The present invention relates to novel antibody frameworks with advantageous properties.

An immunochromatography test strip for detecting pollution of diacetoxyscirpenol includes a bottom plate, where a water absorption pad, a detection pad, a gold-labeled pad and a sample pad are sequentially attached to one side of the bottom plate from top to bottom, adjacent pads are connected in an overlapping manner at a joint, the detection pad uses a nitrocellulose membrane as a base pad, a quality control line and a detection line are transversely arranged on the nitrocellulose membrane, the quality control line is coated with a rabbit antimouse polyclonal antibody, the detection line is located below the quality control line, and the detection line is coated with a diacetoxyscirpenol-ovalbumin conjugate; the gold-labeled pad is transversely spray-coated with a nanogold-labeled anti-diacetoxyscirpenol monoclonal antibody; and the anti-diacetoxyscirpenol monoclonal antibody is secreted by a hybridoma cell strain DAS5G11E7 with the preservation number of CCTCC NO.C201881.

An immunochromatography test strip for detecting pollution of diacetoxyscirpenol includes a bottom plate, where a water absorption pad, a detection pad, a gold-labeled pad and a sample pad are sequentially attached to one side of the bottom plate from top to bottom, adjacent pads are connected in an overlapping manner at a joint, the detection pad uses a nitrocellulose membrane as a base pad, a quality control line and a detection line are transversely arranged on the nitrocellulose membrane, the quality control line is coated with a rabbit antimouse polyclonal antibody, the detection line is located below the quality control line, and the detection line is coated with a diacetoxyscirpenol-ovalbumin conjugate; the gold-labeled pad is transversely spray-coated with a nanogold-labeled anti-diacetoxyscirpenol monoclonal antibody; and the anti-diacetoxyscirpenol monoclonal antibody is secreted by a hybridoma cell strain DAS5G11E7 with the preservation number of CCTCC NO.C201881.

Disclosed are compositions and methods for the multiplexed analysis of one or more intracellular targets of a single cell. Exemplary compositions of the disclosure comprise a surface comprising a plurality of capture agents operatively-linked thereto, wherein each capture agent specifically binds to a distinct intracellular target and wherein the plurality of capture agents form a repeating pattern; a substrate comprising a plurality of chambers, wherein the substrate releasably couples with the surface and wherein each chamber of the plurality of chambers comprises at least one repeat of the repeating pattern of the plurality of capture agents of the surface; a coating composition comprising a cell lysis composition; and a linker composition comprising a functionalization component and an extension component.

Disclosed are compositions and methods for the multiplexed analysis of one or more intracellular targets of a single cell. Exemplary compositions of the disclosure comprise a surface comprising a plurality of capture agents operatively-linked thereto, wherein each capture agent specifically binds to a distinct intracellular target and wherein the plurality of capture agents form a repeating pattern; a substrate comprising a plurality of chambers, wherein the substrate releasably couples with the surface and wherein each chamber of the plurality of chambers comprises at least one repeat of the repeating pattern of the plurality of capture agents of the surface; a coating composition comprising a cell lysis composition; and a linker composition comprising a functionalization component and an extension component.

The present disclosure provides an automatic test card for a multi-blood group system and a test method. The test card of a multi-blood group system includes four parts from top to bottom: a sample loading layer, a reaction layer, a color developing layer, and an identification layer. The automatic test card for a multi-blood group system and the test method combines blood group detection with encoding, and can rapidly and automatically identify and test multiple blood groups, reduce manual judgment errors, and improve detection efficiency. The method does not require special equipment and achieves rapid, accurate, automated, and portable detection of the blood groups.

The present disclosure provides an automatic test card for a multi-blood group system and a test method. The test card of a multi-blood group system includes four parts from top to bottom: a sample loading layer, a reaction layer, a color developing layer, and an identification layer. The automatic test card for a multi-blood group system and the test method combines blood group detection with encoding, and can rapidly and automatically identify and test multiple blood groups, reduce manual judgment errors, and improve detection efficiency. The method does not require special equipment and achieves rapid, accurate, automated, and portable detection of the blood groups.

The invention provides an oriented and covalent method for immobilizing a glycoprotein and an antibody on a chip. The method includes providing a silver-coated solid surface equipped with alkynes and cuprous oxide nanoparticles. The azido boronic acid tosyl probe is conjugated to the silver-coated solid surface by the cuprous oxide nanoparticles through the self-catalyzed azide-alkyne cycloaddition reaction. The glycan(s) of a glycoprotein or an antibody is provided to the boronic acid tosyl probe, and alcohol groups of the glycan(s) of the glycoprotein or the antibody and the boronic acid group of boronic acid tosyl probe form boronate ester. The nucleophilic residues on the glycoprotein or the antibody replace the tosyl group by SN2 reaction, so as to immobilize the glycoprotein or the antibody through the covalent bond formation.

The present disclosure relates to improved methods and compositions for making extracellular vesicles (EVs). The present disclosure also relates to novel EV-based ELISA assays and kits for performing such assays, as well as methods of producing antibodies to particular antigens using EVs comprising membrane-bound antigen.

The present disclosure relates to improved methods and compositions for making extracellular vesicles (EVs). The present disclosure also relates to novel EV-based ELISA assays and kits for performing such assays, as well as methods of producing antibodies to particular antigens using EVs comprising membrane-bound antigen.