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.

In one example an apparatus can include a controller communicatively coupled to a droplet dispenser to deposit antibody fluid on a matrix of an immunoblotting array, the controller is to align the droplet dispenser with a protein band included in the matrix, instruct the droplet dispenser to deposit a first antibody fluid on to the protein band of the matrix, and instruct the droplet dispenser to deposit a second antibody fluid on to the protein band of the matrix, adjacent to the first antibody fluid.

In example implementations, an apparatus is provided. The apparatus includes a channel, an opening in the channel, and a heating element aligned with the opening on opposite sides of the channel. The channel contains a droplet of a first liquid containing a particle, wherein the droplet is carried within a second liquid in the channel. The heating element is to heat the first liquid to generate a vapor in the first liquid to eject the droplet of the first liquid through the opening.

The invention relates to a piezoelectric micropipette, which comprises a capillary tube forming the pipette, and an expansion chamber connected to the capillary tube, the expansion chamber having a flexible element and being connected to a piezoelectric actuator. According to the invention the flexible element of the micropipette is arranged in the expansion chamber, and the flexible element is connected to a rigid displacing element, and a piezoelectric actuator is connected to the rigid displacing element.

A droplet (415) is ejected from a surface (411) of a fluid sample containing an analyte using an ejector (420). A solvent is pumped into a solvent inlet (432) of an open port probe (OPP) (430) spaced apart from the surface using a pump (438). The solvent is pumped to send it from the solvent inlet (432) to a tip (431) of the OPP (430) through a solvent capillary (434) of the OPP (430), receive the droplet (415) at the tip (431) where the droplet is combined with the solvent to form an analyte-solvent dilution, and transport the dilution from the tip (431) to an output (435) of the OPP (430) through a sample capillary (436) of the OPP (430). The solvent is heated to a temperature above a threshold temperature using a heating element (437). The solvent is heated to reduce the viscosity of the solvent below a threshold viscosity and maintain the viscosity below the threshold viscosity as the dilution is transported from the tip (431) to the outlet (435).

An example input voltage agnostic fluidic device may include a level shifter to adjust an input voltage of control signals received at an input interconnect to a voltage level that is within operational thresholds of on-chip devices of the input voltage agnostic fluidic device.

The invention relates to a method for detecting a particle in a container filled with liquid, the method having the following steps: dispensing a liquid sample into the container, scanning a partial volume area of the container in order to detect a particle located in the liquid sample, characterized in that an upper limit and a lower limit of the partial volume area is determined in a calibration operation upstream of the dispensing process.

This relates to acoustic microfluidic systems that can generate emulsions/droplets or encapsulate particles of interest (including mammalian cells, bacteria cells, or other cells) into droplets upon detection of the particles of interest flowing in a stream of particles. The systems operate on the detect/decide/deflect principle wherein the deflection step, in a single operation, not only deflects particles of interest from a stream of particles but also encapsulates the particles of interest in an emulsion droplet. The microfluidic systems have an abrupt transition in the channel geometry from a shorter channel to a taller channel (i.e., in the shape of a ‘step’) to break the stream of the dispersed phase into a droplet upon acoustic actuation. When there is no acoustic wave present, no droplets/emulsions are generated and the stream of particles proceeds uninterrupted. The rapid actuation and post-actuation recovery employed by the microfluidic systems taught herein ensure that the vast majority of selected particles are properly deflected, that few or no empty droplets are produced, and that total throughput remains high.

In one example in accordance with the present disclosure, a fluid ejection die is described. The fluid ejection die includes a fluid feed slot to deliver fluid from a reservoir to an array of ejection chambers fluid connected to the fluid feed slot. Each ejection chamber includes at least one fluid actuator and an opening through which fluid is to be ejected. The fluid ejection die also includes a number of antechambers. An antechamber includes sidewalls that curve inward.

A microfluidic valve may include a first portion of a liquid conduit to contain a gas, a second portion of a liquid conduit to contain a liquid, and a constriction between the first portion and the second portion and across which a capillary meniscus is to form between the gas and the liquid. The microfluidic valve may further include a drop jetting device within the second portion to open the valve by breaking the capillary meniscus across the constriction.