The present invention discloses a kind of centrifugal detection channel, including: a first chamber, at least one inlet channel, at least one buffer valve, at least one outlet channel, and a second chamber. Specifically, at least one inlet channel is connected to the first chamber. At least one buffer valve is connected to the inlet channel, including: a valve body and a transient chamber. At least one outlet channel is connected to the buffer valve. At least one second chamber is connected to the outlet channel. In addition, the detection devices and the detection methods comprising the centrifugal detection channel have also been proposed.

An example micro-fluidic device includes a micro-fluidic channel having an inner surface and a plurality of pillars positioned along the inner surface. The device further includes a plurality of power supplies connected to the pillars. Another example micro-fluidic device includes a micro-fluidic channel having an inner surface and a plurality of pillars positioned along the inner surface. The device further includes a power supply. The pillars are grouped into at least two groups of pillars, each group of pillars including at least two pillars, and all pillars of at least one group of pillars are connected to the power supply. In another example, a sensing system for detecting bioparticles includes a micro-fluidic device, wherein a surface of each pillar comprises functionalized plasmonic nanoparticles or functionalized SERS nanoparticles, a radiation source for radiating the micro-fluidic device, and a detector for detecting SERS signals or surface plasmon resonance.

Devices and methods for analyzing a sample are disclosed. In various embodiments, the present disclosure provides devices and methods for preparing a serial dilution of a sample. In various embodiments, the present disclosure provides devices and methods for preparing a serial dilution of a sample and conducting sample analysis. In various embodiments, the present disclosure provides a cartridge device and a reader instrument device. The reader instrument device receives, operates, and/or actuates the cartridge device to prepare a serial dilution of a sample and conduct sample analysis.

The present application relates to biosensors and methods for detecting and/or quantifying a target analyte such as a target allergen or toxin. In some embodiments, the biosensors use an allergen- or toxin-binding molecule conjugated to a fluorescent label such as a quantum dot that adheres to and is quenched by graphene oxide in the absence of the allergen or toxin.

Accordingly, in some embodiments of the disclosure, a multi-chambered assay device is provided, which is configured for arrangement on a disc, as well as configured to process an individual sample. A plurality of such assay devices can be arranged along a periphery of the disc at a distance/radius from the center, such that a plurality of individual samples can be processed, e.g., one per assay device. In addition, in an arrangement that a plurality of assay devices are used, they can be spaced apart such that they balance the disc during rotation (which can be with samples contained in one or more of the assay devices, a plurality, a majority, or all of the assay devices).

A spatially selective surface functionalization device configured to generate a pattern of micro plasmas and functionalize a substrate surface may include: a pattern management system, a patterning head, and a gas delivery system, wherein the gas delivery system provides a primed gas mixture for forming a plasma between the patterning head and a target substrate below the patterning head. A patterning head may generate a distribution of micro plasmas from individual directed beams of electrons with spatial separation. A pattern management system may store and manipulate information about a pattern of surface functionalization and generate instructions for regulating a distribution of micro plasmas that functionalize a substrate surface.

The present invention relates to sample-to-answer systems, devices, cartridges, and method of using the same for detecting the presence of microorganisms in a sample, such as bacteria.

A capillary chamber for performing chemical and physical analysis using a plurality of whole blood samples is presented. Following a loading of the whole blood samples into a plastic tube, the whole blood samples are distributed into a collection chamber and the capillary chamber has means of adding respective vaccines or similar biological products into each capillary tubes. The whole blood is then analyzed using standard microscopic techniques with sufficient resolution and contrast to record the chemical and physical properties of the blood immediately after withdrawal.

A liquid handling device has an accommodation part for accommodating a liquid, two or more flow paths each opening to a lower part of a side wall surface of the accommodation part, and a liquid movement suppression part that is disposed in the lower part of the side wall between the openings of two of the flow paths that are adjacent to each other and slows or stops the movement of the liquid along the corner formed by the lower surface of the accommodation part and the side wall surface.

The method is for preparing a sample in a microfluidic device. A microfluidic device is provided that has a first reservoir in fluid communication with a second reservoir in fluid communication with and adjacent to a draining unit that has a first absorbing member disposed therein. The first reservoir contains a first liquid that is held in the first reservoir by a capillary stop valve connecting the first and second reservoirs. The second reservoir has a sample support disposed therein. A second liquid, containing substances, is added to the second reservoir. The second liquid contacts the first liquid and the first absorbing member. The first absorbing member absorbs the second liquid and the first liquid. The substances adhere to the sample support.