In an embodiment, an immunochemistry analysing system includes a source of paramagnetic particles, a source of fluid, a cuvette configured to receive the paramagnetic particles and the fluid, a pipette configured to (i) translate so that at least a portion of the pipette is located within the cuvette and (ii) dispense at least one of the paramagnetic particles and the fluid into the cuvette so that the paramagnetic particles and the fluid can be mixed within the cuvette, a motor configured to move the pipette while located in the cuvette, and a control unit configured to vary a motor drive of the motor to cause the pipette to mix the fluid with the paramagnetic particles within the cuvette.

A fluid delivery device includes at least one area onto which at least one support element having at least one well may be placed in a defined position. The fluid delivery device further includes at least one pipetting device having a connector configured to releasably connect the at least one pipetting device with a disposable tip and with a fluid displacement element which enables aspiration and ejection of a defined volume of liquid to or from the disposable tip. The at least one pipetting element is movable in a vertical and preferably in at least one horizontal direction. The fluid delivery device also includes a blowing element that has at least one aperture coupled to a source of pressurized gas and is movable in a vertical and preferably at least one horizontal direction. A system includes such a fluid delivery device and the at least one support element.

A dispensing apparatus, a liquid dispensing method, and a cell dispensing method which can dispense liquid with very high accuracy. A dispensing apparatus includes a glass pipette, a tubular elastic member, a rod-shaped member, and a piezoelectric element actuator. A portion of the tubular elastic member located adjacent to a first open end thereof covers a portion of the glass pipette located adjacent to an opening portion thereof. A portion of the tubular elastic member located adjacent to a second open end thereof covers at least a forward end portion of the rod-shaped member. When the piezoelectric element actuator pushes the rod-shaped member toward the opening portion of the glass pipette, the tubular elastic member deforms such that the volume of the internal space of the tubular elastic member decreases.

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 method for setting a cell concentration and/or a particle concentration in a dispensing device that has a fluid chamber into which a liquid sample is introduced that has a liquid and cells and/or particles, wherein the cell concentration and/or the particle concentration is determined, in particular in one region of the dispensing device, and the cell concentration and/or particle concentration that has been determined is compared with a target value and the cells and/or particles, in particular one or the other, that are present in the fluid chamber are moved or not moved as a function of the result of the comparison.

A liquid-metering device for discharging metered liquid in the nanometer range, includes a pipetting-tip receiving device defining, at least in a metering-ready operating position of the liquid-metering device, a receiving space that runs along a virtual receiving axis and is designed to receive a portion of a pipetting-tip. The liquid-metering device also includes a triggering plunger moveable relative to the pipetting-tip receiving device, between a standby position and a triggering position. The liquid-metering device also includes movement drive, which is coupled to the triggering plunger so as to transmit motion, and a control device for controlling operation of the movement drive. A first and second deformation formation define therebetween an axial longitudinal region of the receiving space as a deformation region, in which region the first and second formations can be brought closer or farther away to/from one another. The triggering plunger is located in the deformation region.

A pipette controller for aspirating and dispensing multiple aliquots of a fluid from a reservoir of fluid. The pipette controller can include a pipette holder adapted to operatively connect a pipette to the pipette holder; a pump having a vacuum port and a pressure port, the pump pneumatically connected to the pipette holder; an aspirate valve that controls airflow between the vacuum port and the pipette holder; a dispense valve that controls airflow between the pressure port and the pipette holder; a piston chamber; an aliquot dispense pump including a piston having a shaft that extends into the piston chamber, the shaft defining a stroke length; and an aliquot check valve that connects the pipette holder and the aliquot dispense pump; wherein the aliquot valve opens to allow airflow into the pipette holder upon engagement of the aliquot dispense valve. The pipette controller can also include a piston pump pneumatically connected to the pipette holder configured to deliver a bolus of air to the pipette holder.

A biological sample processing apparatus, including: a pipette block with which a plurality of pipettes for sucking or discharging a biological sample in a multi-well plate in which wells are arranged in a matrix shape along row and column directions are detachably coupled; a pipette block forward and backward transfer unit configured to move the pipette block along a forward and backward direction along a process direction; a pipette block top and bottom transfer unit configured to move the pipette block along a vertical direction; a magnetic field applying unit disposed below the multi-well plate for applying a magnetic field to a well of the multi-well plate; and a heating unit disposed below the multi-well plate so as to be spaced apart from the magnetic field applying unit, for heating a well of the multi-well plate.

In an embodiment, an immunochemistry analysing system includes a source of paramagnetic particles, a source of fluid, a cuvette configured to receive the paramagnetic particles and the fluid, a pipette configured to (i) translate so that at least a portion of the pipette is located within the cuvette and (ii) dispense at least one of the paramagnetic particles and the fluid into the cuvette so that the paramagnetic particles and the fluid can be mixed within the cuvette, a motor configured to move the pipette while located in the cuvette, and a control unit configured to vary a motor drive of the motor to cause the pipette to mix the fluid with the paramagnetic particles within the cuvette.

A pipette (1) having a cylinder (10), a piston (8), a volume display (25) for displaying a pipetting volume (14) associated with the piston stroke, a display adjustment mechanism (22) for changing the volume display (25), an adjustment display for indicating an adjustment of the pipette (1) via the volume display (25), and a volume adjustment mechanism (19) for changing the piston stroke, the volume adjustment mechanism (19) being coupled to the display adjustment mechanism (22) in a first mode of operation of the pipette (1), and the volume adjustment mechanism (19) being decoupled from the display adjustment mechanism (22), and the display adjustment mechanism (22) being coupled to the adjustment display in a second mode of operation of the pipette (1), a method of operating such a pipette.