A method for aspirating a first liquid medium of two liquid media of different density from a sample container comprises: lowering a pipette of the laboratory automation device into the sample container until a pipette tip of the pipette has passed a lowering distance from the surface of the first liquid medium in the sample container, wherein the lowering distance is chosen, such that the pipette tip passes at least an aspiration volume in the sample container; aspirating liquid from the sample container during the lowering of the pipette by generating an underpressure in the pipette, wherein the first liquid medium is aspirated, and after the interface and the pipette tip pass each other, the second liquid medium of the two liquid media is aspirated; measuring a pressure in the pipette during the lowering of the pipette and detecting a position of the interface, when a slope of the pressure changes; when the lowering distance has been passed and no interface is detected, aspirating the aspiration volume from the first liquid medium and dispensing the aspiration volume of the first liquid medium into a further sample container.

The present invention provides devices and systems for use at the point of care. The methods devices of the invention are directed toward automatic detection of analytes in a bodily fluid. The components of the device are modular to allow for flexibility and robustness of use with the disclosed methods for a variety of medical applications.

A microfluidic dispenser can include a processor to receive a user input via a user interface related to limiting dilution (or a limiting dilution assay) to be performed, and calculate a dispense volume of a fluid for the limiting dilution based on the user input. The microfluidic dispenser can also include a dispense cassette including a fluid reservoir, and a microfluidic dispense head to dispense the fluid via a nozzle in accordance with the calculated dispense volume.

The present invention relates to an immunoassay method and an immunoassay device.

According to an aspect of the present invention, provided is an immunoassay device including: a stage capable of accommodating a plurality of cartridges having a plurality of wells; a solution transfer unit including a plurality of tips, which are movable relative to the stage and disposed to correspond to a position of the cartridge so as to suction a solution stored in each of the wells or discharge the suctioned solution from the well; and a control unit controlling the stage and the solution transfer unit to be relatively movable and controlling suction or discharge of a content into/from the plurality of tips.

Provided herein are automated apparatus for the identification of microorganisms in various samples. The disclosure solves existing challenges encountered in identifying and distinguishing various types of microorganisms, including viruses and bacteria in a timely, efficient, and automated manner by sequencing.

A matrix droplet extruder includes a casing; one or a plurality of reagent containers; a plurality of pneumatic connectors on the casing that are each configured to be connected to a pneumatic actuator to provide controlled pneumatic pressure to one or more of said plurality of the pneumatic connectors; a droplet matrix extrusion surface with one or a plurality of printing zones, each printing zone comprising an array of perforations; and a liquid management chip for dispensing one or more reagents from said one or a plurality of reagent containers through the array of perforations of said one or a plurality of printing zones, so as to repeatedly generate a matrix of droplets when applying the pneumatic pressure to said one or more reagents.

Provided herein are apparatuses and systems for mixing liquids and suspensions that include vessels with structures that improve mixing while not contacting liquid delivery components. The apparatuses and systems can include a motor drive that allows speed and directional control of rotation of the vessel. The apparatuses and systems can include one or more magnets for separating magnetic beads in a suspension. Also provided are methods using said apparatuses and systems for mixing and separation processes.

An auto-pipetting apparatus includes a dispensing head with at least one pipetting tip mandrel having an elongated stud body with an insertion end. The at least one pipetting tip mandrel mates with a pipetting tip. A first adjustable seal, disposed on the elongated stud body, and a second adjustable seal, disposed on the elongated stud body, seal the pipetting tip mated to the at least one pipetting tip mandrel. The first adjustable seal defines a snub surface. The snub surface effects a substantially continuous circumferential contact seal with radially impinging contact between the pipetting tip and the at least one pipetting tip mandrel. The second adjustable seal is adjustable between a disengaged position and an engaged position and effects a releasable grip and another substantially continuous circumferential contact seal between the pipetting tip and the at least one pipetting tip mandrel around the pipetting tip.

The invention relates to a multi-channel head (100) of a liquid handling apparatus for aspirating and dispensing a metered amount of liquid, comprising: an array of connectors (130) for picking up an array of disposable tips, whereby a peripheral end of each connector is provided with an elastomeric seal (140); an alignment plate (150) that is moveable in a z-direction and has a plurality of openings through which the connectors (130) extend, a linear displacement mechanism (170b, 175), driven by a motor (180), for moving the alignment plate (150) in z-direction relative to the connectors, and a controller for controlling the motor. The multi-channel head is configured to attach the array of disposable tips in a pick-up action, in which the multi-channel head (100) is lowered relative to the disposable tips so as to insert each connector into an internal passageway of a corresponding disposable tip by an amount sufficient to bring an upper collar of the disposable tips into contact with an underside (150s) of the alignment plate. This insertion deforms the elastomeric seal against the tip internal passageway so as to form a sealing contact therewith. The controller of the multi-channel head (100) is programmed such that once the pick-up action is complete, an alignment action is performed in which the alignment plate (150) is moved relative to connectors (130) by an amount sufficient to close any gap between the underside (150s) of the alignment plate and the upper surface of the tip collars that arises due to e.g. relaxation of the deformed seals (140).

A metering head for a metering machine having a carrier having parallel attachments for picking up pipette tips, wherein each attachment has: a tube having a supporting protrusion at the bottom end, at least one sleeve which surrounds the tube and can be axially shifted on the tube, and at least one elastomer O-ring which surrounds the tube, a pressure plate above the sleeves having a plurality of first holes through which the tubes extend, wherein the pressure plate can be shifted along the tubes from a release position into a clamping position where the sleeves are pressed, at the bottom ends, against the adjacent O-rings, and the O-rings are expanded to clamp pipette tips; and a first shifting apparatus connected to the pressure plate moving the pressure plate between the release position and clamping position.