An integrated microfluidic chip and a single-cell culture, screening, and export method applying the same are disclosed; the chip includes a base, an inlet flow channel, an outlet flow channel, a plurality of common flow channels and a plurality of functional units, wherein two ends of the common flow channel are connected to the inlet flow channel and the outlet flow channel, respectively, wherein each of the functional units includes a single-cell introduction port, a cell culturing-screening chamber, a cell export chamber, a cell export port, and a drive element, wherein the drive element is used to provide power to liquid to introduce single cells entering the common flow channels into the cell culturing-screening chamber, and after culturing and screening, to export target cell population in the cell culturing-screening chamber through the cell export port.

A single junction sorter for a microfluidic particle sorter, the single-junction sorter comprising: an input channel, configured to receive a fluid containing particles; an output sort channel and an output waste channel, each connected to the input channel for receiving the fluid therefrom; a bubble generator, operable to selectively displace the fluid around a particle to be sorted and thereby to create a transient flow of the fluid in the input channel; and a vortex element, configured to cause a vortex in the transient flow in order to direct the particle to be sorted into the output sort channel.

In one example an apparatus can include a controller communicatively coupled to a droplet dispenser to deposit fluid on a digital microfluidic (DMF) array including a plurality of droplet manipulation electrodes, the controller to: select a first droplet manipulation electrode from the plurality of droplet manipulation electrodes to on which to dispense a first volume of fluid via the droplet dispenser; position the droplet dispenser over the selected first droplet manipulation electrode; and deposit the first volume of fluid onto the selected first droplet manipulation electrode.

The present disclosure provides for methods of delivering cargo material to a cell(s) in vivo or in vitro, devices configured to deliver cargo material to the cell, systems configured to deliver cargo material to the cell, and the like. The present disclosure can synergistically combine multiple technologies to improve the rate of cargo material introduction and utility of physical cellular modification in a transformative way compared to the current microinjection state-of-the art.

Methods are provided for separating magnetically responsive beads from a droplet in a droplet actuator. Droplet operations electrodes and a magnet are arranged in a droplet actuator to manipulate a bead-containing droplet and position it relative to a magnetic field region that attracts the magnetically responsive beads. The droplet operations electrodes are operated to control the droplet shape and transport it away from the magnetic field region to form a concentration of beads in the droplet. The continued transport of the droplet away from the magnetic field causes the concentration of beads to break away from the droplet to yield a small, concentrated bead-containing droplet immobilized by the magnet.

An analytical toilet is disclosed with a bowl adapted to receive excreta, a conduit for transporting a liquid excreta sample from the bowl, and a liquid reagent source. The analytical toilet also includes a microfluidic chip that has a sensor configured to detect at least one property of the excreta sample. The microfluidic chip also has an excreta sample path in fluid communication with the conduit and the sensor and a reagent path in fluid communication with the liquid reagent source and the sensor. The length of and number of channels in the sample path and the reagent path are selected so as to control the respective fluid resistance of the excreta sample and the reagent to thereby optimize the mixing and flow rates of the excreta sample and reagent into the sensor. There is also disclosed analytical toilet with a microfluidic chip having reagent path that includes a first and a second channel. The second channel is longer than the first channel. A valve, which is controllable so as to cause the reagent to flow through either the first channel, the second channel or both channels. As such, the fluid resistance of the reagent is controlled, to thereby optimize the flow rate of the reagent into the sensor.

Systems and methods for recovering content of a sample from a microcapillary array are provided. The microcapillary array includes a plurality of microcapillary wells. A laser is positioned to target a first microcapillary well in the plurality of microcap-wells. The laser pulses at least one time at the first microcapillary well. The content from the first microcapillary well is extracted, recovering the content of the first microcapillary well.

In an embodiment, the present disclosure pertains to a microfluidic platform composed of a droplet generator having an entry point for donor particles and target particles, a first droplet incubation chamber in fluid communication with the droplet generator, a droplet detection functionality to allow for analysis of the inner content of droplets, and a droplet sorting functionality to allow for the separation of droplets based on the analysis of the inner content of droplets. In another embodiment, the present disclosure pertains to a method for cell-to-cell DNA, RNA, or other genetic material transfer through use of a water-in-oil emulsion microdroplet-based microfluidic platform for automation and high throughput identification or screening of genetic transfer outcomes utilizing the microfluidic platforms as disclosed herein.

A unitary, molded fluid reservoir body to which a fluid ejection head substrate is attached. The unitary, molded fluid reservoir body includes one or more discrete fluid chambers therein. Each of the one or more fluid chambers have an open top, side walls, and sloped bottom walls attached to the side walls, wherein each of the one or more fluid chambers terminates in a fluid supply via, and wherein the sloped bottom walls have an angle ranging from about 6 to about 12 degrees relative to a plane orthogonal to the sidewalls. An ejection head support face is disposed opposite the open top for attachment of a single fluid ejection device to the ejection head support face for ejecting fluid provided from the one or more chambers through the one or more fluid supply vias.

The present disclosure is drawn to microfluidic cellular membrane modification devices. In one example, a microfluidic cellular membrane modification device can include a microfluidic channel including a pumping portion and an electric field portion. An electrode pair can be positioned about the electric field portion. A bidirectional pump can be in fluid communication with the microfluidic channel at the pumping portion to move fluid backward and forward through the electric field portion.