Herein is reported a method for determining the binding of an antibody, which comprises a first binding site specifically binding to a first antigen and a second binding site specifically binding to a second antigen, to said first and said second antigen, wherein the method comprises the steps of capturing the antibody on a solid phase using a capture reagent specifically binding to a constant domain of the antibody, incubating the captured antibody with the first or the second antigen to form a captured antibody-antigen complex and determining a first binding signal, either i) incubating the captured antibody-antigen complex with the antigen not used for the formation of the captured antibody-antigen complex to form a captured antibody-antigen-antigen complex and determining a second binding signal, or ii) regenerating the surface, capturing the antibody on a solid phase using a capture reagent specifically binding to a constant domain of the antibody, incubating the captured antibody with the antigen not used for the formation of the captured antibody-antigen complex in step b) to form a captured antibody-antigen-antigen complex and determining a third binding signal, and determining the overall or individual binding of the antibody to the first and the second antigen from the first binding signal and the second or third binding signal.

A custom-made matrix suitable for receiving a tissue sample is described, as well as the use thereof to obtain a multiplex histological preparation. The disclosure also relates to a multiplex biopsy array comprising tissue and/or cell samples arranged in a matrix material and to a method for the preparation of a multiplex biopsy array. Methods for preparing blocks of matrix material to be used in multiplex biopsy arrays are also described, as well as methods for loading biopsy samples in the blocks, and methods for treating and processing the blocks to form biopsy arrays. The biopsy arrays made using the block of matrix material can be used to prepare sections and slides for histological procedures, including quantitative analyses and parallel processing.

The invention provides barcode libraries and methods of making and using them including obtaining a plurality of nucleic acid constructs in which each construct comprises a unique N-mer and a functional N-mer and segregating the constructs into a fluid compartments such that each compartment contains one or more copies of a unique construct. The invention further provides methods for digital PCR and for use of barcode libraries in digital PCR.

The present application discloses an electrochemiluminescence immunosensor. The immunosensor includes an electrode functionalized by a nanocomposite film. The film further includes carbon nanohorns dispersed in Nafion® perfluorinated resin solution. The polymeric solution is further stabilized by magnetic nanoparticles. The immunosensor is a Point of care (POC)-based. The immunosensor is configured to work in the range from 100 ng/mL to 1 fg/mL, and has tendency to detect even traces of the tropomyosin. The immunosensor is capable to detect traces even less than 1 fg/mL, hence having high specificity for Tro-Ag detection in food products with distinguished repeatability.

Corona Phase Molecular Recognition (CoPhMoRe) utilizing a template heteropolymer adsorbed onto and templated by a nanoparticle surface to recognize a specific target analyte can be used for macromolecular analytes, including proteins.

The present invention relates to the field of biological diagnosis in oncology. It relates to a method and apparatus for detecting and/or characterizing tumor cells by detecting one or more elements of the tumor cell secretome, in particular one or more peptides or proteins, and, in particular, one or more tumor markers. The invention also relates to detecting and/or characterizing droplets of tumor cells and their method of preparation.

Biosensing platform for simultaneous, multiplexed, high throughput and ultra-sensitive optical detection of biomarkers labelled with plasmonic nanoparticles, the platform being provided with a biosensor, a broadband and continuous spectrum illumination source, an optical detector for simultaneously capturing spatially resolved and spectrally resolved the scattering signal of each individual nanoparticle, an autofocus system and an optical system adapted to collect the scattered signal of the biosensor's surface onto the optical detector, the platform being provided with translation means for the optical system and/or the biosensor, such that the optical system and the biosensor can be displaced relative to each other in the three dimensions, and wherein the processing means are adapted to: i) simultaneously capture spatially and spectrally resolved scattering signals from each nanoparticle individually, and ii) to analyze these signals simultaneously with the capture process.

In a method for immunologically quantifying a steroid, it is possible to exclude a steroid from cyclodextrin when a standard solution containing the steroid included in cyclodextrin is treated with a surfactant, which thereby suppresses the deviation in behavior of the antigen-antibody reaction between the specimen (test sample) and the standard solution, and then significantly improves the accuracy of steroid quantification.

Embodiments of the present disclosure provide a target capturing apparatus and a manufacturing method thereof, and a target detecting method. The target capturing apparatus includes a cavity structure, the cavity structure includes: an inlet portion, an outlet portion and a capture region positioned between the inlet portion and the outlet portion, and the capture region includes a capture component, and a combination specifically combined with a to-be-captured target is included in the capture component so as to capture the target in a sample entering the cavity structure.

A custom-made matrix suitable for receiving a tissue sample is described, as well as the use thereof to obtain a multiplex histological preparation. The disclosure also relates to a multiplex biopsy array comprising tissue and/or cell samples arranged in a matrix material and to a method for the preparation of a multiplex biopsy array. Methods for preparing blocks of matrix material to be used in multiplex biopsy arrays are also described, as well as methods for loading biopsy samples in the blocks, and methods for treating and processing the blocks to form biopsy arrays. The biopsy arrays made using the block of matrix material can be used to prepare sections and slides for histological procedures, including quantitative analyses and parallel processing.