Disclosed in the present invention are a monoclonal antibody (YWHG-4) against HLA-G isoforms (HLA-G1, HLA-G4, HLA-G5) and use thereof. The antibody (YWHG-4) is produced by the hybridoma deposited under CCTCC NO: 2021204, and an antigenic peptide (RGYYNQSEASSHTLQWMIGC) of amino acid sequences at positions 106-126 of a heavy chain of HLA-G molecules is used as an immunogen. Provided in the present invention are a nucleotide encoding the YWHG-4 antibody of the present invention and an encoded amino acid sequence thereof. Further provided in the present invention is use of the YWHG-4 antibody in the detection of the HLA-G isoforms (HLA-G1, HLA-G4, HLA-G5) by means of immunoblotting, immunohistochemistry, ELISA and flow cytometry.

Provided are novel methods for screening and testing for pathogens in food, water, and bodily fluids using methods that are faster to complete than conventional methods of culturing and plating that require lengthy times in properly equipped labs. The invention utilizes specific, rapid and sensitive optical detection to capture small concentrations of the target bacteria and render them amenable for detection with various specific synthesis binding agents approaches. The technique merges capture and detection steps with quantification unit suitable to provide results in a relatively shorter time current detection methods.

Provided are novel methods for screening and testing for pathogens in food, water, and bodily fluids using methods that are faster to complete than conventional methods of culturing and plating that require lengthy times in properly equipped labs. The invention utilizes specific, rapid and sensitive optical detection to capture small concentrations of the target bacteria and render them amenable for detection with various specific synthesis binding agents approaches. The technique merges capture and detection steps with quantification unit suitable to provide results in a relatively shorter time current detection methods.

The present invention provides compositions, kits, and methods for the detection of host cell proteins (HCPs) in biological samples. In some embodiments, the present invention utilizes immunization of aves hosts with proteins derived from non-aves host cells to produce aves antibodies specific for non-aves HCPs.

The present invention provides compositions, kits, and methods for the detection of host cell proteins (HCPs) in biological samples. In some embodiments, the present invention utilizes immunization of aves hosts with proteins derived from non-aves host cells to produce aves antibodies specific for non-aves HCPs.

A reagent combination, kit, system, and method for detecting a target protein are disclosed. In a case that a target protein is contained in the solution to be detected, a first antibody and a second antibody are used to form a double-antibody sandwich structure with the target protein. Through the complementary pairing between multiple single stranded DNAs, the donor fluorescent molecules excite the acceptor fluorescent molecules to emit fluorescence, so as to calculate the content of the target protein. The detection method in the present disclosure is simple, has little background interference, high sensitivity and small measurement error.

A reagent combination, kit, system, and method for detecting a target protein are disclosed. In a case that a target protein is contained in the solution to be detected, a first antibody and a second antibody are used to form a double-antibody sandwich structure with the target protein. Through the complementary pairing between multiple single stranded DNAs, the donor fluorescent molecules excite the acceptor fluorescent molecules to emit fluorescence, so as to calculate the content of the target protein. The detection method in the present disclosure is simple, has little background interference, high sensitivity and small measurement error.

Methods for detecting colorectal cancer or precancerous conditions such as adenomatous polyps in a subject by detection of a galactose-containing 40-kDa molecule in a serum sample from the subject are provided. Methods for quantifying the amount of a galactose-containing molecule in a serum sample are also provided. The methods can further comprise assaying the sample for the quantity of at least one additional marker to confirm the detection or diagnosis of colorectal cancer using one or more additional quantitative immune-detection assays; the additional marker can be at least one of galectin-3, a peptide derived from galectin-3, carcinoembryonic antigen (CEA), and CYFRA21-1.

Methods for detecting colorectal cancer or precancerous conditions such as adenomatous polyps in a subject by detection of a galactose-containing 40-kDa molecule in a serum sample from the subject are provided. Methods for quantifying the amount of a galactose-containing molecule in a serum sample are also provided. The methods can further comprise assaying the sample for the quantity of at least one additional marker to confirm the detection or diagnosis of colorectal cancer using one or more additional quantitative immune-detection assays; the additional marker can be at least one of galectin-3, a peptide derived from galectin-3, carcinoembryonic antigen (CEA), and CYFRA21-1.