Disclosed is a station, for testing an analyte in a sample, enabling accurate and quick reaction and analysis of the sample and a reagent in one apparatus. To this end, the present disclosure provides a station, which is for testing a sample by means of inserting a cuvette, having a standby chamber on which a collecting member is placed, a sample chamber, a reagent chamber and a detection unit. The station comprises: a housing which has an input/output part into which a cuvette is inserted; a driving unit which is provided inside the housing, horizontally moves the cuvette, vertically moves a collecting member, reacts a sample in a sample chamber and a reagent in a reagent chamber, and injects a reaction result thereof into a detection unit; and an optical reader which is provided on the horizontal movement path of the cuvette and is for analyzing the reaction result.

A sample plate comprising a sample well is disclosed. The sample well can comprise one or more bead retaining chambers. Also provided herein is a method of using the sample plate and kits comprising the sample plate.

A sample analyzer, comprising a sample storage region, a sample-drawing channel, and a transport mechanism; the sample storage region being provided with a plurality of storage channels; the sample-drawing channel is provided with a sample-drawing position; the transport mechanism comprises an engagement slot, an actuation mechanism and a first moving mechanism; the engagement slot and the actuation mechanism are fixed on the first moving mechanism, the actuation mechanism comprises an actuator and a second moving mechanism, the actuator is drivable by at least one of the first moving mechanism and the second moving mechanism to realize the movement of the sample holder between the storage channels and the engagement slot; during sample drawing, the first moving mechanism drives the engagement slot to move to the sample-drawing channel, the actuation mechanism enables samples to pass through the sample-drawing position and to make a stop for sample drawing.

An autosampler includes: a sample cooling unit that is brought into thermally contact with a bottom surface of a sample rack so as to cool a sample accommodated in the sample rack; a condensed water receiver that has at least one hole on a bottom surface thereof, and is provided below the sample rack for receiving water condensed around the sample rack; a discharging passage configured in such a manner that a droplet falling from the at least one hole flows therein.

A sample plate comprising a sample well is disclosed. The sample well can comprise one or more bead retaining chambers. Also provided herein is a method of using the sample plate and kits comprising the sample plate.

The invention relates to a sample processing system and method for processing biological samples, comprising a sample processing device having: a receiving plate, which is arranged substantially horizontally in a plane; a first and second working arm, which can move relative to the receiving plate and extend substantially parallel to each other in a second direction (Y) over the receiving plate; at least one pipetting device mounted on the first working arm, which is movable in the second direction (Y) and in a third direction (Z) orthogonal in relation to the first and second direction (X, Y); at least one gripping device, mounted on the second working arm, with grippers that can be rotated around a gripper axis of rotation (GA) parallel to the third direction (Z); and a control device for controlling the pipetting device and the gripping device.

A pipette-tip connecting device has a base, a first positioning mechanism, a second positioning mechanism, a connecting seat, a pipette-fixing seat, and a tilt actuator. The first positioning mechanism extends along a first direction. The second positioning mechanism is linked to the first slider and extending upward and downward along a second direction. The connecting seat is mounted on the second slider such that positions of the connecting seat along the first direction and the second direction are controlled by the first positioning mechanism and the second positioning mechanism respectively. The pipette-fixing seat is mounted on the connecting seat and is pivotal relative to the connecting seat. The pipette-fixing seat has a pipette-tip connector which moves in the first direction and the second direction when the pipette-fixing seat pivots. The tilt actuator controls a relative angle between the pipette-fixing seat and the connecting seat.

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.

A pipetting device (100) for an apparatus for processing a sample or reagent is disclosed. The pipetting device (100) comprises a coupling mechanism, wherein the coupling mechanism comprises at least a first coupling unit (104) adapted to be coupled to a first pipetting tip (108) and a second coupling unit (106) adapted to be coupled to a second pipetting tip (110), and a selection element (138) for selectively allowing a coupling of the first coupling unit (104) to or releasing the first coupling unit (104) from the first pipetting tip (108) and for selectively allowing a coupling of the second coupling unit to or releasing the second coupling unit (106) from the second pipetting tip (110). The selection element (138) is mechanically coupled to the first coupling unit (104) and the second coupling unit (106). Further, an apparatus (198) for processing a sample or reagent and a method for pipetting a sample or reagent are disclosed.

The invention relates to a method and apparatus for measuring the optical state on the inside of a reaction vessel. The apparatus includes: linking portions that optically connect with the interior of the reaction vessel that is linkable with reaction vessels, a connecting end arranging body having an arranging surface that arranges and supports along a predetermined path, connecting ends to which is provided back ends of the light guide portions, the front ends thereof being provided to the linking portions, the connecting ends being provided to the linking portions; a measurement device having measuring ends that are successively optically connectable with the connecting ends, and in which light based on the optical state is receivable by optical connections between the connecting ends and the measuring ends; and a light guide switching mechanism that successively optically connects the connecting ends and the measuring ends.