The automatic analyzer includes a suction nozzle; a liquid transfer syringe; a suction channel which connects the suction nozzle and the liquid transfer syringe; a flow cell which is arranged in the middle of the suction channel; a detector for sample analysis which is arranged in the flow cell; a reaction auxiliary liquid vessel and a cleaning liquid vessel which store liquids to be sucked in by the suction nozzle; means for supplying a diluting fluid to the vessels; a cleaning tank for dumping liquid remaining in the vessels; and a controller for supplying the diluting fluid to the vessels when the remaining liquid is discharged from the vessels and thereafter having the diluted remaining liquid sucked into the flow cell via the suction nozzle and having the sucked remaining liquid discharged to the cleaning tank.

A multi-well fluid container that includes a container body is provided for use in an in vitro diagnostics automation system. The container body includes a first well having a first well size configured to hold a first fluid and an openable first well closure that covers a first well opening. The first well opening provides access to the first fluid in the first well when the openable first well closure is opened. The container body also includes a second well having a second well size configured to hold a second fluid and having an openable second well closure that covers a second well opening. The second well opening provides access to the second fluid in the second well when the openable second well closure is opened. The first well size of the first well is different than the second well size of the second well.

The present invention provides a processing device with a high degree of flexibility in setting of preprocessing and which is capable of increasing the preprocessing efficiency, and an analysis system provided with the same. Setting receiving means (84d) receives, for each sample, setting of a plurality of types of preprocessing and a parameter for each preprocessing. A preprocessing execution section (84e) controls a plurality of preprocessing sections and a transport arm (24) so that a plurality of types of preprocessing set for each of different samples is performed simultaneously in parallel. The preprocessing execution section (84e) performs control in such a way that preprocessing is not to be performed on different samples at the same preprocessing section at the same.

To minimize cross talk in systems and methods for detecting two or more different optical signals emitted from each of a plurality of reaction receptacles, an excitation signal associated with each of the optical signals has a known excitation frequency, and any detected signal having a frequency that is inconsistent with the excitation frequency is discarded. The receptacles are moved relative to optical sensors configured to detect each unique optical signal from an associated receptacle, and to further minimize cross talk, the optical sensors are arranged so that only one reaction receptacle at a time is in a signal detecting position with respect to one of its associated optical sensors, and the optical sensors are grouped by the optical signal they are configured to detect so that a first optical signal is detected from each of the reaction receptacles before a second optical signal is detected from the reaction receptacles.

To clean a reagent probe 7a, 8a or a sample probe 11a, 12a with a heated cleaning solution, after a first cleaning solution is caused to overflow from a first cleaning container 23 or a second cleaning container 24, the first cleaning solution is temporarily drawn back into the cleaning-solution heating passage 125 to be heated by the heating mechanism 123. After the heating, the first cleaning solution thus heated is re-supplied to the first cleaning container 23 or the second cleaning container 24. As a result, the cleaning solution heated to clean a dispensing probe can be supplied to a cleaning bath with efficiency.

Provided is an automated analysis device with which sufficient reaction process data can be acquired irrespective of the scale of the device, and with which it is possible to ensure freedom of the device configuration. An automated analysis device 100 is provided with: a reaction disk 1 which circumferentially accommodates a plurality of reaction vessels 2; a specimen dispensing mechanism 11 which dispenses a specimen into the reaction vessels 2; a reagent dispensing mechanism 7 which dispenses a reagent into the reaction vessels 2; a measuring unit 4 which measures a reaction process of a mixture of the specimen and the reagent in the reaction vessels 2; and a cleaning mechanism 3 which cleans the reaction vessels 2 after measurement. Further, the automated analysis device 100 includes a controller 21 which controls the drive of the reaction disk 1 such that in one cycle the reaction vessels 2 move by an amount A in the circumferential direction in such a way that N and A are mutually prime, B and C are mutually prime, and the relationship A×B=N×C±1 holds, where N is the total number of reaction vessels 2 accommodated in the reaction disk 1, the reaction disk 1 moves through C (where C>1) rotations+an amount equivalent to one reaction vessel after B (where B>2) cycles, and the number of reaction vessels 2 moved in one cycle is A (where N>A>N/B+1).

This disclosure provides automatic analyzers and reagent wheels thereof. The reagent wheel can have one or more rings of reagent bottle seats that may be used for placing a reagent container and distributed along a circumferential direction. An included angle may be formed between a symmetrical centerline of the reagent container placed on the reagent bottle seat and a radius of a circle where the reagent wheel is located, where the included angle is not equal to zero. Compared with the situation in which the symmetrical centerline of the reagent container overlaps with the radius of the circle where the reagent wheel is located, an improved balance can be achieved between the capacity and the diametric size of the reagent wheel, thus making an improvement in meeting application requirements of the analyzers.

Provided is an automatic analyzer with improved analysis accuracy and analysis processing capacity per unit space. The automatic analyzer includes a reagent container with an opening on an upper side, a first arm that rotates centering around a first shaft, a tip of the first arm accessing to the upper side of the reagent container, and a second arm that rotates centering around a second shaft, a tip of the second arm accessing to the upper side of the reagent container. A recess is formed on a side that is closer to the tip of the first arm than the first shaft and that faces the second arm.

A reagent filling device and a sample analyzer with the reagent filling device. The reagent filling device includes a base, a horizontal rotation component, a vertical lifting component and a cantilever component, wherein, the horizontal rotation component is connected with the base, the vertical lifting component moves in a vertical direction relative to the base, the vertical lifting component drives the cantilever component to move along the vertical direction, the cantilever component is rotatably arranged relative to the vertical lifting component, there are a plurality of cantilever components, the cantilever component includes a cantilever body, a length of the cantilever body of at least one cantilever component is greater than a length of the cantilever body of each of the rest cantilever components, and the cantilever component is configured to add a reagent in a reagent disc to a reaction cup in a reaction disc.

Embodiments are directed to transferring and opening reagent containers for use in a clinical analyzer in an in vitro diagnostics (IVD) environment. Contents of a reagent container may be automatically recorded, and the container is positioned and opened, making available its contents to a transfer probe. A set of mechanical fingers open and close relative to one another, to release and grip the reagent container on opposite sides thereof for transferring the container. Once the container is positioned, the mechanical fingers raise and are positioned above a seal concealing the contents of the reagent container. The fingers are configured to close together and travel in a downward trajectory to pierce the seal. The reagent container is originally presented as an un-opened package to prevent spillage and to control reagent life expectancy. According to an embodiment, a method of performing a cycle unload, transfer, and load, without operator intervention, is provided.