The present invention relates to a specific protein marker and to a method for identifying the statistical distribution of protein stoichiometry. Novel specific protein markers and methods for their detection are needed in order to clarify important biological questions. This objective is established by means of a specific protein marker comprising two (separate) units, of which the first unit comprises a molecule for specifically binding to a protein and at least one chemically coupled molecule for binding to the second unit, and the second unit comprises a surface-modified nanoparticle, said surface-modified nanoparticle having a surface coating comprising at least one molecule for binding to the first unit.

An immunoassay for the detection of an analyte in a sample includes a plurality of moieties capable of binding to the analyte. Capture moieties, which are not specific for the same epitope, are bound to a solid substrate, and at least one epitope-specific detection moiety is bound to a detectable marker. The detectable marker is a large particle marker having a particle size of ≥50 nm and ≤5000 nm.

This disclosure provides methods and devices for determining a quantitative estimate of syndecan-1 levels in a mammalian subject suspected of internal hemorrhaging. The method includes applying a blood sample from the subject to a hand-held assay device capable of providing optical quantitation of the amount of syndecan-1 in the sample, measuring, by means of said assay device, an analyte signal value correlated to a concentration of the syndecan-1 in the blood sample and comparing the analyte signal value to a minimum threshold, wherein an analyte signal value less than the minimum threshold indicates that the subject is not internally hemorrhaging, and an analyte signal value above the minimum threshold indicates the subject is internally hemorrhaging. The methods and devices are adapted to rapidly assess internal hemorrhaging and hemorrhagic shock in a patient outside of hospital settings.

The invention relates to a SERS method for analyzing a biological sample, the method comprising the following step of: a. obtaining a biological sample which is viscous biofluid, b. depositing at least one droplet of the biological sample onto a microscope slide, and drying the droplet, c. depositing a drop of an aqueous dispersion of metallic nanoparticles above the droplet dried in step b), to have a dense distribution of nanoparticles on the surface of the dried droplet and to obtain a SERS-activated biological sample, d. drying the SERS-activated biological sample, e. irradiating the SERS-activated biological sample using a light source to obtain a SERS spectrum, and f. collecting the SERS spectrum.

The present invention relates to a method for functionalising a cellulose support with metal nanoparticles comprising the steps of: depositing on the cellulose support a single aqueous solution containing the metal precursor in the form of acid or salt in a concentration from 1 to 6 mM; and placing the cellulose support at a temperature from 65° C. to 80° C. for a time from 10 to 40 minutes. The present invention also relates to a method for producing an electroanalytical sensor comprising said functionalised cellulose support with electrocatalytic and concentration properties of the metal marker at the working electrode and to a method for producing the electroanalytical sensor.

This present disclosure provides devices, systems, and methods for performing point-of-care analysis of a target analyte in a biological fluid via a binding assay. The present disclosure includes a cartridge for collecting the target analyte contained in a fluid sample and performing an assay. The cartridge includes an assay stack having a first separation layer, a second separation layer, and a detection membrane. The cartridge also includes a plurality of first complexes comprising a capture molecule and a magnetic bead and a plurality of second complexes comprising a detection molecule and a detection label. Further, the detection membrane includes a substrate that interacts with the detection label to elicit a quantifiable response in the presence of the target analyte. The quantifiable response corresponds to an amount of detection antibody present in the detection membrane, and the amount of detection antibody present corresponds to an amount of the target analyte present.

Provided herein are encoded split pool libraries useful, inter alia, for forming highly diverse and dense arrays for screening and detection of a variety of molecules.

The methods of the invention employ targeted magnetic particles, preferably targeted nanomagnetic particles, and targeted buoyant particles such as buoyant microparticles and microbubbles. Among the benefits of the invention is the ability to combine targeted magnetic particles with differentially targeted buoyant particles to achieve separation of two or more specifically cell targeted populations during the same work flow.

NT-proBNP can be determined in a biological sample using at least one antibody which recognizes an epitope of NT-proBNP in both a glycosylated and non-glycosylated form of NT-proBNP. Said antibody is preferably an isolated polyclonal antibody or a mixture of monoclonal antibodies coated onto a particle, preferably coated onto said particle in a coating ratio of 6-60%, forming a layer or multiple layers of antibodies on said particle. The assay, realized in the form of a nephelometric or turbidimetric assay, can be applied to a wide range of automated clinical analyzers.

The purpose of the present invention is to provide a method for accurately measuring and controlling intracellular potential by a simple method that is less invasive to the cell and does not require a skilled technique. The present invention makes it possible to provide an intracellular recording electrode inside the cytoplasm by introducing conductive nanoparticles into a cell cultured on a conductive plate electrode, attracting the conductive nanoparticles inside the cell to the side of the cell adhered to the conductive plate electrode, and causing the conductive nanoparticles to pass through the cell membrane. Measuring the current or voltage between the intracellular recording electrode and an extracellular electrode in extracellular solution makes it possible to measure the intracellular potential. In addition, applying a current from one of the electrodes or applying a voltage makes it possible to control the intracellular potential and to measure the activity of the ion channels using a membrane potential fixation method. Similarly, using a magnetic electrode adhered to the cell surface of a target cell into which conductive nanoparticles have been introduced beforehand to attract the conductive nanoparticles in the cell to the side of the cell adhered to the electrode and cause the conductive nanoparticles to pass through the cell membrane to make contact with the magnetic electrode, makes it possible to provide an intracellular recording electrode inside the cytoplasm. Alternatively, adhering conductive nanoparticles adsorbed to the surface of a magnetic electrode to the upper side of the target cell and causing the conductive nanoparticles to pass through the cell membrane by attracting the conductive particles to an iron plate provided on the lower side of the cell thereby forms an intracellular recording electrode.