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. In one example embodiment, the automatic analyzer includes cuvettes, a first pipettor, a device with an optical measurement unit, a device for heterogenous immunoassays, a cuvette washing unit, a needle washing unit, a temperature control unit.

Various systems for the containment or delivery of a product are provided. The systems allow for the storage of products at low temperatures and include a container closure inserted into a container (10). The container closure may have an elastomeric body (12) and include a material (14) having a negative coefficient of thermal expansion. In other systems, the material having a negative coefficient of thermal expansion may be inserted between the elastomeric container closure and a seal. Other systems may include an insert at least partially embedded within the elastomeric body of a container closure, an actuator having a distal end movably attached to the insert, and a resilient element between the distal end of the actuator and the insert, wherein the resilient material expands radially upon displacing the distal end of the actuator toward the insert.

A tool for the distribution of a sample of biological or microbiological material, the tool including an elongated body, provided with a first portion and a second portion; a distributing element, the distributing element being configured at least for distributing a sample of biological or microbiological material on a culture medium; a connector being configured for allowing the joining of the tool with a supporting element of a machine configured for carrying out a distribution of a sample of biological or microbiological material, in particular of a pipetting machine; wherein the connector is adapted and specifically configured for being removably coupled to a supporting element in alternative to another tool, in particular to a tip or pipette for the collection and/or deposit of the sample of biological or microbiological material.

Provided is a pipette device that achieves both suction and discharge of a large amount of fluid and high-precision discharge of a minute amount of fluid. The pipette device includes: a first syringe 30 that is capable of suctioning fluid and is capable of discharging fluid with a predetermined discharge precision; a second syringe 40 that is capable of suctioning fluid and is capable of discharging fluid with a higher precision than the first syringe; a nozzle 70 provided in common to the first syringe 30 and the second syringe 40; a flow path 60 that causes the first syringe 30 and the second syringe 40 to be in communication with each other, and is in communication with the nozzle 70; and driving units 80, 90 configured to drive the first syringe 30 and the second syringe 40 such that the first syringe 30 and the second syringe 40 suction and discharge fluid from the nozzle 70 individually or in cooperation with each other.

Provided is a device for extracting and detecting nucleic acids, comprising one or more sample receiving modules, one or more lysing modules, one or more extraction module of nucleic acids, one or more amplification module of nucleic acids, and a detection module. Also provided is a molecular in vitro diagnostic instrument comprising the device for extracting and detecting nucleic acids and an automatic control system. Further provided is an in vitro diagnosis method by means of performing extraction and amplification of nucleic acids in a sample using the device for extracting and detecting nucleic acids.

A pipetting device for processing a fluid sample includes a receiving element and a pipette tip detachably arranged on the receiving element, a displacement element flow-connected to the pipette tip for generating a flow for receiving or ejecting the fluid sample. The pipetting device includes an optically transparent extension detachably arranged on the pipette tip in such a way that the extension is flow-connected to the displacement element via the pipette tip, so that the fluid sample can be received into the extension or can be ejected from the extension by the flow that can be generated by the displacement element.

What is disclosed in the present invention is to provide a quantitative transfer pipette structure, wherein an anti-backflow compartment is configured in the first bulb. The dimensions and locations of the first bulb, the second bulb and the third bulb are specifically configured to aspirate and transfer a specific volume of the liquid to a container, mix the liquid with the substance in the container by pressing and releasing the specific bulbs, so as to achieve the effects of precise quantification and sufficient mixing.

A laboratory instrument for processing a sample and a method for automatic surveillance of at least one pipetting procedure of at least one laboratory instrument for processing a sample are disclosed. The laboratory instrument includes at least one pipetting device with at least one pipetting head configured for being coupled to a plurality of pipetting tips. The laboratory instrument further includes a compartment configured for receiving, storing, and/or releasing at least one sample holder. The pipetting device is configured for performing at least one pipetting procedure on the sample holder and the laboratory instrument includes at least one sensor unit configured for gravimetric measuring of the sample holder.

A method for detection of a bottom of a well of a multiwell plate for a pipetting device is disclosed. The pipetting device includes a pipetting head configured for being coupled to a plurality of pipetting tips. A force sensor configured for measuring a resistance force depending on a force on a pipetting tip exerted by the bottom is used. The method includes measuring the resistance force during movement of one of the pipetting tips from a start position downstream towards the bottom of the well and stopping the movement at a bottom position. The method further includes storing the bottom position together with a corresponding logical position of the well in the multiwell plate in a database. Further disclosed is a pipetting device, a laboratory instrument for processing and/or analyzing a sample and a computer program and a computer-readable storage medium for performing the method.

A pipetting device, a system comprising the pipetting device, and a system for handling liquids and providing a pipetting device, the pipetting device comprising a housing with two parallel flat surfaces with a maximal distance of 17.5 mm between them accommodating a Z-shaft mounted in a guiding and connected to a Z-drive for actuating the Z-shaft; and a Y-drive which is connected to the housing and comprises a Y-gear wheel that is arranged next to an opening in the housing