A metering apparatus including a scale on which a metering head is disposed in such a manner that the scale measures the weight of the metering head, and a metering tool for taking up and dispensing substance, attached to the metering head. The metering tool is configured as a glass tubule having a glass punch slidably disposed therein, forming a seal. The metering head is provided with a first gripping tool for clamping the glass tubule in place and with a second gripping tool for clamping the glass punch in place. The metering head furthermore has a raising and lowering device for raising and lowering the second gripping tool relative to the first gripping tool, such that the glass punch can be raised and lowered in the glass tubule of the metering tool.

Provided herein, in some embodiments, are compositions and methods for producing a molecular expression map of a biological sample using Deterministic Barcoding in Tissue for spatial omics sequencing (DBiT-seq).

A pipetting arrangement includes at least two sets of pipettes (9a; 9b; 9c; 9d). Each set of pipettes (9a; 9b; 9c; 9d) is operationally connected, via a controllable ON/OFF valve (11a; 11b; 11e; 11d) to a common aspiration port (7). Latter is connectable to a pumping arrangement. The valves (11a; 11b; 11e; 11d) are controlled by a timing-control unit (15) conceived to establish, by control of the valves (11a; 11b; 11e; 11d), the operational connections of the at least two sets of pipettes (9a; 9b; 9c; 9d) to the aspiration port (7) in a time-multiplexed manner.

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.

An apparatus includes a flow cell interface adapted to be coupled to a flow cell having a plurality of channels and a pump manifold assembly carrying pump valves and pumps and including pump-channel fluidic lines, pump fluidic lines, and a shared fluidic line. The pump valves and the pumps are operable to individually control fluid flow through each channel of the plurality of channels of the flow cell via the corresponding pump-channel fluidic lines. Each pump valve being coupled to a corresponding pump-channel fluidic line, a corresponding pump fluidic line, and the shared fluidic line and being movable between a first position fluidically coupling a corresponding channel, a corresponding pump-channel fluidic line, and a corresponding pump fluidic line and a second position fluidically coupling a corresponding pump fluidic line, the shared fluidic line, and a waste reservoir. Each pump coupled to a corresponding pump fluidic line.

A sample analysis support apparatus includes a sample region in which a sample is to be disposed, a tip region in which a tip is to be disposed, a first operation unit capable of an operation on the sample using the tip, the tip being attachable to and detachable from the first operation unit, a second operation unit capable of an operation on the sample using the tip, the tip being attachable to and detachable from the second operation unit, a transport unit configured to support each of the first operation unit and the second operation unit moveably between the tip region and the sample region, and a movement controller capable of controlling the transport unit to move each of the first operation unit and the second operation unit between the tip region and the sample region.

A pipette module 10 has a pipette-module frame 12 attachable to the z-axis frame 120 of a liquid handling system 100. A translatory-motion frame 14 attached to the pipette-module frame 12 is movable with respect thereto by a motor 16. A pneumatic aspirator assembly 18 including a cylinder 20, tube 24, tube tip 26 and pressure sensor 28 is attached to the translatory-motion frame 14. A piston 22 disposed in the cylinder 20 is fixedly attached to the frame 12. A controller 30 for the pipette module 10 has a liquid surface detection mode which enables a pressure feedback control algorithm causing the motor 16 to move the translatory-motion frame 14 in a z-axis translator motion until a change in a pressure in the tip 26 as sensed by the pressure sensor 28 indicates that the tip 26 has made contact with the liquid surface 110.

The present invention relates to a fluid transport system for an automated slide treatment apparatus for treating one or more tissue samples disposed on slides, whereby the slide treatment apparatus includes a plurality of slide treatment modules arranged to receive ones of the slides, and the fluid transport system includes a fluid dispensing robot configured by a controller to dispense a plurality of reagents to said ones of the slides received in the slide treatment modules to treat said one or more tissue samples respectively.

Aspects of the present disclosure relate to a method and/or a device for carrying out chemical, biochemical and/or immunochemical analyses of liquid samples, which are present in a sample store of an automatic analyzer, with the aid of liquid reagents which are present in at least one reagent store of the analyzer, with cuvettes for receiving the liquid samples and reagents, wherein a plurality of cuvettes is arranged as at least one stationary, linear cuvette array in the analyzer. The analyzer has movable and stationary automated components, wherein at least two automated components are designed so as to be movable in the x-direction independently of one another along or parallel to the line of movement defined by the linear cuvette array and each have access to different cuvettes or groups of cuvettes in a freely selectable sequence.

A rover-based integrated laboratory system including autonomous mobile robots is disclosed. Namely, a rover-based integrated laboratory system is disclosed comprising a workspace; a laboratory component within the workspace, the laboratory component being adapted to perform a laboratory technique; a labware component within the workspace that is adapted to be used in the laboratory technique; and a rover component within the workspace that is operatively connected to the laboratory and the labware components, the rover component being an autonomous mobile robot.