A microfluidic device includes a substrate and a cover. The substrate has an inlet port, a first microchannel, one or more parking loops, a second microchannel and an outlet port for each microchannel network. The first microchannel is connected to the inlet port, the second microchannel is connected to the outlet port, the parking loops are connected between the first and second microchannels. Each parking loop includes a parking loop inlet, a parking loop output, a fluidic trap connected between the parking loop inlet and the parking loop outlet, and a bypass microchannel connected to the parking loop inlet and the parking loop outlet. The cover is attached to a top of the substrate and has an inlet opening and an outlet opening through the cover for each microchannel network. The inlet and outlet openings of the cover are disposed above the inlet and outlet ports in the substrate.

Provided is a multi-flux micro-fluidic chip including a chip body. The chip body includes a fluid inflow cavity communicated with an external air path, reaction-quantification cavities, waste liquid cavities, and a fluid path distribution cavity disposed at a middle position of the chip body. The two or more reaction-quantification cavities are distributed on two sides of the fluid path distribution cavity in rows to form the first and second row of reaction-quantification cavities respectively; and they are communicated with a fluid outlet of the fluid path distribution cavity through fluid path branches, and a fluid inlet of the fluid path distribution cavity through fluid path branches, and a fluid inlet of the fluid path distribution cavity is communicated with a fluid outlet of the fluid inflow cavity and an external fluid path, which making it possible to detect multiple items simultaneously and greatly improving the flux of the micro-fluidic chip.

Described here is a microfabricated particle sorting device that uses a transient pulse of fluidic pressure to deflect the target particle. The transient pulse may be generated by a microfabricated (MEMS) actuator, which pushes a volume of fluid into a channel, or sucks a volume of fluid from the channel. The transient pressure pulse may divert a target particle into a sort channel.

A method of analyzing a skin-print provided on a first surface of an optically transparent substrate. The method comprises the steps of exposing the skin-print on the first surface of the optically transparent substrate to one or more reagents selected to bind with one or more metabolites present in the skin-print; transmitting electromagnetic radiation onto the skin-print through the optically transparent substrate using a radiation source to thereby produce an optical signal of said one or more reagents and/or said one or more metabolites; and detecting an optical image of the optical signal through the optically transparent substrate using a sensor. Also a skin-print analysis apparatus and a reagent cartridge for use in carrying out the method.

Provided is a rotatable microfluidic device for conducting simultaneously two or more assays. The device includes a platform which can be rotated, a first unit which is disposed at one portion of the platform and detects a target material from a sample using surface on which a capture probe selectively binds to the target material is attached, and a second unit which is disposed at another portion of the platform and detects a target material included in the sample by a different reaction from the reaction conducted in the first unit.

This invention pertains to a new microfluidic device and the method of using it to sort droplets. The method comprises (a) providing a plurality of droplets flowing in a microfluidic channel, wherein the plurality of droplets comprise desired droplets and undesired droplet (b) identifying desired droplets in the plurality of droplets, (c) changing volume of the desired droplets relative to volume of the undesired droplets such that at least some of the desired droplets have a different volume than the undesired droplets, and (d) passively sorting the desired droplets having the different volume from the undesired droplets.

Certain embodiments are directed to finite step emulsification device and/or methods that combine finite step emulsification with gradients of confinement for the formation of a 2D monolayer array of droplets with low size dispersion.

A microfluidic flow cell array can include a fluid directing body with multiple layers of three-dimensionally printed material defining a first pair of microfluidic channels that individually transect a portion of the multiple layers and also redirect fluid flow when within the fluid directing body, and a second pair of microfluidic channels that individually transect a portion of the multiple layers and also redirect fluid flow when within the fluid directing body. The contact deposition seal can be adapted to contact a deposition surface and deliver fluid thereto, and can define a first flow chamber and a second flow chamber. The first flow chamber can be fluidly coupled to adjacent terminating ends of the first pair of microfluidic channels forming a first flow cell. The second flow chamber can be fluidly coupled to adjacent terminating ends of the second pair of microfluidic channels forming a second flow cell.

A method of exchanging fluids with suspended particles includes providing a microfluidic device with a first inlet channel operatively coupled to a source of particles and a second inlet channel operatively coupled to an exchange fluid. A transfer channel is connected at a proximal end to the first inlet channel and the second inlet channel. First and second outlet channels are connected to a distal end of the transfer channel. The source of particles is flowed at a first flow rate into the first inlet channel while the exchange fluid is flowed at a second flow rate into the second inlet channel wherein the ratio of the second flow rate to the first flow rate is at least 1.5. Particles are collected in one of the first and second outlet channels while fluid substantially free of particles is collected in the other of the first and second outlet channels.

A fluid handling device has fluidic structures having inlet and outlet chambers and a connecting duct fluidically connecting the two. In a first state, the inlet chamber is completely or partly filled with at least a liquid and partly filled with a compressible medium, and the outlet chamber is at least partly filled with the compressible medium. One of the inlet chamber and the outlet chamber has such a venting duct that a flow resistance/volume product of venting of the chamber for the compressible medium amounts to at least 6700 N.Math.s/m.sup.2, the other of the inlet chamber and of the outlet chamber being vented. An actuator for actuating the fluidic structures is to cause a pressure difference of at least 30 Pa between the compressible media within the inlet and outlet chambers, so as to thereby switch a valve device implemented into the connecting duct.