A device for agitating and collecting biological liquid samples comprises an agitator of racks of tubes, a sampling apparatus capable of collecting a biological liquid sample in a tube, and a changer capable of gripping a tube on a rack received in the agitator and moving it to the sampling apparatus. The agitator is capable of agitating at least three racks simultaneously, and the device also comprises a scheduler capable of determining destination data for a tube and destination data for the rack which receives this tube, and of determining for each tube a final location based on the destination data of the tube and the destination data of the racks received in the device, which final location designates a rack, received on the agitator and a position on this rack and can be different from the location of the tube when the rack that received it has been introduced into the device, and arranged to control the changer in order to grip a tube, present it to the sampling apparatus and replace it after sampling at the final location.

The present disclosure relates to the technical field of automated analysis, and provides a sample analysis system and a control method for the same and a sample analysis method. The sample analysis system includes: a control device; a rail device for carrying cuvettes under control of the control device; at least one independent sample distribution node arranged on the rail device for distributing samples to the cuvettes, the independent sample distribution node being used for sample aspiration, transfer, and discharge; and at least two independent reagent distribution and measurement nodes arranged on the rail device for distributing test reagents to the cuvettes and measuring the mixture liquid in the cuvettes, the independent reagent distribution and measurement nodes being used for reagent aspiration, transfer, and discharge and reagent-sample mixture liquid measurement.

A pipetting device (100) for an apparatus (164) for processing a sample or reagent is disclosed. The pipetting device (100) comprises a coupling mechanism (102), wherein the coupling mechanism (102) comprises at least a first coupling unit (104) adapted to be coupled to a first pipetting tip and a second coupling unit (106) adapted to be coupled to a second pipetting tip, and a tilt mechanism (112) for moving the first coupling unit (104) between an untilted position, in which the first coupling unit (104) and the second coupling unit (106) are arranged parallel to one another, and a tilted position, in which the first coupling unit (104) is tilted relative to the second coupling unit (106).

Embodiments are directed to transferring and opening reagent containers for use in a clinical analyzer in an in vitro diagnostics (WD) 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 piece 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.

The present invention provides a disposable ultra-filtration system comprising a disposable pipetting tip and a disposable ultra-filtration cartridge, wherein the cartridge includes a membrane filtration chamber and a dead-end channel. In use, a piston in the pipette pressurizes air within the channel; the pressurized air can subsequently move the piston and cause a reverse flow back through the membrane of the cartridge, unplugging the pores thereof. Also disclosed is an automated workstation incorporating the disposable ultra-filtration system, and a system comprising the automated workstation, useful for measuring the free therapeutic drug concentration and free hormone concentration in a sample.

The disclosure provides a to-be-tested object processing apparatus and a nucleic acid testing integrated machine with the to-be-tested object processing apparatus. The to-be-tested object processing apparatus includes: a frame, provided with a sample processing platform; an extraction mechanism, configured to extract an analyte; a grabbing part, movably arranged above the sample processing platform; a transfer part being movably arranged on the sample processing platform, the transfer part including an extraction plate transfer part, the extraction plate transfer part being provided with a first transfer position, the grabbing part being provided with a first grabbing position and a second grabbing position, and when the extraction plate transfer part is located in the first transfer position, the grabbing part being able to move between the first grabbing position and the second grabbing position; and a pipetting part, movably arranged above the sample processing platform, wherein the extraction plate transfer part is further provided with a sample adding position, and when the extraction plate transfer part is located in the sample adding position, the pipetting part is further provided with a first pipetting position.

According to one embodiment, a liquid dispensing apparatus includes a base to which a liquid discharging device for discharging a liquid is to be mounted, an interface configured to communicate with an external device, a driving circuit to supply driving voltages to an actuator of the liquid discharging device, and a control unit configured to acquire a use history of the liquid discharging device from the external device through the interface, and cause the driving circuit to supply a discharge voltage to the actuator if the acquired use history indicates the liquid discharging device has not been used.

According to one embodiment, a liquid discharging device includes a storage unit storing a use history indicating whether the liquid discharging device has been previously used, and a discharging device mounted on a liquid dispensing apparatus and configured to discharge a liquid when supplied a discharge voltage in response to a discharge signal received from the liquid dispensing apparatus.

A mechanism (10) for an automated Karl Fischer (KF) titration system (1) includes a support console (6), a first vertical guide rail element (11), solidly attached to the support console, and a carriage unit (12), slidably constrained to the first vertical guide rail element, allowing the carriage unit a first degree of linear vertical mobility relative to the support console. The carriage unit holds a vial lift unit (13) with a lift platform (14) for a sample vial (18). The carriage unit, in a downward movement phase, lowers the lift platform from a starting position into an oven cavity of the titration system. A subsequent upward movement phase raises the lift platform to the starting position. A second vertical guide rail element, solidly connected to the lift platform and slidably constrained to the carriage unit, enables a second degree of linear vertical mobility of the lift platform.

The invention provides a high-throughput screening system based on a single manipulator, and belongs to the field of biotechnology and detection equipment. A high-throughput screening system based on single manipulator, comprises of one manipulator which is surrounded by deep well plate loading platform, shallow well plate loading platform, pipetting head loading platform, control cabinet, waste pipetting heads container platform, shallow well plate recycling platform, deep well plate recycling platform, Microplate Reader with oscillating mixer and items-placing platform in a counterclockwise or clockwise order. The present invention is a combination of microbiology and mechanics. It promotes the automation of microbial high-throughput screening system for screening microorganisms with specific properties. It effectively contributes to the development of microbial breeding technology and further promotes the development of microbial science.