The present disclosure provides methods and devices for sample extraction.

The present invention relates to a reagent container and an operation method therefor, and a reagent treatment system. The reagent container comprises a tube body and an elastic tube stopper, the tube body comprises a tube stopper accommodating section, the tube stopper accommodating section comprises a first inner diameter section and a second inner diameter section in the depth direction of the tube body, the inner diameter of the second inner diameter section is smaller than that of the first inner diameter section; the elastic tube stopper is provided with a through channel in a direction extending into the tube body; the elastic tube stopper can be in non-interference fit with or be fitted by a first interference magnitude with the first inner diameter section, and the elastic tube stopper can be fitted with the second inner diameter section by a second interference magnitude; when the elastic tube stopper can be in non-interference fit with the first inner diameter section, the second interference magnitude is larger than zero, and when the elastic tube stopper can be fitted with the first inner diameter section by the first interference magnitude, the second interference magnitude is larger than the first interference magnitude; and the through channel is configured to be compressed and sealed along with radial shrinkage of the elastic tube stopper when the elastic tube stopper is fitted with the second inner diameter section by the second interference magnitude

A reaction method includes a reaction step of reacting two or more substances with each other by using a pipette tip, attached to a pipette nozzle, for sucking or discharging a liquid to supply a liquid to a reaction field and remove the liquid from the reaction field a plurality of times. The reaction method further includes: a first process of, prior to the reaction step, detecting an end height of the pipette tip and setting a reference height of the pipette nozzle on the basis of the end height of the pipette tip; and a second process of correcting, in a course of the reaction step, the height of the pipette nozzle from the reference height so as to cancel out variation in the end height of the pipette tip due to a change in the temperature of the pipette tip.

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.

Systems and methods for providing multiple lumens within a single sample probe of an autosampler system are described. In an aspect, a sample probe for an autosampler system includes, but is not limited to, a tube enclosing at least a portion of a plurality of lumens; and a controller communicatively coupled with a fluid handling system to introduce or draw one or more fluids through each of the plurality of lumens, wherein during a droplet purge operation, the controller is configured to expel a gas from a tip of one of the lumens to purge a droplet of fluid from the tip.

Provided herein are systems and methods for isolating a target from a biological sample. In some aspects, provided herein are automated systems and methods for isolating a target from a plurality of biological samples. For example, provided herein are automated systems and methods for isolating viral nucleic acid from a biological sample using a magnetic force to draw the nucleic acid out of a liquid biological sample.

This invention relates to methods, systems, and computer program products for verifying dispensing of a fluid from a pipette.

An improved system, method and interface for automated rapid antimicrobial susceptibility testing (AST) is disclosed which includes, in one aspect, a carrier population station comprising a workstation having a graphic user interface (GUI). The GUI accepts information from a lab technologist, including information related to a scope of testing to be performed on a microorganism containing sample. The GUI controls intelligent assignment of microorganism containing samples to test panels in a manner that maximize utilization of the test carrier by grouping together samples of similar tests scopes and advantageously testing those samples using one multiplexed test panel. Customizing workflow in accordance with test scope to facilitate parallel processing of multiple samples advantageously reduces laboratory waste, decreases test latencies, increases AST system throughput and efficiency, and thus lowers the costs to the AST lab.

Various embodiments include a system having a pipetting chamber, a set of pipettor cartridges docked in the pipetting chamber, a gantry system mounted on a ceiling within the pipetting chamber, the gantry system including at least one stationary track aligned in a first direction, and a movable track aligned in a second direction distinct from the first direction, the movable track coupled to the at least one stationary track, and a carrier configured to transport each of the set of pipettor cartridges to a pipetting location within the pipetting chamber, the carrier configured to move each pipettor cartridge in a third direction perpendicular to both the first and second directions.

A pipetting apparatus for aspirating and dispensing liquids having a pipetting unit with an interchangeable vessel that receives a liquid to be transferred, a holder for the pipetting unit, a positioning device for the pipetting unit, a micrometering unit, and an electronic control device. The micrometering unit is embodied separately from the pipetting unit and has a separate electronic control unit. The pipetting unit has a coupling device and the micrometering unit has a counterpart coupling device that matches the coupling device for the purpose of coupling. Coupling device and/or counterpart coupling device is/are switchable. The holder or the micrometering unit has a contact device with at least one electrical contact element and the micrometering unit or the holder has a counterpart contact device, matching the contact device, with at least one counterpart electrical contact element for making electrical contact with the contact element.