Beads for use as a control, calibration and/or quantification probe in a mass cytometry assay, wherein the beads are labeled with a heavy metal selected from the group comprising osmium or ruthenium. Also disclosed are beads labeled with a heavy metal exhibiting a surface functionalization that allows for the binding of an affinity reagent, such as a metal-conjugated antibody. Methods are described for the labeling of the beads and usage of the beads for quantification of cell surface receptors or for a compensation of channel crosstalk in mass cytometry assays.

The present disclosure provides assays, such as lateral flow assays, and components thereof for detection of an analyte, e.g., a neutralizing antibody, that blocks binding of a first molecular component and a second molecular component of a molecular binding pair. In some embodiments, the disclosed assays and components thereof enable the rapid detection of a SARS-CoV-2 neutralizing antibody in a sample from an individual. Also provided in other aspects of the disclosure are devices, methods of making and using, and kits of the assays described herein.

Disclosed herein are erasable label systems that involve nanocage molecules positioned around nanoparticles, which can be loaded with, bound to, or adsorbed with imaging agents. The nanocages can contain targeting arms composed of ssDNA or ssRNA that can be used to target biomolecules. For DNA or RNA targeting, this can be done directly. Antibodies can be targeted using avidin-biotin coupling to ssDNA or direct ssDNA conjugation to the antibody surface. ssDNA or ssRNA complementary to one of the arms can then be used to “erase” the label.

Provided herein are methods for identification of antigen binding molecules such as antibodies from a sample by exposing the antigen binding molecules to an antigen conjugated to an oligonucleotide.

Disclosed herein are devices for molecule detection and methods for using detection devices for molecule detection, such as nucleic acid sequencing. In some embodiments, a detection device comprises one or more pole pieces, one or more sensors, each of the one or more sensors coupled to at least one of the one or more pole pieces, and detection circuitry coupled to the one or more sensors. The detection circuitry is configured to detect a characteristic of each of the one or more sensors, the characteristic indicating presence or absence of one or more magnetic nanoparticles (MNPs) coupled to at least one of a plurality of molecules to be detected, and at least one of the one or more pole pieces is operable to draw the one or more MNPs toward at least one of the one or more sensors.

The present disclosure provides assays, such as lateral flow assays, and components thereof for detection of an analyte, e.g., a neutralizing antibody, that blocks binding of a first molecular component and a second molecular component of a molecular binding pair. In some embodiments, the disclosed assays and components thereof enable the rapid detection of a SARS-CoV-2 neutralizing antibody in a sample from an individual. Also provided in other aspects of the disclosure are devices, methods of making and using, and kits of the assays described herein.

Method consists of placing a flexible container within a rigid frame and expanding the container by pneumatic or hydraulic pressure such that the walls of the container conform to the inside walls of the rigid frame thus forming a well-defined chamber. The system has the capability of reducing the volume of the chamber by adjusting the distance between the walls of the rigid container. The methods and systems so described are applicable to closed sterile systems that employ immunomagnetic isolation or purging of components from blood products. By providing a fixed volume and at least one surface upon which targeted entities can be magnetically deposited, target cells in the case of positive isolations can be magnetically held, flushed with wash buffers over them to remove entrapped cells and finally the recovery of product of extremely high purities and at high yields.

The visualization method of the present invention includes the steps of: visualizing a first substance capable of binding to a target substance in a specimen; and visualizing a second substance produced by action of the first substance in the specimen.

The present invention relates to means and methods for conjugating/attaching target molecules such as proteins to a label and/or carrier. Specifically, the present invention provides a complex comprising a metal cation coordinating (i) nitrate as a metal cation ligand and (ii) a metal cation chelating domain comprising a chelating ligand and a label and/or carrier. This complex can be used for attaching a label and/or a carrier to a target molecule, preferably a protein. The attachment of the label or carrier via the complex of the invention involves the replacement of the metal cation ligand with a coordinating group of the target molecule so that a product complex with the target molecule as primary ligand in the coordination sphere of the metal cation is formed. Accordingly, the present invention also provides for uses and methods involving the attachment of a label and/or carrier to a target molecule. Also provided are the products obtained by the labeling and or carrier-attaching methods of the invention and uses thereof. The invention further relates to methods for producing the complex of the invention and kits comprising the components for producing the complex of the invention.

A method for screening a DNA-encoded library of chemical structures (2) for activity in a cellular target (11) wherein the chemical structures (2) of the library, the corresponding encoding DNA (4) and, optionally, a chemical probe (7/8/9) susceptible to the response molecule (12) are covalently linked to beads (1); the method comprising providing an incubation medium (13) or aliquot thereof comprising the cellular target (11) and exactly one or more than one bead (1) as defined above, releasing the chemical structures (2) from the bead(s) (1) in the incubation medium (13) or aliquots thereof by cleaving the structure linkers (3) and incubating the released chemical structures (2) and the cellular target (11); and sequencing the encoding DNA present or remaining on the bead(s) (1). A bead (1) suited for the method is also provided.