This automated analyzer 100 comprises: a sample probe 11a for dispensing a substance to be dispensed into a plurality of reaction vessels 2 for causing a sample to be analyzed to react with a reagent, a measurement unit (light source 4a, spectrophotometer 4, and control device 21) for measuring a reaction liquid produced from the sample and reagent in a reaction vessel 2, a cleaning tank for probe cleaning, and a control device 21 for controlling the operation of the probe, measurement unit, and cleaning tank 13. The cleaning tank 13 comprise a cleaning pool 36 for storing cleaning water for immersing and cleaning the probe and a drying tank 37 for sucking up the cleaning water on the surface of the probe after the probe has been immersed in the cleaning water of the cleaning water pool 36 and cleaned. As a result, it is possible to reduce the amount of cleaning water used to clean the probe.

An automated analyzer includes a rod-like member 12a, a driving portion 12c, and a control mechanism 30. The driving portion 12c lifts and lowers the rod-like member 12a a direction of being inserted into and removed from the container 24. The control mechanism 30 controls the driving portion 12c so that the rod-like member 12a is lifted after being lowered so that a tip portion of the rod-like member 12a reaches a first position in the liquid L, and at a time when the rod-like member 12a reaches a second position where the tip portion is not separated from the liquid, an upward motion of the rod-like member 12a is stopped for a given period of time to reduce liquid film adhering to the rod-like member.

This container storing a washing solution for a blood analyzer includes a container body made of thermoplastic resin resistant against a chlorine-based washing solution and provided with an opening on an upper portion, a chlorine-based washing solution stored in the container body, and a multilayer film covering the opening. The multilayer film includes a seal layer heat-sealed to the container body thereby blocking the opening and a gas barrier layer arranged on the outer side of the seal layer.

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.

Provided is fluid control equipment for bio-reaction, including a pipette configured to transport a reaction solution, and a liquid pump configured to adjust the internal pressure of the pipette.

A method of cleaning an aspiration tube in a specimen measuring apparatus includes: moving the aspiration tube while discharging a cleaning liquid onto an outer side surface of the aspiration tube; stopping the aspiration tube in a state where a tip of the aspiration tube or a droplet attached to the tip contacts a surface of a flow of the cleaning liquid; and moving the stopped aspiration tube in a direction away from the surface of the flow of the cleaning liquid.

A dispenser device includes: a valve system, a dispensing head for dispensing liquid and connected with a transfer tube to the valve system, a dispensing pump connected to the valve system, a first inlet port for conducting rinse liquid to the valve system, and a second inlet port for conducting rinse gas to the valve system. The device includes control equipment for operating the valve system so that the flow via the transfer tube towards the dispensing head includes both the rinse liquid and the rinse gas. The rinse gas is capable of collecting gas bubbles formed on the inner walls of the transfer tube to larger amounts of gas. Thus, the rinse gas facilitates the removal of the gas bubbles with the aid of the rinse liquid.

The present application relates to a method for operating a dosing device with a control unit and a dosing unit. The dosing unit has a cannula with a first volume and a tip, and also a sampling container fluidically connected to the cannula. In a first step, the dosing unit is moved linearly at a predetermined speed in a first direction along an axis, such that the cannula is moved into a vessel containing at least one liquid. At the same time, fluid is aspirated constantly through the cannula with a predetermined volumetric flow by a pump device. At least one optical parameter of the aspirated fluid is measured by at least one optical sensor, which is arranged between the cannula and the sampling container. When a change of the at least one optical parameter is detected, a first position of the dosing unit on the axis is stored by the control unit and the movement of the dosing unit is interrupted. The control unit then calculates a second position of the dosing unit on the axis, at which second position the tip of the cannula has penetrated a first phase boundary, in particular upon immersion into the liquid. The calculation is performed on the basis of the first position, the predetermined speed, the first volume and the predetermined volumetric flow.

The disclosure concerns a method for operating an automated analyzer, including transporting a liquid containing a plurality of particles into a chamber, such as a reactor chamber and/or measuring cell chamber of the analyzer, introducing a gas or gas mixture, for example, air into the chamber, such as through the liquid present in the chamber so that the particles in the liquid are stirred up, and subsequently draining at least part of the liquid from the chamber through a fluid line ending in the chamber and an open valve arranged in the fluid line.

Described herein are systems and methods used for washing needle assemblies with multiple needles.