A microfluidic apparatus includes a microfluidic chip for MicroOrganoSpheres (MOS) generation. A first channel is defined in a surface of the microfluidic chip and includes: a droplet generation portion including an inlet portion, a junction between the inlet portion and an emulsifying fluid channel, and a chamber downstream of the junction. A cross-sectional area of the chamber is larger than that of the inlet portion. The first channel includes a polymerization portion downstream of the droplet generation portion, the polymerization portion having a serpentine configuration. The apparatus includes a cartridge for MOS demulsification, including: a collection container; a substrate disposed on the collection container, and a membrane disposed between the collection container and the surface of the substrate. A second channel is defined in the surface of the substrate that faces the collection container and is fluidically connected to an output of the polymerization portion of the first channel.

A droplet driving method includes displaying a droplet path editing interface in response to a droplet path editing request, where the droplet path editing interface at least includes a path planning window; receiving a path selecting operation in the path planning window and displaying, in the path planning window, the droplet moving path information corresponding to the path selecting operation; controlling a driving signal for the microfluidic chip according to the droplet moving path information to drive a droplet to move along a moving path corresponding to the moving path information when the microfluidic chip receives the driving signal.

A method for dispensing a liquid sample by means of a dispensing apparatus in which it is determined whether a particle condition is satisfied, wherein the determination comprises checking whether at least one target particle present in a liquid of the liquid sample is contained in a monitoring region of the dispensing apparatus, wherein the monitoring region comprises a discharge region and a buffer region, wherein the buffer region is a region from which the at least one target particle is movable into the discharge region during a time delay between the determination of whether the particle condition is satisfied and an output operation of the dispensing apparatus. The method is characterised in that it is determined that the particle condition is satisfied when the at least one target particle is arranged in the buffer region and no target particle is arranged in the discharge region, and that the liquid sample is dispensed onto a target particle carrier if the particle condition is satisfied.

An automated assay-fluid dispensing system includes a database that associates assay protocols with assay procedures, the procedures including a first assay procedure specifying dissimilar first and second channel procedures for driving first and second channels of a fluid-dispenser cassette. The system includes a controller with a procedure selector to select or to assist a human to select an assay procedure from the database to be executed in an assay run. The controller also includes a cassette driver to drive the cassette to dispense fluids automatically to multiple sites during the assay run so that fluids in the first and second channels are dispensed in accordance with the dissimilar first and second channel procedures. The system includes a cassette interface to engage the cassette so that the controller can drive it to implement the assay run.

A method includes flowing a first fluid through a first channel of a microfluidic apparatus and flowing a second fluid through a second channel of the microfluidic apparatus. The first fluid comprises biological material and a matrix material and is immiscible with the second fluid. The first and second fluids are combined at a junction to form droplets of the first fluid dispersed in the second fluid in a third channel. Multiple exposures of a droplet in the third channel are captured in a single image, comprising: illuminating a region of the third channel with multiple successive illumination pulses during a single frame of the imaging device; identifying the droplet and determining a velocity or a size of the droplet based on an analysis of the captured exposures; and controlling the flow of the first fluid or second fluid to obtain droplets of a target size or velocity.

A fluid cartridge has a bottle to retain a volume of fluid. An ejector chip resides in fluid communication with the bottle and causes ejection of fluid upon activation of fluid ejectors. Control logic coordinates ejector activation with dose control logic and temperature control circuitry. The dose control logic pre-specifies an amount of fluid to be ejected and prevents further ejection upon reaching the amount. Meanwhile, the temperature control circuit inhibits any ejection until a temperature of the fluid is within a predefined acceptable range. Bottle modularity, fluid dispense-areas and group-control of the ejectors facilitate certain designs.

A device for determining a position and/or an extension of a drop in a position determination space, where the device has a camera having an objective and a beam splitter in the recording area of the camera, and the device is designed in such a way that light coming from the position determination space can enter the objective of the camera along a first light path as well as along a second light path, where light along the first light path can be reflected at a first reflector element in the direction of the beam splitter and can be transmitted through the beam splitter towards the objective, and where light along the second light path can be reflected at a second reflector element in the direction of the beam splitter and can be reflected at the beam splitter towards the objective.

A method includes flowing a first fluid through a first channel of a microfluidic apparatus and flowing a second fluid through a second channel of the microfluidic apparatus. The first fluid comprises biological material and a matrix material and is immiscible with the second fluid. The first and second fluids are combined at a junction to form droplets of the first fluid dispersed in the second fluid in a third channel. Multiple exposures of a droplet in the third channel are captured in a single image, comprising: illuminating a region of the third channel with multiple successive illumination pulses during a single frame of the imaging device; identifying the droplet and determining a velocity or a size of the droplet based on an analysis of the captured exposures; and controlling the flow of the first fluid or second fluid to obtain droplets of a target size or velocity.

A method and system for determining droplet frequency of a flow of microfluidic droplets within a microfluidic droplet channel, comprising illuminating the flow of microfluidic droplets, using a beam splitter to split light from the flow of microfluidic droplets into a first portion and a second portion, directing the first portion to a camera, directing the second portion through an aperture located in front of a photodetector to the photodetector, and processing a signal from the photodetector and determining a droplet frequency from fluctuations in the processed signal. The method may be used to determine droplet dimension. The method may also be used to adjust a pressure of a flow of droplet fluid in response to a determined droplet dimension to generate a flow of droplets.

A method and system for generating a flow of droplets comprising providing a first droplet fluid, providing a second droplet fluid, providing a carrier fluid and forming a double emulsion of droplets each comprising a first droplet region comprising the first droplet fluid surrounded by a second droplet region comprising the second droplet fluid within the carrier fluid, by providing a flow of said first droplet fluid, a flow of said second droplet fluid, and a flow of said carrier fluid to a droplet generation sub-system of a microfluidic structure. The method comprises determining a dimension of said first droplet region of sequential droplets within the emulsion, determining an outer dimension of said second droplet region of sequential droplets within the emulsion, adjusting a pressure of the flow of the first droplet fluid in response to the determined dimension of the first droplet region, and adjusting a pressure of the flow of the second droplet fluid in response to the determined outer dimension of the second droplet region.