A test strip including: a first site that's a detection site, where a first antibody specifically binding to the substance to be measured is immobilized on a porous carrier; a second site that's a specimen liquid addition site, where a second labeled antibody binding to the substance to be measured and having a recognition site different from that of the first antibody is retained on a porous carrier to be movable; and a third site that is a specimen liquid or developer addition site, where colored microparticles bound with a substance binding to a label substance of the second antibody are retained on a porous carrier to be movable, wherein the second site is provided between the first and the third sites, and the specimen liquid or developer can move, due to capillarity, from the second site to the first and from the third to the first site.

A time-resolved fluorescence immunochromatographic test paper card for testing clothianidin. A binding pad includes a detection microsphere and a quality control microsphere thereon, wherein the detection microsphere is a fluorescent microsphere coated with a clothianidin monoclonal antibody on the surface thereof, the quality control microsphere is a fluorescent microsphere coated with a rabbit anti-tag protein on the surface thereof. An NC film is provided with a detection line and a control line. The lengths of the detection line and the control line are the same as the width of the NC film. A first clamping part is arranged at one end of the sample pad. A second clamping part and a third clamping part are respectively arranged at two ends of the binding pad. A fourth clamping part is arranged at one end of the NC film, the other end of the NC film is joined with an absorption pad.

Provided herein are structures and methods for detecting one or more analyte molecules present in a sample. In some embodiments, the one or more analyte molecules are detected using one or more supramolecular structures. In some embodiments, the supramolecular structures are bi-stable, wherein the supramolecular structures shift from an unstable state to a stable state through interaction with one or more analyte molecules from the sample. In some embodiments, the stable state supramolecular structures are configured to provide a signal for analyte molecule detection and quantification.

The present disclosure provides methods and kits for detecting Group A Streptococcus in biological samples. More particularly, the present disclosure provides methods for enhancing the specificity and sensitivity of Group A Streptococcus immunoassays by including N-propionyl-D-glucosamine, 2-N-butanoyl-D-glucosamide, Bis-(2-(D-2-deoxy-glucosaminyl))-PEG3-amide, m-PEG4-glucosamine, m-PEG6-glucosamine, or m-PEG10-glucosamine. The methods and kits disclosed herein are thus useful for reliable and early diagnosis of streptococcal infections in a subject.

A portable device (1) for detecting and quantifying a concentration of a marker, for example TROPONIN I, present in a sample of biological fluid. The device (1) comprises a cartridge (100) adapted to receive the biological fluid sample and comprising at least one reactive agent configured to bind to the marker defining an electrochemiluminescent solution. The cartridge (100) is coupled to an electrode cell (101) configured to supply electrical energy to the electrochemiluminescent solution so as to trigger an electrochemiluminescence reaction of the electrochemiluminescent solution, generating a light signal representative of a concentration value of the marker in the biological fluid sample. The device (1) further comprises an analyzer (200), connectable to the cartridge (100) and configured to receive and analyze at least one property of the light signal so as to quantify a concentration of the marker in the biological fluid.

Methods of detecting a target in a sample are provided. Kits for performing the methods described herein are also provided.

Disclosed herein are integrated photonics systems (3800) for biosensing including an interrogator photonic circuit (3802) and cartridge (3804) and methods using these systems. The cartridge (3804) comprises a sensor photonic integrated subcircuit. The cartridge (3804) is configured to receive a biological sample. The interrogator photonic circuit (3802) is optically coupled to the cartridge (3804) an comprises: (i) a light source (3806) configured to generate light; and (ii) one or more waveguides configured to carry the light, wherein the light is used to determine a characteristic of the biological sample in the cartridge (3804). A system can have an assembly of a plurality of modular photonic integrated subcircuits. Each subcircuit can be pre-fabricated and can be configured to transfer light to and receive light from another subcircuit based on the first functionality. An output port of a first subset of the subcircuits can be configured to be aligned with an input port of a second subset of the subcircuits. At least one subcircuit can be configured to be removed from the first integrated photonics assembly and connected to a second integrated photonics assembly having a second functionality. The first integrated photonics assembly can be different from the second integrated photonics assembly and the first functionality can be different from the second functionality.

The present invention provides self-contained systems, apparatus and methods for determining a chemical state, the system includes a stationary cartridge for performing the assay therein, the cartridge adapted to house at least one reagent adapted to react with a sample; and at least one reporter functionality adapted to report a reaction of the at least one reagent with the sample to report a result of the assay, a mechanical controller including a first urging means adapted to apply a force externally onto the cartridge to release the at least one reagent; and at least one second urging means adapted to apply a removable force to induce fluidic movement in a first direction in the cartridge and upon removal of the force causing fluidic movement in an opposite direction to the first direction, an optical reader adapted to detect the reaction and a processor adapted to receive data from the optical reader and to process the data to determine said chemical state.

The invention is a nanowire-comprising device for detecting at least one target biomolecule. The nanowires are placed between a substrate and a multilayer structure. The multilayer structure lies between the nanowires and a sample liable to contain a target biomolecule. The multilayer structure comprises a functionalization surface making contact with the sample. When light is emitted from the functionalization surface, fluorescence light for example, at least one nanowire allows the light to be detected. The fluorescence light may indicate the presence or absence of a target biomolecule on the functionalization surface.

A method for performing an enzyme-linked immunosorbent assay (ELISA), the method comprising immobilizing a capture antibody to a substrate, wherein the capture antibody is configured to bind to a laminin beta-1 chain; adding a micronized tissue sample to the substrate containing the capture antibody; adding a detection antibody to the substrate containing the capture antibody and the micronized tissue sample, wherein the detection antibody is configured to bind to a laminin gamma-1 chain; detecting whether a complex of the capture antibody, a target antigen in the micronized tissue sample, and the detection antibody has been formed, wherein presence of the complex indicates presence of the target antigen with intact tertiary structure in the micronized tissue sample, and absence of the complex indicates absence of the target antigen with intact tertiary structure in the micronized tissue sample.