A sensor for the rapid, onsite identification of analytes characterized by: (a) a sample layer; (b) at least one reaction layer, interconnected with the sample layer; (c) at least one reporter layer, interconnected with the reaction payer; (d) at least one preventative layer, interconnected with the reporter layer; and (e) an absorption pad, interconnected with the preventative layer; with the layers arranged as a signaling channel.

Disclosed is a covalently-linked multilayered three-dimensional matrix comprising capture molecules, linkers and spacers (referred to as a Molecular Net) for specific and sensitive analyte capture from a sample. Also disclosed herein is a Molecular Net comprising covalently-linked multilayered three-dimensional matrix comprising more than one type of capture molecule and more than one type of linker and may comprise one or more spacer for specific and sensitive capture of more than one type of analyte from a sample. A Molecular Net may comprise a pseudorandom nature. Use of various capture molecules, linkers and spacers in a Molecular Net may confer unique binding properties to a Molecular Net. Porosity, binding affinity, size exclusion abilities, filtration abilities, concentration abilities and signal amplification abilities of a Molecular Net may be varied and depend on the nature of components used in its fabrication. Uses of a Molecular Net may include analyte capture, analyte enrichment, analyte purification, analyte detection, analyte measurement and analyte delivery. Molecular Nets may be used in liquid phase or on solid phases such as nanomaterials, modified metal surfaces, nanospheres, microspheres, microtiter plates, slides, pipettes, cassettes, cartridges, discs, probes, lateral flow devices, microfluidics devices, microfluidics devices, optical fibers and others.

The invention provides a novel method of preparing a capture phase for detecting and/or quantifying a target biological entity, said capture phase including a biological ligand for the biological entity, said biological ligand being covalently bonded to an amphiphilic polymer and being immobilized on a solid support, the method being characterized in that the biological ligand is immobilized on the solid support by bringing the solid support into contact with a dispersion of micelles formed by a plurality of chains of the amphiphilic polymer, said micelles carrying a plurality of molecules of the biological ligand on the surface thereof. The invention also provides corresponding capture phases and associated detection methods and kits.

Embodiments of the disclosure include coatings comprising an oligomerized polyphenol layer. The oligomerized polyphenol layer can be used as an intermediate coated layer on a medical device that hydrogen bonds to a synthetic or natural polymer, which in turn can be used as a top coat or further associated with another coated layer. The multilayered coatings can provide properties such as hemocompatibility or lubricity. In other embodiments, the oligomerized polyphenol layer is used on a medical device as a hemostatic layer configured to contact blood and promote coagulation. The oligomerized polyphenol layer can also be used on the inner surface (e.g., inner diameter) of a medical device to prevent bacterial adherence. The oligomerized polyphenol layer can also be used on the surface of a in vitro diagnostic article, or a cell culture device to, promote adsorption of a biological mo lecule.

Provided is a method to detect a target molecule, including a complex formation step of reacting a target molecule, a carrier modified with a first antibody which specifically binds to the target molecule, and two or more second antibodies which specifically bind to the target molecule, and are labeled with enzymes having a substrate cleaving activity and mutually different substrate specificities, to form a complex consisting of the first antibody, the target molecule and the second antibodies, on the carrier; and a detection step of reacting two or more substrates having cleavage sites by the enzymes, a fluorescent substance bound to one terminal side of each of the cleavage sites and a quencher bound to another terminal side thereof, wherein the fluorescent substances are mutually different in fluorescence wavelength, and the complex, to detect fluorescence emitted from the fluorescent substances.

Disclosed probes comprise metal nanoparticle cores associated with magnetic particles that allow probes associated with targets to be concentrated by an applied magnetic field to increase detection sensitivity and provide sufficient spacing between concentrated probes to avoid signal quenching. The probe may comprise at least one recognition receptor, and may further comprise at least one reporter molecule, such as a fluorescent tag, a Raman reporter, or combinations thereof. Concentrating probe-target composites substantially enhances a sensing signal, such as from 5 to 10 times, compared to detection without concentrating the probes. The method may be used to detect, for example, interleukins at concentrations at least as low as 25 pg/ml in sputum or blood from a subject for early and precise profiling of viral infections, such as SARS-CoV-2 infections.

A device suitable for the detection and/or characterization of target particles in a fluid is disclosed. The device comprises: at least one heating element for heating and/or measuring a temperature, the heating element comprising a core comprising at least one electrically conducting portion, an electric isolating layer provided at a surface of the core and electrically isolates the core from the sample, and a plurality of binding sites at/to which target particles can bind. The device further comprising a processing means configured to measure an electric output of the least one heating element, a change of the electric output of the at least one heating element and/or its heating power and for deriving, based thereon, a characteristic of the target particles.

Biocompatible methods of functionalising inert surfaces for use in biological applications are described. The methods employ the use of synthetic constructs of the generic structure F-S-L (where F is a functional moiety, S is a spacer selected to provide a construct that is dispersible in water, and L is a diacyl- or dialkyl-glycerophospholipid). An object of the invention is to localise or immobilise functional moieties to the inert surface of a substrate wherein the surface is comprised of glass, silver, polyamide, polycarbonate, polypropylene, polyethersulfone, polytetrafluoroethylene or polyvinylidene fluoride, and the substrate is comprised of a fibre, membrane, microsphere or nanosphere.

The present invention relates to compositions and methods use in designing immunoassay controls. In various aspects, the invention provides synthetic peptides comprising the sequence CPRRPYIL or an analog thereof; ELAGLGFAELQC or an analog thereof; and CDWRKNIDAL or an analog thereof; specific binding reagents that bind to a CPRRPYIL, ELAGLGFAELQC or CDWRKNIDAL peptide; methods of producing such reagents; and assays utilizing such reagents to provide assay controls signals that are unrelated to the measurement of the analyte or analytes of interest in that no reagents used in the analyte assay(s) contribute to the control signal.

Disclosed are devices and methods for detecting analytes from a sample.