitry is configured to control the dispensing mechanism so as to dispose of the reagent in the flow path.

The purpose of the present invention is to provide a control system which, when a sensor is not built in a motor, saves the power of the sensor and increases the life thereof by on/off-controlling power supply to the sensor before and after the operation of the motor, and also to provide an automatic analysis device. The control system 201 is provided with sensors 309a, 309b, 602, 603 for monitoring the operation of a motor and a control mechanism for controlling the operation of the motor. The control mechanism is provided with: a function of starting power supply to the sensors 309a, 309b, 602, 603 before a first predetermined time from the time when the motor starts the rotating operation; and a function of stopping the power supply to the sensors 309a, 309b, 602, 603 after a second predetermined time from the time when the motor terminates the rotating operation.

An automatic analyzer for making measurements for different analysis processes by a compact mechanism. The apparatus performs inspection for plural different analysis processes and includes: an incubator for holding plural reaction vessels on circumferential positions, first and second dispensing mechanisms each having a dispensing nozzle capable of arc-shaped movement around a rotational axis and vertical movement, in which a first locus of an arc-shaped movement of the dispensing nozzle of the first dispensing mechanism and a second locus of the arc-shaped movement of the dispensing nozzle of the second dispensing mechanism intersect the circumference of the incubator where the reaction vessels are arranged, while the first locus and the second locus do not intersect, the first dispensing mechanism is used in a first inspection having a first reaction period, and the second dispensing mechanism is used in a second inspection having a second reaction period longer than the first reaction period.

Since a detergent is a consumption article, it is desirable that a use amount of the detergent be as small as possible in a limit that the washing effect is not substantially reduced. Provided is an automatic analyzer which includes a syringe pump which is connected to a probe and performs the body aspiration and discharge, a feed pump which feeds washing water for washing the inside of the probe to the probe via the syringe pump and a controller which controls the dispensing mechanism and the syringe pump, in which the controller, in a case of washing the probe by sucking a detergent in the probe a plurality of times, controls the syringe pump so as to discharge the detergent after sucking the detergent and to suck the next detergent without feeding the washing water to the probe by the feed pump.

There is provided an automatic analysis device with a structure in which a measurement unit is less susceptible to disturbance as compared to a device in the related art, and a method of designing the automatic analysis device. A first rotation axis 301 of a reaction disk 1, a second rotation axis 302 of a reagent disk 9, and a measurement unit are arranged on the same straight line 311 when an automatic analysis device 100 is viewed from an upper surface side, the first rotation axis 301 of the reaction disk 1 is arranged between the second rotation axis 302 of the reagent disk 9 and the measurement unit, and the measurement unit is arranged on a front side to be accessed by a user of the automatic analysis device 100.

A system for automated microorganism identification and antibiotic susceptibility testing comprising a reagent cartridge, a reagent stage, a cassette, a cassette, stage, a pipettor assembly, an optical detection system, and a controller is disclosed. The system is designed to dynamically adjust motor idle torque to control heat load and employs a fast focus process for determining the true focus position of an individual microorganism. The system also may quantify the relative abundance of viable microorganisms in a sample using dynamic dilution, and facilitate growth of microorganisms in customized media for rapid, accurate antimicrobial susceptibility testing.

A reagent-bottle lid opening mechanism is disclosed, which has a needle for piercing a lid of a reagent bottle to be delivered to a reagent disk, has an aligning mechanism of automatically adjusting a position of the needle with respect to the lid such that a needle body of the needle can stick in the center of the lid, and accurately and repeatedly makes an incision in the center of the lid. As a result, an automatic analyzer is provided that is capable of unsealing the center of the lid of the reagent bottle with accuracy even if the central axis of the needle and the central axis of the lid are offset from each other.

A pretreating apparatus includes a transferring mechanism configured to transfer a storing container storing an unpretreated sample or a pretreated sample, a pretreating portion having a port in which the storing container storing the sample is installed by the transferring mechanism, configured to pretreat the sample in the storing container installed in the port, and a diluting portion configured to suck a predetermined amount of the pretreated sample from the storing container and supply the sample and a diluent to an empty storing container to dilute the sample.

An object of the present invention is to suppress time and effort into generating a calibration curve while ensuring accuracy of the calibration curve in an analysis step of generating the calibration curve by using two or more standard solutions (two or more concentrations). A calibration curve generation method according to the present invention includes acquiring time course data by irradiating a mixed reaction liquid obtained by mixing one standard solution containing a component to be measured having a concentration other than a zero concentration and a reagent reacting with the component to be measured with light and measuring a turbidity change over time of the mixed reaction liquid, extracting pieces of light amount data in a plurality of different times from a fitting line obtained by complementing discrete portions of the time course data, and generating the calibration curve indicating a relationship between the plurality of pieces of light amount data and a plurality of concentrations by converting the plurality of different times into the plurality of concentrations of the component to be measured (FIG. 1).

The disclosure provides cartridges that are pre-loaded with reagents for performing antimicrobial susceptibility testing (AST) and FISH testing. Cartridges of the disclosure include various incubation wells loaded with different antimicrobial agents for differential growth analysis. Imaging wells with species-specific microbial probes, fluorescent tags, magnetic particles and dye-cushion layers allow for tagging and imaging of target microbes for differential growth analysis.