A flow control system for a microfluidic device includes: a plurality of fluid flow controllers, each fluid flow controller associated with a respective microfluidic device inlet of the microfluidic device, and wherein each fluid flow controller includes: a controller inlet for receiving a fluid flow, a first fluid channel and a second fluid channel, each of the first and the second fluid channels having a first end connected to the controller inlet and a second end connected to a supply channel, and a valve for selecting the fluid flow to be passed from the controller inlet to the first fluid channel or to the second fluid channel, wherein the first fluid channel has a first flow resistance that smaller than a second flow resistance of the second fluid channel.

Methods for laser-assisted repositioning of a micro-object and for culturing an attachment-dependent biological cell within a microfluidic device are described herein. Laser illumination is used to controllably create a bubble which repositions the micro-object. Further, methods of culturing an attachment-dependent biological cell are described, where the methods may include laser-assisted repositioning.

Devices and methods for the detection of analytes are disclosed. Devices and methods for detecting food-borne pathogens are disclosed.

We describe a method comprising: providing a droplet comprising a plurality of constituents, splitting said droplet into a first droplet and a second droplet, wherein said first droplet comprises a first fraction of said plurality of constituents and said second droplet comprises a second fraction of said plurality of constituents, analysing said constituents of said first fraction of said plurality of constituents in said first droplet, and sorting said second droplet dependent on an outcome of said analysis.

A multiplex PCR chip capable of simultaneously detecting multiple target genes and a multiplex PCR method using the same are proposed. More specifically, in the multiplex PCR chip and multiplex PCR method, after a plurality of spatially separated particle-forming grooves is formed in one or more reaction chambers and a probe in a solution state is injected into the particle-forming grooves, planar shapes of the particle-forming grooves are varied or shapes and patterns of particle holders respectively formed on inner surfaces of the particle-forming grooves are varied, and the probe including primers specifically hybridizing with sequences of different nucleic acid molecules is injected into the particle-forming grooves, whereby simultaneous multiplex detection is possible by allowing multiple target genes to be detected on the basis of positions and shapes of the probe particles and the shapes and patterns of the particle holders respectively formed inside of the probe particles.

Methods and systems for isolating platelet-associated nucleated target cells, e.g., such as circulating epithelial cells, circulating tumor cells (CTCs), circulating endothelial cells (CECs), circulating stem cells (CSCs), neutrophils, and macrophages, from sample fluids, e.g., biological fluids, such as blood, bone marrow, plural effusions, and ascites fluid, are described. The methods include obtaining a cell capture chamber including a plurality of binding moieties bound to one or more walls of the chamber, wherein the binding moieties specifically bind to platelets; flowing the sample fluid through the cell capture chamber under conditions that allow the binding moieties to bind to any platelet-associated nucleated target cells in the sample to form complexes; and separating and collecting platelet-associated nucleated target cells from the complexes.

A gene amplification chip may include a substrate; a through-hole array including through-holes that extend from an upper surface of the substrate to a lower surface of the substrate and in which a gene amplification reaction occurs; and a photothermal film provided on at least one of the upper surface and the lower surface of the substrate and configured to generate heat using light.

A device includes a collimated light source operable to generate a collimated light source beam, which includes a beam direction. The device includes a first channel in a first plane and a second channel in a second plane different from the first plane. The second channel communicates with the first channel and includes a flow direction. The second channel is oriented to receive the collimated light source beam. The device includes a third channel in a third plane different from the second plane and communicates with the second channel. The collimated light source beam is oriented to enter a cross-section of the first channel, then to pass through the second channel, and then to enter a cross-section of the third channel such that the beam direction is opposite to the flow direction in the second channel. The device includes a focused particle stream nozzle operably connected to the first channel.

The present invention relates to a microfluidic mixer and a microfluidic device including the same, and in the microfluidic mixer according to the present invention, a disk-shaped mixing unit with double U-shaped protruding portions formed therein can be continuously provided along a microchannel, thereby increasing collisions of samples to improve the binding efficiency thereof and shorten the binding time. Furthermore, the microfluidic device according to the present invention can detect a target material at high speed even at a high flow rate by including the microfluidic mixer, and thus can be usefully utilized for early diagnosis and prognosis diagnosis of a disease such as cancer.

A multi-channel bio-separation system configured to utilize a cartridge that has a individual, separate integrated reagent (i.e., a separation buffer) reservoir dedicated for each separation channel. The multiple channels may have different characteristics, such as different separation medium of different chemistries, different separation length, different channel sizes and internal coatings. In one embodiment, the cartridge does not include integrated detection optics. Not all channels need to be operative. One or more of the channels in the cartridge may be “dummy channels” that are not operative (e.g., not provided with a capillary tube). A capillary tube may be routed between the reservoir/electrode (anode) of one channel to an electrode (cathode) in another channel, thus allowing a longer length of capillary tube to be used to define a longer separation channel to improve resolution.