The present invention provides point-of-need diagnostic devices and kits for detecting a target nucleic acid sequence in a sample. Methods of using the point-of-need diagnostic devices or the kits disclosed are also provided.

Implementations of a method for seeding sequence libraries on a surface of a sequencing flow cell that allow for spatial segregation of the libraries on the surface are provided. The spatial segregation can be used to index sequence reads from individual sequencing libraries to increase efficiency of subsequent data analysis. In some examples, hydrogel beads containing encapsulated sequencing libraries are captured on a sequencing flow cell and degraded in the presence of a liquid diffusion barrier to allow for the spatial segregation and seeding of the sequencing libraries on the surface of the flow cell. Additionally, examples of systems, methods and compositions are provided relating to flow cell devices configured for nucleic acid library preparation and single cell sequencing. Some examples include flow cell devices having a hydrogel with genetic material disposed therein, and which is retained within the hydrogel during nucleic acid processing.

This present disclosure provides devices, systems, and methods for performing point-of-care analysis of a target analyte in a biological fluid via a binding assay. The present disclosure includes a cartridge for collecting the target analyte contained in a fluid sample and performing an assay. The cartridge includes an assay stack having a first separation layer, a second separation layer, and a detection membrane. The cartridge also includes a plurality of first complexes comprising a capture molecule and a magnetic bead and a plurality of second complexes comprising a detection molecule and a detection label. Further, the detection membrane includes a substrate that interacts with the detection label to elicit a quantifiable response in the presence of the target analyte. The quantifiable response corresponds to an amount of detection antibody present in the detection membrane, and the amount of detection antibody present corresponds to an amount of the target analyte present.

An integrated microfluidic chip and a single-cell culture, screening, and export method applying the same are disclosed; the chip includes a base, an inlet flow channel, an outlet flow channel, a plurality of common flow channels and a plurality of functional units, wherein two ends of the common flow channel are connected to the inlet flow channel and the outlet flow channel, respectively, wherein each of the functional units includes a single-cell introduction port, a cell culturing-screening chamber, a cell export chamber, a cell export port, and a drive element, wherein the drive element is used to provide power to liquid to introduce single cells entering the common flow channels into the cell culturing-screening chamber, and after culturing and screening, to export target cell population in the cell culturing-screening chamber through the cell export port.

A single junction sorter for a microfluidic particle sorter, the single-junction sorter comprising: an input channel, configured to receive a fluid containing particles; an output sort channel and an output waste channel, each connected to the input channel for receiving the fluid therefrom; a bubble generator, operable to selectively displace the fluid around a particle to be sorted and thereby to create a transient flow of the fluid in the input channel; and a vortex element, configured to cause a vortex in the transient flow in order to direct the particle to be sorted into the output sort channel.

A portable diagnostic device for performing the diagnosis of pathogens, such as viruses, bacteria, microorganisms, etc., by rapidly detecting their nucleic acids in a biological sample to be tested. Also, the use of the portable diagnostic device and the methods for detection of at least one nucleic acid sequence of interest implemented with the aid of the portable diagnostic device.

The presently disclosed subject matter provides dual-depth thermoplastic microfluidic devices, related kits, microfluidic systems comprising the dual-depth thermoplastic microfluidic device, methods of isolating nucleic acid analytes from a liquid sample, and methods of isolating extracellular vesicles from a liquid sample.

The present disclosure relates to a single cell analysis system. Disclosed herein is an instrument for single cell processing. The instrument comprises: a motor component; a processing component, which comprises a processing chamber inside and multiple first connecting holes; a container, which comprises a sample collecting reservoir, a waste collecting reservoir, multiple sample loading reservoirs, multiple first microchannels, and a second microchannel; a chip, which is connected under the container and forms a gap with the container, the chip comprises a third microchannel, the bottom of the third microchannel comprises a microwell array; a snap component comprises a feeding beam and a snap body, and a first end of the feeding beam connects to the snap body and a second end of the feeding beam connects to the motor component; and a pneumatic component which connects with the multiple first connecting holes.

Systems and techniques are described for capturing target extracellular vesicles from a fluid sample. In some implementations, a microfluidic device includes a microfluidic channel where an internal surface of at least one wall of the microfluidic channel includes a plurality of grooves or ridges, or both grooves and ridges, arranged and configured to generate chaotic mixing within a fluid sample flowing through the microfluidic channel. The microfluidic device also includes a plurality of elongate flexible linker molecules, each having a molecular weight between about 1.8-4.8 kDa, where each elongate flexible linker molecule is bound at a first end to an internal surface of at least one wall of the microfluidic channel and is bound at a second end to one or more binding moieties that specifically bind to a target extracellular vesicle.

A fluid device composite member includes: a silicone member that includes a body part which is made of silicone and which has a flow-path-defining section for defining a flow path on one surface of the body part, and that includes barrier layer having hydrophilicity or hydrophobicity disposed in at least a portion of the flow-path-defining section; and a resin substrate disposed on another surface of the body part opposite to the one surface. This method for manufacturing the fluid device composite member includes a layered body manufacturing step in which a liquid silicone material is placed on a surface of the resin substrate, and the liquid silicone material is cured at a temperature of 100° C. or less to obtain a layered body in which a silicone cured product is bonded to the resin substrate.