Single-use diagnostic consumables for use in performing multiple analyses on a fluid sample are provided. The diagnostic consumables include a first sensing region configured for analysis of at least one analyte in a fluid sample that has been received by the diagnostic consumable. The diagnostic consumable further includes a fluid transport material configured to flow a portion of the fluid sample into a second sensing region fluidically connected to the fluid transport material and configured for performing a second analysis of the fluid sample. Methods for performing multiple analyses of a fluid sample on a single-use diagnostic consumable are also provided.

Described herein are microfluidic devices and methods that can greatly improve cell quality, streamline workflows, and lower costs. Applications include research and clinical diagnostics in cancer, infectious disease, and inflammatory disease, among other disease areas.

Devices and methods for measuring analytes and target particles in a sample are disclosed. In some embodiments, the disclosure provides a cartridge device. In other embodiments, the disclosure provides a method of using a cartridge device as disclosed herein for analyzing analytes and target particles in a sample. In further embodiments, the disclosure provides an analyzer including a cartridge device and a control unit device. The control unit device is configured to receive, operate, and/or actuate the cartridge device. In some embodiments, the disclosure provides a method of using an analyzer as disclosed herein for analyzing analytes and target particles in a sample.

The present invention relates to a microfluidic system (10, 20) comprising: a sample reservoir (110, 210); a first sample channel (120, 220) connected to the sample reservoir (110, 210), branching off into a second sample channel (122, 222) ending in a first valve (130, 230), and into a third sample channel (124, 224) which branches off into a fourth sample channel (126, 226) ending in a second valve (132, 232), and into a fifth sample channel (128, 228) ending in a third valve (134, 234); a buffer reservoir (140, 240); a first trigger channel (150, 250) arranged to connect the buffer reservoir (140, 240) to the second valve (132, 232); a second trigger channel (152, 252) connecting the second valve (132, 232) and the first valve (130, 230); and an exit channel (154, 254) connected to the first valve (130, 230).

The application relates to microfluidic apparatus and methods of use thereof. Provided in one example is a microfluidic device comprising: a first fluidic input and a second fluidic input; and a fluidic intersection channel to receive fluid from the first fluidic input and the second fluidic input, wherein the fluidic intersection channel opens into a first mixing chamber on an upper region of a first side of the first mixing chamber, wherein the first mixing chamber has a length, a width, and a depth, wherein the depth is greater than about 1.5 times a depth of the fluidic intersection channel; an outlet channel on an upper region of a second side of the first mixing chamber, wherein the outlet channel has a depth that is less than the depth of the first mixing chamber, and wherein an opening of the outlet channel is offset along a width of the second side of the first mixing chamber relative to the fluidic intersection.

Provided are a method and a device for encapsulating a cell in droplet for single-cell analysis, or a method and a device for forming droplet for single-cell analysis. According to the method and the device of one aspect, by using the effects of inertial ordering, not only a ratio at which one cell is encapsulated in one droplet is increased, but also a yield of generating droplet is improved.

Some embodiments of the disclosure disclose manifolds, microfluidic systems and methods that provide control over fluid flow distribution to an array of bio-scaffolds contained within the manifolds. In some embodiments, multiple perfusates may be injected into the manifold via multiple inlets where the manifold contains a bio-assembly with a substrate having a bio-scaffold disposed thereon. Biological investigations of the perfusates may then be conducted in the vascular components and chambers of the bio-scaffold.

Microchannels include membranes operable with magnets or other actuators to deliver samples to one or more reaction zones defined in the microchannels. Membrane flexing can direct samples to selected reaction zones and each reaction zone can be independently temperature controlled to implement a PCR-based sample analysis.

Method of analysis. In the method, a first emulsion and a second emulsion substantially separated from one another by a spacer fluid may be formed. The first emulsion, the spacer fluid, and the second emulsion may be flowed in a channel from a fluid inlet to a fluid outlet of a heating and cooling station having two or more temperature-controlled zones, such that each emulsion is thermally cycled to promote amplification of a nucleic acid target in droplets of the emulsion. Amplification data may be collected from individual droplets of each emulsion downstream of the heating and cooling station. A level of the nucleic acid target present in each emulsion may be determined based on the amplification data collected from the individual droplets of the emulsion.

Nanofluidic flow cells and systems for single-molecule nanoconfinement and imaging of molecules in a fluid are described. The nanofluidic flow cell comprises a bottom substrate bonded to a top substrate, microchannels and a central chamber carved in the bottom or top substrate. The microchannels and the central chamber define an empty space into which a fluid can flow. The microchannels extend on opposite side of the central chamber, each microchannel comprising a central portion crossing the central chamber and a pair of arms extending outside the central chamber, these arms comprising a fluid port positioned at opposite ends of the microchannel and outside the central chamber. The central chamber comprises a nanoconfinement and imaging area including carved nanostructures configured for single-molecule nanoconfinement. Also described are nanofluidic chips, methods of confinement, pneumatic-based nanofluidic systems and manifold assembly for the nanofluidic flow cell.