A reaction processor includes: a reaction processing vessel including a channel in which a sample moves and a pair of air communication ports, a first air communication port and a second air communication port, provided at respective ends of the channel; a temperature control system that provides a medium temperature region and a high temperature region between the first air communication port and the second air communication port in the channel; and a liquid feeding system that discharges and sucks air in order to move and stop the sample inside the channel. One of the pair of air communication ports of the reaction processing vessel that is farther away from the high temperature region communicates with the liquid feeding system via a tube. One of the pair of air communication ports of the reaction processing vessel that is closer to the high temperature region is opened to atmospheric pressure.

A method herein to isolate exosomes includes providing a microfluidic device having a spiral-shaped channel in fluid communication with two inlet ports and at least two outlet ports. One of the two inlet ports is proximal to an inner wall of the spiral-shaped channel and the other is proximal to an outer wall thereof. At least one of the outlet ports is in fluid communication with a container for storing isolated exosomes. A blood sample and sheath fluid are introduced into the inlet ports proximal to the outer and inner walls, respectively, to form a diluted sample in the spiral-shaped channel and driven through for exosomes recovery in the container. The spiral-shaped channel in fluid communication with a first outlet port includes a first outlet channel connecting the spiral-shaped channel to the first outlet port and is longer than other outlet channels respectively connecting the spiral-shaped channel to the other outlet ports. A method of identifying diabetes mellitus is also disclosed herein.

A device for isolating a biological material from a sample includes a housing, a slider and a dry reagent capsule. The housing defines a plurality of compartments and a plurality of fluid channels. Each compartment is configured to be fluidically connected to a respective fluid channel, and each fluid channel includes a respective end terminating at a track disposed on the housing. The slider is movable along the track and includes a plurality of connecting channels extending therethrough. A selected one of the connecting channels is configured to connect ends of selected ones of the fluid channels based on a position of the slider along the track. The dry reagent capsule is configured to be mounted to the housing, and includes at least one dry reagent for mixing with the sample. The dry reagent capsule is further configured to be fluidically connected to a respective fluid channel in-situ.

An array platform for three-dimensional cell culturing and drug testing and screening is disclosed. In the array platform, a hydrogel-cell mixture injection area is configured to inject a plurality of kinds of hydrogel-cell mixtures. Cell observation areas are connected to the hydrogel-cell mixture injection area. Electrodes are disposed under the cell observation areas and automatic cell quantification and three-dimensional cell co-arrangement of the plurality of kinds of hydrogel-cell mixtures in the cell observation areas through the electrodes to imitate a structure of body's tissues. A drug injection area is configured to inject a plurality of kinds of drugs. Drug combination generators respectively correspond to the cell observation areas and are connected to the drug injection area. Each drug combination generator has a microfluidic channel structure and configured to generate drug combinations according to the plurality of kinds of drugs.

A method for detecting an analyte reactive towards luminol, comprising the steps of: feeding into a reaction chamber an alkaline solution of luminol, noble metal nanoparticles and at least one analyte reactive towards luminol, wherein the reaction chamber is in the form of a curved channel; detecting the light emitted due to a chemiluminescence reaction taking place in said channel; and discharging a reaction mass from said channel, characterized in that the average diameter of the metal nanoparticles is greater than 25 nm. Also provided is a microfluidic device for carrying out the method.

Embodiments of the invention provide a microfluidic chip having microfluidic structures formed on a surface. The structures form an input channel, an output channel, auxiliary channels, and a hydraulic resistor structure connecting the input channel to the output channel via the auxiliary channels. The resistor structure includes N flow resistor portions (N≥2), which are connected to the auxiliary channels. The chip further includes at least N−1 actuatable valves, which are arranged in respective ones of the auxiliary channels. The actuation state of the valves can determine the effective hydraulic resistance of the resistor structure. The valves can be electrogates, each including a liquid-pinning trench arranged in a respective one of the auxiliary channels that define a flow path for a liquid introduced therein, so as to form an opening that extends across said flow path. Each electrogate can further include an electrode extending across the flow path.

An analysis cartridge includes a first cover, a second cover, a plurality of containers, a plurality of fluid tunnels and a rotary valve. The second cover has two opposite surfaces, a plurality of first through holes and a second through hole individually penetrate through the two opposite surfaces, and the first cover is attached to the second cover. The plurality of containers are disposed between the first cover and the second cover, with each of the containers being aligned to and filled in the first through holes. The plurality of the fluid tunnels are disposed on the first cover, and each of which is individually connected with a first pipette. The rotary valve is rotatably disposed between the first cover and the second cover to correspond to the second through hole, and a flow channel disposed on the rotary valve is connected with the containers individually.

The present invention is directed to systems and devices that allow for separation of cells based on size and electric properties and for high-throughput cell sorting. The system may comprise a microfluidic platform having a main microfluidic channel and cavity acoustic transducers (CATs). The microfluidic platform may be coupled to an external acoustic source. The system may further comprise a fluid disposed through the main microfluidic channel comprising cells having different sizes and electric properties. The fluid may intersect the CATs to form one or more interfaces. The system may further comprise electrodes underneath the microfluidic platform. The CATs may oscillate the interfaces to produce one or more microstreaming vortices, such that each microstreaming vortex is capable of selectively trapping cells based on size. The set of electrodes may apply an AC to cause the cells to move relative to the set of electrodes based on electric properties.

The present disclosure is related to a method of producing a microfluidic sorting apparatus. The method includes providing an injection-molded substrate comprising a network of channels; bonding an insulating film to an upper surface of the substrate to cover the network of channels; and depositing a conductive film on the insulating film. The substrate can be separated from the conductive film.

Provided is a digital microfluidic device for quick polymerase chain reaction. The digital microfluidic device includes an enclosed chamber for holding droplets comprising PCR mixtures. The chamber has an upper layer and a lower layer, which provide a top heater and a bottom heater contained in a thermal electrode respectively to form dual heaters. The lower layer further has an array of electrodes and a dielectric layer, e.g. Norland Optical adhesive 61, coating thereon. Such arrangement of the digital microfluidic device allows quick and homogeneous heating of droplets to lower the heating voltage, shorten the reaction time, and prevent the dielectric layer from breakdown during the thermal cycle.