A nano-fluidic device includes: a first substrate that has a nanoscale groove on one surface; and a second substrate that is integrally provided with the first substrate by bonding one surface of the second substrate to the one surface of the first substrate and forms a nanochannel with the groove of the first substrate, in which either the first substrate or the second substrate includes at least a thin portion in a part of a position overlapping the nanochannel in plan view, and the thin portion is deformed by pressing to open and close the nanochannel.

A valve system for driving fluid and a method for using the same are provided. The valve system includes a fluid unit far away from the rotation center, a fluid unit close to the rotation center, a fluid transferring unit and a gas path pipeline for communicating the fluid unit close to the rotation center with the fluid unit far away from the rotation center. A rotation radius of a fluid outlet of the fluid unit far away from the rotation center is greater than that of a fluid inlet of the fluid unit close to the rotation center. The fluid outlet of the fluid unit far away from the rotation center is located at an end thereof away from the rotation center, and the fluid inlet of the fluid unit close to the rotation center is located at an end thereof close to the rotation center.

A microfluidic valve includes a carrier layer and a flexible membrane layer arranged on a surface of the carrier layer. The surface of the carrier layer has a valve chamber in the form of a spherical cap and a membrane formed by the flexible membrane layer covers at least the valve chamber. A plurality of microfluidic channels opening into the valve chamber are formed in the surface of the carrier layer. Moreover, an inflow channel and an outflow channel are connected to one another by a microfluidic connection channel. The connection channel and the valve chamber are positioned relative to each other in such a way that in the closed state of the membrane, a fluid can flow from the inflow channel via the connection channel into the outflow channel to bridge the valve chamber, while the at least one supply channel is closed by the membrane.

A system for testing for an analyte includes a test strip. The test strip includes a first flow path. The test strip further includes a heating element in communication with a heating area of the first flow path, for heating a sample in the first flow path. The test strip further includes an e-gate, the e-gate in the first flow path, the e-gate separating the heating area from a detection area of the first flow path.

The invention provides sample cartridges for processing samples. The sample cartridges comprise at least one fluidic channel. Each fluidic channel comprises a sample chamber, a lysis chamber, a binding chamber, a pre-amplification region, and an amplification region. The sample cartridges also comprise a waste line that is in fluidic connectivity with each fluidic channel. The sample cartridges can interface with a plurality of plungers that are capable of occluding at least one fluidic channel, waste line, and/or optional assay line to limit the transport of fluids into, out of, and/or along at least one fluidic channel by plunging. The invention also provides multi-channel sample cartridges, which are sample cartridges that comprise at least two fluidic channels. In addition, the sample cartridges can house fluids on the cartridge, off the cartridge, or some on the cartridge and some fluids off the cartridge.

Provided is an integrated microfluidic device for SARS-CoV-2 detection. Also provided is a method for detecting SARS-CoV-2 by using the same, comprising viral lysis, RNA extraction, and reverse-transcription loop-mediated isothermal amplification (RT-LAMP). The integrated microfluidic device of the present disclosure is small in size, automatically operatable, and easy to use by ordinary people, and the present disclosure can achieve rapid detection with high sensitivity and specificity.

A fluidic coupler to engage a plurality of flow cells of a sensor device includes a body and a plurality of fluidics interfaces formed in the body. Each fluidic interface of the plurality of fluidics interfaces includes an opening, a first port in fluid communication with the opening, a second port, and a third port in fluidic communication with the second port.

Function fabrication in a microfluidic device manufactured with a custom 3D printer. The functions may include, for example, transporting or routing fluid, fluid mixing through flow and/or diffusion, blocking fluid (valve), pumping fluid, providing chemical reaction regions, providing analyte capture regions, and providing analyte separation regions. The fluid may be a liquid or a gas.

A flow cell having at least one storage zone connected to a duct for conducting fluid out of, into or/and through the storage zone. The duct includes a duct section which is delimited by a substrate and a film joined to the substrate and in which the duct is sealed and can be opened at a predetermined breaking point by deflecting the film. The film covers a recess in the substrate which forms the duct section. A sealing wall that seals the duct and is integrally joined to the substrate is placed in the recess. The predetermined breaking point is formed by a breakable joining region between the film and an edge portion of the sealing wall facing the film. The dimensions of a peripheral area of the sealing wall is formed in the edge portion and runs parallel to the film determine the surface area of the joining region.

Among other things, the present invention is related to devices and methods of performing biological and chemical assays, particularly an easy sample manipulation and/or a rapid change or a rapid thermal cycling of a sample temperature is needed (e.g. Polymerase Chain Reaction (PCR) for amplifying nucleic acids).