A method for measuring the presence of calprotectin (S100A8/A) heterodimer in a biological sample using a particle-enhanced turbidimetric immunoassay (PETIA) based on monoclonal antibodies. The method can be adapted on automated standard analyzers and provides a reliable clinical measurement of calprotectin in faecal samples and extracts. The method is comparable to commerical two-site sandwich ELISA. The disclosed method counters spontaneous agglutination caused by calcium ions and low-molecular weight calcium-binding S100 proteins as observed with conventional PETIAs. The method can be used for measuring the presence of human calprotectin in stool, urine, serum, plasma, synovial liquid and other body liquids. Metrological traceability and high commutability with conventional immunoassays (ELISA) has been shown despite of different measurement principles used.

A multiplexed sample plate comprising a sample well is disclosed. A plurality of substantially cylindrical reagent bead 2500 are inserted in use within a hole or aperture of the sample well. The substantially cylindrical reagent beads are positioned so as not to protrude beyond an upper surface of the base portion.

The present invention relates to the field of pulmonary arterial hypertension. More specifically, the present invention provides methods and compositions useful in assessing Insulin-Like Growth Factor (IGF) axis proteins. In one embodiment, a method comprises the steps of (a) detecting an increased level of IGFBP2 relative to a control in a sample obtained from a subject suspected of having PAH; and (b) treating the subject with a PAH therapy.

A detection method of multiple analytes includes the following. A microparticle is provided. The microparticle is coupled with at least one first ligand, and includes a body and a plurality of first protrusions formed on a surface of the body. Next, the microparticle is mixed with a variety of analytes to form a first complex. Thereafter, the first complex is mixed with a variety of second ligands carrying a variety of first labels, such that the variety of second ligands bind to the variety of analytes in the first complex and form a second complex. Lastly, the variety of first labels in the variety of second ligands in the second complex are detected.

Described herein are materials and kits for associating species with a surface of an object. In some embodiments, the object comprises a plurality of capture objects (e.g., beads).

The present invention intends to provide an immunochromatographic test piece that makes it possible to achieve both highly sensitive detection of a substance to be detected and a simple test piece structure, which are usually difficult to be made compatible with each other. The immunochromatographic test piece is an immunochromatographic test piece comprising a membrane on which a capture substance being a ligand that bonds to a substance to be detected is immobilized, wherein insoluble carrier particles to which a ligand that bonds to the substance to be detected is bound are used and accumulated by being captured with the capture substance immobilized on the membrane, the membrane is irradiated with light to detect light emitted from a portion where the insoluble carrier particles are accumulated or light emitted from a portion surrounding and other than the portion where the insoluble carrier particles are accumulated, thereby measuring the substance to be detected, and a light-reflecting material is provided on a side of the membrane opposite to a side irradiated with light.

The present application relates to detection units and methods for detecting one or more target analytes in a sample using a complex formed by a target and first and second probes, wherein the first probe is coupled to a detectable piece, the target is coupled to the first probe and the second probe, and the second probe is coupled to a solid support. Specific binding of the detectable piece to the target analyte can be distinguished from non-specific binding of the detectable piece by measuring the number of detectable pieces that leave their initial location after exposure to a disruptor that uncouples the detectable piece from the solid support.

An immunochromatography including steps of mixing an antigen-containable specimen and modified magnetic particles, which are magnetic particles modified with a monoclonal antibody X; collecting the magnetic particles from the mixture using magnetism; dissociating the modified magnetic particles to obtain an antigen-containing solution; neutralizing the antigen-containing solution to obtaina neutralized antigen-containing solution; spreading gold particle composite bodies on an insoluble carrier having a reaction site at which a monoclonal antibody Z has been immobilized, wherein the gold particle composite body is a composite body of the antigen and a modified gold particle which is a gold particle modified with a monoclonal antibody Y; capturing the gold particle composite bodies at the reaction site; and silver-amplifying the gold particle composite body, in which the antibody X and the antibody Y are different from each other, and the antibody X and the antibody Z are different from each other.

An immunochromatography including steps of mixing an antigen-containable specimen and modified magnetic particles, which are magnetic particles modified with a substance having a specific affinity to the antigen; collecting the magnetic particles using magnetism; dissociating the modified magnetic particles to obtain an antigen-concentrated solution by mixing the collected magnetic particles with a dissociation solution, an amount of which is smaller than the antigen-containable specimen; obtaining a neutralized antigen-concentrated solution; spreading gold particle composite bodies on an insoluble carrier having a reaction site at which a second binding substance has been immobilized, in a state where the gold particle composite bodies which are composite bodies of an antigen in the neutralized antigen-concentrated solution and modified gold particles which are gold particles modified with a first binding substance are formed; capturing the gold particle composite bodies at the reaction site; and silver-amplifying the gold particle composite body.

A digitally encoded microflake includes a polymer layer, which has a top surface and a bottom surface substantially parallel to the top surface. At least one of the top surface and the bottom surface is to be coupled to target-specific probes for bonding with a target analyte. The microflake is identified by a binary sequence of bits encoded by an edge outline on a plane substantially parallel to the top surface and the bottom surface. The bits in the binary sequence are encoded at respective predefined locations surrounding the edge outline.