A device for separating a reagent from a reactor includes a collecting means, provided with a liquid receiving port and a solid receiving port, a holding component disposed above the collecting means and used for placing the reactor, and a rotating mechanism for driving the holding component to rotate. The liquid receiving port and the solid receiving port are arranged at different positions in the circumferential direction of rotation of the holding component, when the holding component passes over the liquid receiving port, reagent in the reactor falls into the liquid receiving port, when the rotating mechanism continues rotating in the original direction until the holding component passes over the solid receiving port, the reactor falls into the solid receiving port from the holding component.

One aspect of the present invention provides a nucleic acid extraction device. The nucleic acid extraction device includes a container which stores each of a cleaning solution and an eluting solution, a water level sensor configured to detect amounts of the cleaning solution and the eluting solution which are stored in the container, a tube sensor configured to sense a sample tube disposed on a sample tube accommodation portion, and an operation initiation portion configured to determine whether the cleaning solution and the eluting solution which are necessary for a nucleic acid extraction operation are provided on the basis of the number of such sample tubes which is sensed by the tube sensor and the amounts of the cleaning solution and the eluting solution which are sensed by the water level sensor.

A highly integrated, fully automatic chemiluminescence detection equipment and its operation method are disclosed. The chemiluminescence detection equipment comprises a control module, a first electrical machine, a reagent wheel disc tank, a sampling module, a washing module, a second electrical machine and a detection module. Compared with the traditional large-scale chemiluminescence detection equipment, the chemiluminescence detection equipment of the present invention has the advantage of high integration, and greatly reduces the overall volume and weight of the chemiluminescence detection equipment.

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 solution jetting device includes: a cylindrical member; a movable member that is movably fitted to a hollow portion of the cylindrical member; a first drive mechanism that moves the movable member; a first flow passage that connects a solution container, in which a solution containing a biological sample or containing a reagent to be reacted with a biological sample is contained, to the hollow portion; an openable and closable first on-off valve that is provided on the first flow passage; a jetting tool that jets the solution to an objective region; a second flow passage that connects the hollow portion to the jetting tool; an openable and closable second on-off valve that is provided on the second flow passage; a second drive mechanism as defined herein; and a control unit as defined herein.

A pretreatment apparatus (100) for performing pretreatment of a sample is provided with a holder (610) for holding a container (10) containing a sample, a centrifugal separation device (600) for rotating the container (10) held by the holder (610) to perform a centrifugal separation, a temperature adjustment device (420) for adjusting the temperature of the sample in the container (10) in the holder (610), an input device (320) for receiving from a user a designated temperature that is adjusted by the temperature adjustment device (420), a controller (300) for controlling the temperature adjustment device (420) in accordance with the designated temperature received via the input device (320).

Provided is an automatic analysis device that can suppress concentration of a reagent made to react with a specimen. This automatic analysis device is provided with: a reagent container which accommodates a reagent and which has attached thereto a perforable lid; a perforation unit for perforating the lid; and a reagent suction nozzle that is inserted into a hole formed by perforation and that sucks up the reagent. The automatic analysis device is characterized by being further provided with a state storage unit that stores the state as to whether the reagent container is in an unused state or in a used state, and a state update unit that, when the lid is perforated by the perforation unit while the reagent container is in an unused state, updates the state stored in the state storage unit to the used state.

Disclosed herein is an apparatus for facilitating chemical analysis based on color principle. Accordingly, the apparatus may include a base located at the bottom of the apparatus. Further, the base may be composed of a rectilinear receptacle. Further, the apparatus may include an intermediate plate located above the base. Further, the apparatus may include a hood located atop the intermediate plate. Further, the hood may include a hood rectilinear receptacle. Further, the hood rectilinear receptacle may be secured to the intermediate plate using a fastening mechanism. Further, the apparatus may include a roundtable housed within the hood. Further, the apparatus may include a motion system passing through and engaging with the roundtable and the hood. Further, the apparatus may include an analysis system embedded into at least one board suspended within the base. Further, the analysis system facilitates automated chemical analysis of a plurality of extraneous vials.

An automated analysis device includes a reagent disc on which a plurality of reagent containers are loaded; a reagent loader that loads a reagent from the outside onto the reagent disc and carries a reagent to the outside; a display unit that displays the reagents in the plurality of reagent containers, so as to be paired with corresponding analysis items for which the reagents are used; and a control unit that causes the reagent loader to simultaneously carry, to the outside of the reagent disc, a reagent which is selected, on the display unit, by an operation device used for an operation input from an operator instructing the reagent loader to take out the reagent and simultaneously carry a reagent which is to be used for a different analysis item to be performed simultaneously with the analysis item for the selected reagent.

The automatic analyzer includes: a member to be washed, such as a probe or a stirrer for contacting and stirring a liquid; a wash station in which the member to be washed is washed with a washing liquid; and a measuring part that measures an optical characteristic of an evaluation reagent contained in a reaction cell. A control unit brings the member to be washed that has been washed in the wash station into contact with the evaluation reagent, causes the measuring part to measure the optical characteristic after contact with the evaluation reagent, and calculates the amount of the washing liquid carried into the reaction cell by the member to be washed, based on the measured optical characteristic.