The present application relates to the field of liquid treatment, and discloses a solution for quantitatively treating a liquid. The solution includes: a container used for containing a liquid to be extracted or discharged; and a micro tubule including: a flow passage extending outwards from the interior of the container to a bifurcation point; a first by-pass communicating with the flow passage and extending from the bifurcation point to a first port; and a second by-pass communicating with the flow passage and extending from the bifurcation point to a second port. A peristaltic pump is disposed in series in at least one of the flow passage, the first by-pass and the second by-pass, and a cut-off valve or another peristaltic pump is disposed in series in at least another of the flow passage, the first by-pass and the second by-pass, so that a predetermined volume of liquid between the bifurcation point and the first port or the second port can be intercepted.

An automatic analyzer capable of confirming the amount of sample aspirated by a sample dispensing unit is provided.

An automatic analyzer that analyzes a sample includes an incubator which holds a reaction container in which a liquid mixture of the sample and a reagent is accommodated, a sample dispensing unit which dispenses the sample by aspirating the sample from a sample container in which the sample is accommodated and storing the aspirated sample in a storage portion and then discharging the sample to the reaction container, and a measurement portion which measures the amount of sample in the storage portion on the basis of a detected signal obtained by detecting light passing through the storage portion while irradiating the storage portion with light.

Automated pipetting systems and methods are disclosed for aspirating and dispensing fluids, particularly biological samples. In one aspect, a liquid dispenser includes a manifold and one or more pipette channels. The manifold includes a vacuum channel, a pressure channel, and a plurality of lanes. Each lane includes an electrical connector, a port to the pressure channel, and a port to the vacuum channel. The pipette channels can be modular. Each pipette channel includes a single dispense head and can be selectively and independently coupled to any one lane of the plurality of lanes. In some aspects, a valve in the pipette channel is in simultaneous fluid communication with a pressure port and a vacuum port of the manifold. The valve selectively diverts gas under pressure and gas under vacuum to the dispense head in response to control signals received through the electrical connector of the manifold.

A method is disclosed for controlling at least one of aspirating and of dispensing a liquid dose or of producing a liquid dose in a pipette or in receptacle, the method having the steps of first loading a first pipette with a first working medium at a first pressure having a first sign with respect to a reference pressure, thereby dispensing the liquid dose into the receptacle or aspirating the liquid dose into the first pipette, second loading a second pipette with a second working medium at a second pressure having a second sign with respect to the reference pressure, thereby dispensing the liquid dose into the receptacle or aspirating the liquid dose into the second pipette, discharging a pressure in the first working medium through a controlled valve arrangement to the reference pressure between first and second loadings. A pipetting device is also disclosed.

Diagnostic analyzers with pretreatment carousels and related methods are disclosed. An example apparatus includes a first carousel that includes a first annular array of slots to receive a first vessel. The example first carousel also includes a first track of rotation about the first carousel having a first diameter and a second track of rotation about the first carousel having a second diameter smaller than the first diameter. The example apparatus includes a first diverter to move the first vessel from the first track to the second track. In addition, the example apparatus includes a second carousel coaxial with the first carousel. The example second carousel includes a second annular array of slots to receive a second vessel.

A controller configured to control one or more of aspiration and dispensing of a primary fluid by an aspirate-dispense apparatus, the aspirate-dispense apparatus comprising a secondary fluid in working communication with the primary fluid, wherein the controller is configured to: receive measurement signalling for a monitored flow parameter of the secondary fluid; determine, using calibration data, a volume of aspirated or dispensed primary fluid based on the received measurement signalling, the calibration data defining a relationship between the volume of aspirated or dispensed primary fluid and the monitored flow parameter of the secondary fluid; and control the flow of primary or secondary fluid based on the determined volume to aspirate or dispense a specific volume of primary fluid.

A cell picking device includes a stage, a sucker, a driver, a work content receiver, a registrar and a device controller. A sample container is placed on the stage. The driver is provided to execute sample scraping work and sample sucking work using a pipette tip attached to the sucker. In a case in which selection of work contents of the driver is received by the work content receiver, a work procedure including the received work contents of the driver is registered by the registrar. The work of the driver is controlled by the device controller in accordance with the registered work procedure.

A method is disclosed for controlling at least one of aspirating and of dispensing a liquid dose or of producing a liquid dose in a pipette or in receptacle, the method having the steps of first loading a first pipette with a first working medium at a first pressure having a first sign with respect to a reference pressure, thereby dispensing the liquid dose into the receptacle or aspirating the liquid dose into the first pipette, second loading a second pipette with a second working medium at a second pressure having a second sign with respect to the reference pressure, thereby dispensing the liquid dose into the receptacle or aspirating the liquid dose into the second pipette, discharging a pressure in the first working medium through a controlled valve arrangement to the reference pressure between first and second loadings. A pipetting device is also disclosed.

In one embodiment, a method is provided comprising analyte testing on one or more types of samples.

Disclosed is a fluid disposing system including a centrifugal separator that centrifugally separates a liquid that is supplied, a reagent supply module provided on one side of the centrifugal separator and that supplies a reagent to the centrifugal separator, a pipetting module provided at an upper portion of the centrifugal separator and that feeds a fluid to the centrifugal separator, a feeding module coupled to one side of the pipetting module, and that moves the pipetting module in an X axis direction and a Y axis direction corresponding to a horizontal direction, and a Z axis direction that is perpendicular to the horizontal direction, and a separation module including a magnetic bead for magnetically separating a material that has been primarily separated by the centrifugal separator.