The invention has an object to provide an automatic analyzer and a control program that can shorten total analysis time. The automatic analyzer comprises: a sample rack that houses a sample; a sample dispensing mechanism that aspirates the sample from the sample rack and dispenses the sample into a reaction container; a plurality of detection units that detect a reaction liquid in the reaction container; and a control unit that controls the sample dispensing mechanism and the detection units. The control unit checks the measurement item specified for the sample and checks one of the detection units that is specified by the measurement item. When measurements specifying the same detection unit among the detection units are specified consecutively, the order of dispensing by the sample dispensing mechanism is changed so that measurements specifying different detection units are made consecutively.

The disclosure relates to a liquid suction device and a sample analyzer, the liquid suction device is configured for sucking liquid in a containing box having a plurality of containing cavities, and the liquid suction device includes a supporting piece; and a plurality of liquid suction mechanisms, each of the liquid suction mechanisms includes a rotating unit, the rotating unit is slidably connected with the supporting piece and includes a rotating shaft, the central axis of the rotating shaft extends in the gravity direction, the liquid suction mechanism can revolve around the rotating shaft, and liquid in the different containing cavities in the containing box can be sucked by the plurality of liquid suction mechanisms at the same time.

A reagent sleeve system such as can be used with various analyzers using chemical phenomena, analyzers and methods of using the reagent sleeve system and analyzer are described. The reagent sleeve system can include a reagent sleeve; and a plurality of removable reagent reservoirs located within the reagent sleeve, wherein each of the plurality of removable reagent reservoirs comprises a respective peripheral wall, and first and second end walls, whereby each of the plurality of removable reagent reservoirs contains a reagent located therein, and the first end wall is pierceable by a reagent extractor, and the reagent sleeve comprises a peripheral wall that encompasses the plurality of removable reagent reservoirs and holds the plurality of reagent reservoirs for sequential use.

An automatic analyzer includes: a plurality of dispensing units; and a plurality of pump units connected to the respective dispensing units. Each of the plurality of pump units includes: a syringe tube that has a liquid port at one end and an opening at another end; a syringe base that is attached to the opening at the other end of the syringe tube; a plunger that penetrates the syringe base and whose tip end is inserted inside the syringe tube; a seal piece that is configured to seal a gap between the plunger and the syringe base; an actuator; and a power transmission mechanism that connects the actuator and the plunger. Each plunger of the plurality of pump units has an individually set diameter and a different thickness. At least one of the syringe base and the syringe tube represents the diameter of the corresponding plunger in appearance.

The invention provides a small-sized automatic analyzer being compact, enabling a large number of analysis items to be carried out, and having a high processing speed. The automatic analyzer is particularly suitably applied to a medical analyzer used for qualitative/quantitative analysis of living body samples, such as urine and blood. A plurality of sample dispensing mechanism s capable of being operated independently of each other are provided to suck a sample from any one of a plurality of sample suction positions and to discharge the sucked sample to any one of a plurality of positions on a reaction disk. The automatic analyzer having a high processing capability can be thus realized without increasing the system size.

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.

A liquid is efficiently suctioned and discharged from and to a container formed by a plurality of aligned storing portions for storing the liquid, using a plurality of nozzles. Provided is a liquid suction/discharge device including a container support device for supporting a culture container formed by a plurality of aligned storing portions, and a nozzle support device for supporting a plurality of nozzles in a state in which distal ends of the nozzles are directed downward. The nozzle support device includes a nozzle support member that swingably supports the plurality of nozzles using prescribed parts as support points, and the liquid suction/discharge device further includes a nozzle inclination device for causing each of the nozzles to be inclined with respect to the nozzle support member.

The present invention is provided with: an automatic analysis device 200 for performing an analysis process to analyze a specimen that is to be analyzed; a specimen pre-processing module 100 for performing pre-processing to cause the specimen to enter a state in which the analysis process can be performed; a main conveyance line 161 for conveying a specimen container carrier 10 which accommodates the specimen that is to be analyzed and in which at least one specimen container can be mounted; and annular conveyance lines 111, 121, 131, 141, 151, 411 that are disposed adjacent to the main conveyance line 161 and that are moreover disposed so as to be capable of transferring the specimen container carrier 10 to and from the main conveyance line 161, the annular conveyance lines 111, 121, 131, 141, 151, 411 being capable of circulating and conveying the specimen container carrier 10 separately without the use of another conveyance line (e.g., a return line 162). This makes it possible to maintain flexibility in conveyance of specimens while suppressing increases in device surface area.

A cell picking device for sucking cells from a liquid sample in a sample container includes a sucking member to which a pipette tip is attachable, a driver that moves the sucking member and performs suction through the sucking member and the pipette tip, a work mode switcher that switches a work mode of the driver between a first mode and a second mode, and a controller that controls the driver.

Systems and methods are described for integrated sample container cover removal and sample probe positioning. In an example implementation, an autosampler system includes, but is not limited to, a z-axis support rotatable about a z-axis of an autosampler deck; a sample probe support structure coupled to the z-axis support, the sample probe support structure configured to hold a sample probe to withdraw a fluid-containing sample held within a sample container supported by the autosampler deck; and a sample cap remover coupled to the z-axis support in an orientation that is rotationally offset from the z-axis support with respect to the sample probe support structure, the sample cap remover configured to lift a cap from the sample container to provide access to an interior of the sample container by the sample probe supported by the sample probe support structure.