Methods for performing bead-based analytical assays for detecting changes in abundance of target analytes in biological samples are disclosed. In an embodiment, a method involves eluting bead-captured analytes from a bead array under conditions that preserve spatial localization of the eluted analytes.

Provided herein are graphene biosensors and related core particles, compositions methods and systems in which more than one pristine graphene sheet is coated with a coating layer of an organic or inorganic material to provide a core graphene particle, to which detectable components comprising a detectable moiety and a peptide linkage are attached through binding of the peptide linkage.

A method of manufacturing synthetic particles for use in microfluidic devices is disclosed. The method includes identifying a set of particle characteristics for a fluid-based process. The set of particle characteristics can include a synthetic particle density and one or more of a size, compressibility, elastic modulus, or porosity. The method includes selecting an input material for the synthetic particles based on the set of synthetic particle characteristics. The method may include selecting an additive based on the set of synthetic particle characteristics. The method includes providing input material and the additive into a droplet generator to create one or more synthetic particles having the set of synthetic particle characteristics, and modifying a surface characteristic the synthetic particles, such that the synthetic particles bind to a target particle in a solution.

In a flow cytometry measurement method, an analysis medium is provided, which includes a fluid and biological cells contained therein. A labeling molecule is provided and is brought in contact with the analysis medium in such a way that the labeling molecule can bind specifically to a target structure located on the surface of the cell if the cell has said cell structure. For the individual cells, flow cytometry measured values are captured for a first and a second physical parameter. The first parameter is fluorescence radiation emitted by the labeling molecule when the labeling molecule is excited. The cells are classified on the basis of the flow cytometry measured values. A first calibrator and a second calibrator are provided, which have solid particles matching in shape, size and material. A target structure matching the target structure of the cells is immobilized on the surface of the first calibrator. The second calibrator does not have said target structure. The calibrators are mixed with the analysis medium before the flow cytometry measured values are captured. Corresponding first and second flow cytometry measured values are captured for the calibrators as well as for the cells. A normalized first flow cytometry measured value for the cell is formed from the first flow cytometry measured value of the first calibrator, the first flow cytometry measured value of the second calibrator and the first flow cytometry measured value of the cell.

Provided herein are methods for detecting an Aspergillus protease in a sample, diagnosing a subject with aspergillosis caused by an Aspergillus infection based on the presence of an Aspergillus protease in a sample, and methods of aspergillosis treatment that incorporate these diagnostic methods. In certain embodiments, the Aspergillus protease is Asp f2, and the Aspergillus infection is caused A. fumigatus, A. flavus, A. versicolor, A. niger, or A. terreus. Also provided herein are antibodies and kits for use in these methods, including novel antibodies specific for Asp f2.

The present disclosure is in the field of in vitro diagnostics and relates to an easily automatable binding assay for establishing a heparin-induced thrombocytopenia, which binding assay uses FcγRIIa protein-coated particles.

Described is a method and device for detecting an analyte in a sample, comprising bringing a sample comprising a target analyte into contact with magnetisable particles, the particles being coated with binding molecules complementary to the target analyte, resulting in bound and unbound binder complexes, positioning the magnetisable particles, comprising both bound and unbound binder complexes, in proximity to a magnetic field sensor, changing the magnetic field sufficient to release at least a portion of the magnetisable particles, comprising both bound and unbound binder complexes, from their proximity to the magnetic field sensor, and measuring changes in a magnetic signal detected from the net movement, being either translational or rotational movement, of the magnetisable particles relative to the magnetic sensor.

Chromonic azo dyes are particular types of chromonic molecules that are alignable homeotropically (aggregated molecules stack perpendicularly to the surface) on different types of substrates, often without the need of any special surface treatment. This feature enables the optimization of a detection device with increased sensitivity based of the alignment distortion created by a biological immune complex.

Two or more upconverting particles are attached to each unit of one or more units of a chemical component in a sample, to form, for each unit of the chemical component, a multi-particle complex including the unit of the chemical component and two or more corresponding upconverting particles. The sample is illuminated by input light having a first wavelength. Light is received at an imaging sensor, the received light including output light generated by at least a portion of the upconverting particles attached to the units of the chemical component, the output light having a second wavelength that is shorter than the first wavelength. One or more images of the sample are captured from the received light. Based on the captured one or more images, a presence or a level of the chemical component in the sample is determined.

A multiplexed digital detection platform embodiment for molecular species in solution is based on a single-molecule immunochemistry, and/or aptamer chemistry, on color-barcoded beads. Beads that capture molecular species from a complex sample using selective binders are exposed to a test sample, and the captured molecular species is tagged using second affinity probes that are linked to photocleavable nucleic acid particles. In the embodiment, the beads are then introduced to a counter system that comprises a microcavity/nanopore device. Once a bead is captured by the micropore, nucleic acid particles, e.g., reporter nucleic acid nanoparticles (rNANPs), are released using photocleavage, and are detected by the nanopore. Each electrical spike that is uniquely produced by the nucleic acid nanoparticle is counted as a single molecular species, and the total count represents the overall number of molecular species in the sample. Various molecular species can be detected at the same time.