The present disclosure provides methods and devices for sample extraction.

The invention relates to a pipetting device, more particularly a pipette or repeater pipette, for pipetting fluid laboratory samples, comprising: an electric control apparatus, by means of which a pipetting process is electrically controllable, a movable part, by means of the movement of which the fluid sample is pipettable, an electrically actuatable motor apparatus, by means of which the movement of the movable part is driveable depending on at least one first speed value defining the speed of the movable part, a measuring apparatus, by means of which at least one measured value which is influenced by the drag caused when pipetting the fluid sample is measurable, wherein the electric control apparatus is configured for the purposes of the at least one first speed value being fixable by the electric control apparatus, depending on at least one measured value. The invention furthermore relates to a method for operating the pipetting device.

A multiple-antenna positioning system with a single drive element, providing reduced weight and complexity over systems that have a drive element for each antenna. In certain examples, each antenna can be coupled with a rotating spindle, with each antenna spindle being coupled with a pair of link arms. By driving a single drive spindle, each of the antenna spindles in the system can be rotated by the associated pair of link arms. The link arms can have an adjustable length, such as through a turnbuckle mechanism, to reduce backlash in the system, and in some examples can apply a preload to the system. By reducing backlash, the multiple antenna positioning system can have improved responsiveness to a rotation of the single drive element, as well as improved stability of the positioning of each antenna when the drive element is held in a fixed position.

A dispensing system comprising a robot configured to move a dispenser for suctioning a liquid to be dispensed, a camera for capturing an image including at least a tip of the dispenser, a liquid surface of the liquid, and an object not to be dispensed located below the liquid surface, and circuitry configured to acquire, based at least in part on the image captured by the camera, surface location information for the liquid surface, boundary location information for a boundary between the liquid and the object not to be dispensed, and dispenser location information for the tip of the dispenser on the basis of the image, and control the robot to lower the dispenser based at least in part on the dispenser location information, the surface location information, and the boundary location information.

A microfluidic reagent card for medical testing and assaying is disclosed. The microfluidic reagent card comprises a card body (10) and a plurality of micropipes, the plurality of micropipes is fixed onto the card body (10). The plurality of micropipes is arranged radially. Each of the micropipe is configured to have a sample inlet end (1) and a closed end (2), and a detection liquid layer (3) and a separation medium layer (4) are arranged inside each micropipe in sequence from the sample inlet end (1) to the closed end (2). The micropipe has a diameter of 0.1-1.0 mm. As the micropipe is configured to have a small diameter, the fluidity of liquid and gel decreases inside the micropipe, and the liquid interface will not flow even when the micropipe is placed in a horizontal direction.

Systems and methods applicable, for instance, to pipette robots. A pipette robot can perform one or more operations regarding deck calibration, one or more operations regarding pipette tip/probe calibration, one or more operations regarding pipette tip pick up, and/or one or more operations regarding tip ejection.

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.

Provided is an electric pipette system, including: an operating condition receiving milt configured to receive an operating condition of a manipulation operation to foe occur next; a suction/discharge operating unit configured to perform at least any one of a suction operation and a discharge operation of a liquid by an electric pipette based cm the operating condition; an information collecting unit configured to collect various types of information during the suction operation or the discharge operation of the liquid; and an information recording unit configured to record the information.

The invention relates to a pipette auxiliary system for supporting manual pipetting or dispensing of a plurality of samples of a sample-holding arrangement, in particular a microtiter plate. The pipette auxiliary system according to the invention supports the manual pipetting or dispensing of a plurality of samples in a working position of a sample-holding arrangement, the pipette auxiliary system comprising: a base apparatus comprising a positioning device which is designed to position the sample-holding arrangement in the working position inside a positioning space of the base apparatus, said positioning space being opened at least along a plane for the pipetting; the sample-holding arrangement which has a plurality of sample holders; a measurement arrangement comprising a plurality of measurement elements which are positioned at least in the working position underneath this plane and using which the occupancy state of at least one sample holder can be detected in the working position; and an output device or a light arrangement using which the sample-holding arrangement can be illuminated in accordance with this occupancy state of this at least one sample holder.

The invention relates to a laboratory apparatus, and a method, for device-controlled handling of at least one laboratory sample, wherein the laboratory apparatus comprises at least one handling device, wherein the handling is controlled by the laboratory apparatus in use of several program parameters, a control device, a user interface device for manually inputting data by an user, and for the display of information, which may in particular depend on these data, wherein the user interface device comprises a display, on which a display area can be represented, and wherein the user interface device comprises a movement detecting sensor device, which is arranged for the detection of at least one user movement, which can be performed on the display area by an user, and wherein the control device is arranged for the provision of a movement detecting input mode, in order toselect the at least one program parameter and/or define its value depending on the at least one user movement, anddisplay at least one graphical sketch element, which represents the at least one user movement, in the display area, depending on the at least one user movement.