The present invention discloses a method for preparing a micro-channel array plate, comprising the steps of: (1) arranging a first optical fiber glass rod and a second optical fiber glass rod closely, melting the two glass rods into a whole at a high temperature to obtain a melted glass rod, drawing the melted glass rod at least one time into a longer and thinner glass rod than the melted glass rod, and cutting the drawn glass rod into small pieces to obtain a micro-channel array plate blank, wherein the corrosion resistance of the first optical fiber glass rod and the second optical fiber glass rod to the same corrosive liquid is different; (2) corroding the micro-channel array plate blank by a corrosive liquid to obtain a micro-channel array plate crude product with through holes; and (3) conducting hydrophobic treatment on the micro-channel array plate crude product to obtain the micro-channel array plate.

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 system and method for dispense characterization is disclosed. According to particular embodiments of the dispense characterization system and method, volumes of dispensed liquids can be determined. In more particular embodiments, additional characteristics and combinations of characteristics of a liquid dispensing event can be determined. Examples of additional characteristics that can be determined include the shape of the dispensing event, the velocity of the dispensing event, and the trajectory of the dispensing event. The dispense characterization system and method can be employed in automated biological sample analysis systems, and are particularly suited for monitoring liquid reagent dispensing events that deliver liquid reagents to a surface of a microscope slide holding a biological sample.

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 system includes a device configured to facilitate an interaction between a first fluid flow and a second fluid flow within a flow path of the device; an optical sensor configured to obtain one or more images representing the flow path; an image analysis module configured to: process the images to identify at least one droplet generated in a flow path of the device by the interaction between the first fluid flow and the second fluid flow, and estimate a size of the at least one droplet; and a control system configured to: determine that the size of the at least one droplet satisfies a threshold condition, and responsive to determining that the size of the at least one droplet satisfies the threshold condition, generate a signal that causes an adjustment to a flow rate of at least one of the first fluid flow or the second fluid flow.

A droplet dispensing apparatus includes a droplet ejection device, a microplate holder, and a sheet stand. The droplet ejection device has a solution holding vessel and an array of nozzles for ejection of droplets communicating with the solution holding vessel. The microplate holder is configured to hold a microplate into which the droplets are ejected. A test sheet being colored or discolored at a place where a light-transmissive droplet is received for testing the array of nozzles can be placed on the sheet stand. The droplet ejection device is configured to move to a first position above the microplate holder for ejection of droplets into the microplate and to a second position above the sheet stand for ejection of droplets onto the test sheet.

A droplet dispensing apparatus includes a droplet ejection device, a microplate holder, a sheet stand, an image capturing device and a controller. The image capturing device is configured to move to a position above the sheet stand. The controller is configured to perform image processing on image data generated from an image captured by the image capturing device when the image capturing device is at the position above the test sheet on the sheet stand, to determine a size of each of test patterns formed by droplets dropped on the test sheet from the array of nozzles. The controller is further configured to generate a data file including the determined size of each of the test patterns. The test sheet colors or discolors at a place receiving a light-transmissive droplet.

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 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.

The present disclosure teaches an apparatus and a method for providing one or more substance liquids to a microfluidic channel network. The microfluidic apparatus includes valves for switching the one or more substance liquids to a microfluidic channel network. The apparatus can be used to generate a sequence of the one or more substance liquids as individual droplets in an immiscible separation liquid wherein individual ones of the sequence of droplets are located between the separation liquid.