Provided is an automatic analyzer capable of further reducing carryover between specimens. The automatic analyzer includes a first dispensing unit for dispensing a specimen related to a first analysis item group having a high possibility of carryover, a second dispensing unit for dispensing a specimen related to a second analysis item group having a low possibility of carryover, an input unit for receiving an input of analysis information related to a plurality of analysis items for a specimen, a classification unit for classifying the analysis information into the first analysis item group and the second analysis item group, and a determination unit for determining a dispensing sequence for each specimen for the first analysis item group and determining a dispensing sequence for each analysis item for the second analysis item group.

A pretreatment device for performing pretreatment using a liquid sucked by a probe from an inside of a septum-attached container includes: a container holding unit which has a space for accommodating the septum-attached container and is provided with a hole into which the probe is inserted with respect to a septum of the septum-attached container to be stored; an installation unit in which the container holding unit is detachably installed; and a fixing unit which fixes the container holding unit to the installation unit in a state where the container holding unit is detachably installed in the installation unit, to solve the above-described problem.

This invention relates to an apparatus for conducting immunoassay test. The apparatus includes a groove unit having a groove along a vertical direction configured to hold a rod-shaped portion of a probe along the vertical direction, and a push pin configured to move along a horizontal direction, the push pin being capable of residing at a first position and a second position. A tip of the push pin is capable of pressing the rod-shaped portion of the probe against the groove when the push pin resides at the first position. The distance between the tip of the push pin and the groove is larger than a diameter of the rod-shaped portion of the probe when the push pin resides at the second position.

An automated analysis device has a reaction container constructed on a reaction disc, a reaction tank for immersing the reaction container in water, a water level sensor, a reagent probe that suctions/discharges a reagent to the reaction container, and a controller. In the reagent probe, a water detection unit that detects the presence of water is provided at a prescribed site, the reagent probe being capable of detecting the water level in the reaction tank. The controller detects the water level in the reaction tank in at least three locations (e.g., a first water level confirmation part, a second water level confirmation part, and a third water level confirmation part) by using the water level sensor and the reagent probe, and has a function for confirming the levelness of the reaction tank or an apparatus on which the reaction tank is installed.

Automation of the collection and reinjection of a sample into a large number of containers is made possible without increasing the size of a liquid handler itself. A preparative liquid chromatography system includes a liquid delivery part (2) that feeds a mobile phase, a separation column (14A; 14B) for separating a sample transported by the mobile phase, a plurality of liquid handlers (6-1 to 6-n), each of which independently including a container arrangement portion (18) in which a plurality of containers for containing a sample are disposed, an injecting part (20A) configured to suck a sample from a container disposed in the container arrangement portion (18) and hold it, and to inject the sample into the mobile phase fed by the liquid delivery part (2) by being interposed between the liquid delivery part (2) and the separation column (14A), and a fractionation part (22) configured to collect a sample eluted from the separation column (14A) so that the sample is fractionated to containers disposed in the container arrangement portion (18), an injection switching part (4) configured to selectively interpose one of the injecting parts (20A) of the plurality of liquid handlers (6-1 to 6-n) between the liquid delivery part (2) and the separation column (14A) by switching connection of channels at a position between the liquid delivery part (2) and the separation column (14A), and a fractionation switching part (12) configured to selectively connect one of the fractionation parts (22) of the plurality of liquid handlers (6-1 to 6-n) to a downstream side of the separation column (14A) by switching connection of channels at a position downstream of the separation column (14A).

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.

An optical measurement device is provided. The device includes first and second optical fibers; first and second reaction vessels, and a light guide stage coupled to the first and second optical fibers. The light guide stage is driven to simultaneously optically connect the first and second optical fibers with the first and second reaction vessels. The device includes a measurement device for receiving emissions from the first and second reaction vessels, and a connecting end arranging body that supports the first and second optical fibers along a path. The arranging body is driven along the path between a first position, in which the first optical fiber is optically connected with the measurement device so that light is transmittable from the first reaction vessel, and a second position, in which the second optical fiber is optically connected with the measurement device so that light is transmittable from the second reaction vessel.

Provided herein are a system, kit and methods that allow quick and precise detection, identification and quantification of analytes in liquid samples. The kit may be used in automated and pre-programmed singleplexed and multiplexed detection and quantification of one or more analytes in a liquid samples. The kit may include a chip caddy, consumable assay chips, an electrode assembly, an electrical connector assembly, one or more cables, a voltage supply, a vacuum pump, a vacuum trap, custom-designed manifolds, one or more buffers, reagents and instructions for use.

Manually operated pipettors, widely used in clinical, forensics, pharmaceutical research, hospital and biotech laboratories to transfer small volumes of liquid, may be subject to positional errors, operator use errors and hidden performance degradation. Manual pipette performance cannot be accepted without monitoring and reporting. This invention concerns a computer controlled vision tracking and lighting system working in conjunction with a sensor controlled fluid dispensing device and controller to confirm pipette tip positional locations during aspiration and dispensing operations with automatic monitoring of liquids entering and leaving a pipette apparatus to digitally track a manual pipetting operation with a digital output file of validated liquid transfer results. The invention may also monitor possible error conditions and prevent improper liquid transfers during the manual process.

A pipetting system is disclosed that includes a pipette head including a multichannel air displacement system for aspirating and dispensing liquids, a pipetting system base that includes a linear guide system along which the pipette head may be moved vertically with respect to the pipetting system base, and counterbalance means for counterbalancing at least a portion of a weight of the pipette head.