A sample input interface for inputting samples into a detecting unit of an in-vitro diagnostic analyzer. The sample input interface comprises a sample input port comprising an outer input-port side configured for plugging-in an open end of a sample container and an inner input-port side, an aspiration needle comprising an upstream end and a downstream end, where the downstream end is fluidically connected or connectable to the detecting unit and where the upstream end is configured to alternately couple to the inner input-port side and to a fluid supply port. The outer input-port side is further configured to alternately couple to a fluid supply port while the upstream end of the aspiration needle is coupled to the inner input-port side in order to rinse the sample input port with fluid aspirated by the aspiration needle from a fluid supply unit via the sample input port.

A pipette-fillable fluid reservoir body. The fluid reservoir body includes two or more discrete fluid chambers therein. At least one of the fluid chambers contains a pressure compensation device and at least another one of the fluid chambers is devoid of a pressure compensation device. Each of the fluid chambers is in fluid flow communication with a fluid supply via, and each of the fluid chambers have sidewalls and a bottom wall attached to the side walls, wherein the bottom wall slopes toward the fluid supply via. The fluid reservoir body also includes an ejection head support face in fluid flow communication with the fluid chambers for attachment of a fluid ejection device to the ejection head support face for ejecting fluid from the fluid chambers.

Automatic substance preparation and evaluation systems and methods are provided for preparing and evaluating a fluidic substance, such as e.g. a sample with bodily fluid, in a container and/or in a dispense tip. The systems and methods can detect volumes, evaluate integrities, and check particle concentrations in the container and/or the dispense tip.

A system for applying a fluid to a substrate bearing a sample for analysis has an array of sensor plates positioned to sense the presence of fluid in contact with respective areas of the substrate. In a particular embodiment, fluid presence in different areas of the substrate is sensed by the effect of the fluid and its identity on the impedances of capacitors formed between sensor plates within the array. In a more particular embodiment, by polling the sensor array continually while fluid is applied to the substrate determine a coverage map, a fluid dispensing mechanism can be controlled to efficiently cover the entire substrate with fluid a minimal amount of fluid, thereby reducing waste.

A method for operating a laboratory system comprising instruments for processing samples and a control unit connected by a communication network is presented. The method comprises receiving and identifying a biological sample and retrieving an order list from a database. The list comprises a plurality of targets defining one or more processing steps to be carried out on the biological sample by one or more of the laboratory instruments. The method also comprises selecting a workflow strategy and retrieving workflow acceptance criterion corresponding to the workflow strategy. The control unit determines a sample workflow for processing the sample based on the workflow strategy and determines whether the sample workflow satisfies the workflow acceptance criterion. If the sample workflow does not satisfy the workflow acceptance criterion, workflow strategy and the workflow acceptance criterion is refined and the sample workflow is determined again until it satisfies the workflow acceptance criterion.

A system and method of fluid delivery for providing a surface fluid pattern, the system comprising: a fluid delivery head for fluid flow therethrough, the fluid delivery head comprising: a fluid delivery surface having surface openings defined therein and arranged across the fluid delivery surface as a two-dimensional display; wherein at least some of the surface openings are grouped as a surface opening unit having at least one aspiration opening through which fluid can be provided to the fluid delivery surface and at least one injection opening through which fluid can be moved away from the fluid delivery surface, the surface opening unit comprising at least three surface openings positioned as a two-dimensional display and outwardly of at least one other surface opening.

An object of the present invention is to provide a dispensing device capable of preventing bubbles from jumping out of a nozzle and realizing highly accurate dispensing even though the nozzle is moved at a high speed toward a liquid level and is decelerated and stopped at a high acceleration. The dispensing device according to the present invention starts suction of a liquid in a period from when a nozzle starts to be lowered toward a liquid level of the liquid to when an end portion of the nozzle comes into contact with the liquid level of the liquid and the lowering of the nozzle is stopped (see FIG. 6).

A system and method for ejecting one or more fluids from a digital dispense device. The method includes a) inputting to a memory a volume per unit area for each of the one or more fluids to be ejected from the digital dispense device; b) matching the volume per unit area to a device resolution for the digital dispense device; c) formatting fluid ejectors for the digital dispense device for the device resolution; and d) ejecting fluid from the digital dispense device to provide the volume per area for each of the one or more fluids.

A cell sorter includes a base for holding a cell culture plate containing a fluorescently labeled sample of cells, a fluorescence imager for viewing the cell culture plate, through bottom of the cell culture plate, to capture one or more fluorescence images of the fluorescently labeled sample of cells, and a cell extraction module for extracting a cell selected based on the one or more fluorescence images. The cell extraction module includes a needle for hydraulically removing the selected cell from the cell culture plate, and a motorized translation stage for translating the needle in a z-dimension to reach the selected cell from above. The cell sorter further includes a motorized translation stage for translating one of the needle and the cell culture plate in x- and y-dimensions, relative to the other one of the needle and the cell culture plate, to position the needle over selected first cell.

A pipetting apparatus having a pipette tube with a first end provided with an opening for aspirating and/or dispensing of a sample fluid and a second end operationally connected to a pressure generating means. The pipetting apparatus has at least one measuring unit adapted to determine at least one measurement value of the sample fluid based on the aspirating and/or dispensing of the sample fluid and to provide a sample fluid measurement signal representative thereof to an output of the measuring unit. The pipetting apparatus also has a control circuit operationally coupled to the output of the measuring unit and the input of the pressure generating means, the control circuit is configured to control said pressure generating device based on the sample fluid measurement signal.