A device (1) for storing reagent containers on several planes for an automatic analysis appliance. The device (1) comprises a pipetting device comprising a pipetting needle (2) for pipetting of reagents, a first device (3) comprising a plurality of first receiving positions (5) for reagent containers, wherein the first receiving positions (5) are arranged on a first plane, and a second device (4) comprising a plurality of second receiving positions (6) for reagent containers, wherein the second receiving positions (6) are arranged on a second plane.

A cell picking device includes a sucker having a pipette tip attached to a tip portion of the sucker and is used to suck the cell from a tip of the pipette tip, a driver configured to cause the sucker to perform a suction operation and move the sucker in a horizontal-plane direction and an axial direction of the pipette tip with the sucker inclined with respect to a vertical direction. A controller moves the sucker such that the tip of the pipette tip moves in a horizontal direction while being in contact with a bottom surface of the container installed on the sample mounting stage in a predetermined position on the sample mounting stage to desorb a cell arranged in the predetermined position from the bottom surface of the container, and suck the cell desorbed from the bottom surface of the container from the tip of the pipette tip.

A method for preparing a deck for a process is disclosed. The deck can be prepared with any necessary components, and then an imaging device can capture an image of the deck. This image can be compared with a reference image and any differences identified. The differences can be indicated in the image and shown to an operator, such that the operator can correct any errors associated with the differences.

Techniques are described for automated microinjection of substances, such as genetic material, into single cells in tissue samples. An example system comprises a robotic manipulator apparatus configured to hold and position a micropipette. Furthermore, the system comprises a microscope camera positioned to observe an injection site. A computing device receives image data from a microscope camera of the system, where the image data represents an image of a tissue sample. The computing device receives, via a user interface, an indication of a line traced by a user on the image of a tissue sample. In response, the computing device controls the robotic manipulator apparatus to move a tip of the micropipette along a path defined by the trajectory line. The pressure controller injects a gas into the micropipette to eject a substance out of the micropipette at one or more points along the path defined by the trajectory line.

A gripper having a mechanical coupling that can be connected to a pipetting tube, at least one fluid channel extends from the coupling and a negative pressure can be transmitted, the gripper having at least one suction cup that is connected to the coupling through the at least one fluid channel as a result of which the negative pressure can be transmitted from the coupling to the at least one suction cup, and the at least one suction cup in the intended use position of the gripper is aligned such that a rim of a suction cup of the at least one suction cup is aligned in a substantially vertical plane.

An apparatus for decontaminating and storing lab instruments such as pipettes. A carousel feature of the apparatus provides convenient access and allows multiple items to be decontaminated at the same time. The ultraviolet lamp directs UV radiation to surface contaminations of the instruments and effectively eliminates various microorganisms.

Techniques are described for automated microinjection of substances, such as genetic material, into single cells in tissue samples. An example system comprises a robotic manipulator apparatus configured to hold and position a micropipette. Furthermore, the system comprises a microscope camera positioned to observe an injection site. A computing device receives image data from a microscope camera of the system, where the image data represents an image of a tissue sample. The computing device receives, via a user interface, an indication of a line traced by a user on the image of a tissue sample. In response, the computing device controls the robotic manipulator apparatus to move a tip of the micropipette along a path defined by the trajectory line. The pressure controller injects a gas into the micropipette to eject a substance out of the micropipette at one or more points along the path defined by the trajectory line.

Provided is a multichannel pipette whose number of channels can be arbitrarily set and managed to improve usability of the multichannel pipette and improve productivity, quality control, and maintainability in a research site. A multichannel pipette includes a pipette main body, a lower part attached to a lower end portion of the pipette main body, and a plurality of chip holder units housed inside the lower part, wherein each of the chip holder units has a connecting portion attachable to and removable from any of a plurality of to-be-connected portions provided in a unit case inside the lower part, and each of the chip holder units is attachable to and removable from the lower part.

A pipetting device includes pipetting unit(s), a guide assembly with at least one guide rail on which the pipetting unit(s) is guided in order to be moved along a movement axis, and a linear drive assembly, by which the pipetting unit(s) can be driven in order to be moved along the movement axis. The linear drive device has a stationary stator, and the at least one pipetting unit forms a linear drive assembly rotor which can be moved along the movement axis relative to the stator. The pipetting device also has at least two rotor magnet assemblies which interact with the same common stator magnet assembly so as to generate a drive force and which are arranged at a distance from one another along a spacing axis that is orthogonal to the movement axis. The common stator magnet assembly is located between the at least two rotor magnet assemblies.

Systems and methods for nesting refill filtered pipette tips to reduce storage space and plastic waste are provided herein. Embodiments include a lower filtered refill wafer comprising a lower plurality of refill filtered pipette tips in a nested filtered pipette tip rack, the lower filtered refill wafer comprising the lower plurality of refill filtered pipette tips having holes between top portions of the lower plurality of refill filtered pipette tips. Various embodiments further include an upper filtered refill wafer comprising an upper plurality of refill filtered pipette tips nested into the holes between the top portions of the lower plurality of refill filtered pipette tips, the nesting of the upper filtered refill wafer thereby reducing storage space for the nested filtered pipette tip rack compared with storage space for a filtered pipette tip rack that is not nested.