A cartridge for delivering a payload to cells of a cell suspension is provided, wherein the cartridge comprises an input channel that delivers the cell suspension to a first plurality of branch channels, and wherein the first plurality of branch channels each deliver the cell suspension into a respective one or a plurality of microfluidic chips or filters. Cell suspension exiting a microfluidic chip or filter flows into a respective one of a second plurality of branch channels, and is then delivered to an output channel by which it exits the cartridge. The cartridge may comprise a plurality of removable covers that hold the chips or filters in place against a body of the cartridge in which the input channel, output channel, and branch channels are formed.

A technique relates to a fluidic cell configured to hold a nanofluidic chip. A first plate is configured to hold the nanofluidic chip. A second plate is configured to fit on top of the first plate, such that the nanofluidic chip is held in place. The second plate has at least one first port and at least one second port. The second plate has an entrance hole configured to communicate with an inlet hole of the nanofluidic chip. The second port is angled above the first port, such that the first port and second port intersect to form a junction. The second port is formed to have a line-of-sight to the entrance hole, such that the second port is configured to receive input for extracting air trapped at a vicinity of the entrance hole.

The invention relates to a method for ordering, sorting and/or focusing particles in a first microfluidic channel system, the method comprising the steps of i) providing for a first microfluidic channel comprising at least a first and a second inlet and a first outlet, ii) injecting a first fluid into the channel through said first inlet, iii) injecting a second fluid into the channel through said second inlet, wherein the viscosity of the first fluid is higher than the viscosity of the second fluid, such that the two fluids flow in a laminar fashion unmixed side by side, and one of the two fluids comprises the particles to be ordered, sorted and/or focused. The invention also relates to a microfluidic channel system for sorting different particles into one droplet.

A particle separating and measuring device of the present disclosure includes: a first flow path device including a post-separation flow outlet through which a first fluid containing specific particles to be separated flows out; and a second flow path device on which the first flow path device is placed and including a first flow inlet through which the first fluid flows in, the first flow path device in which the post-separation flow outlet is arranged in a lower surface is placed on the second flow path device in which the first flow inlet is arranged in an upper surface of a first region, the post-separation flow outlet and the first flow inlet are connected so as to face each other, and a size of an opening of the first flow inlet is larger than a size of an opening of the post-separation flow outlet.

A microfluidic system configured to focus particles suspended in a fluid. One general aspect includes a microfluidic system comprising one or more substrates and a focusing channel formed in the one or more substrates and spanning a length from an inlet to an outlet for receiving a flow of particles suspended in fluid, wherein the particles have a diameter (a) and the focusing channel has a hydraulic diameter (dh).

A step-type inertial focusing microfluidic chip includes an arc-shaped channel having multiple stages connected in series. At least one stage of the arc-shaped channel is separated into a plurality of sub-channels distributed along a radial direction, one end of the multistage arc-shaped channel is provided with at least one fluid inlet and an inlet channel connecting the end of to the fluid inlet. The other end of the multistage arc-shaped channel is provided with a plurality of fluid outlets and a plurality of outlet channels connecting the other end to the fluid outlets. A radius of curvature of the arc-shaped channel is 2 to 50 mm. A cross-sectional width is 50-5000 microns, the cross-sectional height is 20-2000 microns, and a thickness of a sub-channel separation wall in the arc-shaped channel having the sub-channels is 10 to 1000 microns.

Microfluidic devices and methods for focusing components in a fluid sample are described herein. The microfluidic devices feature a microfluidic chip having a micro-channel having a constricting portion that narrows in width, and a flow focusing region downstream of the micro-channel. The flow focusing region includes a positively sloping bottom surface that reduces a height of the flow focusing region and sidewalls that taper to reduce a width of the flow focusing region, thereby geometrically constricting the flow focusing region. The devices and methods can be utilized in sex-sorting of sperm cells to improve performance and increase eligibility.

A fluid entrained particle separator may include an inlet passage to direct particles entrained in a fluid, a first separation passage branching from the inlet passage, a second separation passage branching from the inlet passage and electrodes to create electric field exerting a dielectrophoretic force on the particles to direct the particles to the first separation passage or the second separation passage, wherein the first separation passage, the second separation passage, the electric field and the dielectrophoretic force extend in a plane.

Methods include treating a portion of a sample composition to be tested for presence of an analyte by depleting or blocking the target analyte. The treated composition may be used to equilibrate an acoustic wave sensor prior to exposing the sensor to the untreated sample composition for analysis. By using the treated sample composition, in which the analyte is depleted or blocked, to equilibrate the sensor, the sensor may be equilibrated with a composition having a similar viscosity and non-specific binding characteristics to the untreated sample composition, which should result in improved accuracy when analyzing the analyte in the untreated sample composition.

The present disclosure relates to a fluidic device to detect, capture, and/or remove disease material in a biological fluid. The present invention also relates to methods for the treatment/prevention of sepsis through the use of the claimed device.