The invention relates to identification of synaptogyrin-3 as a target for treating or inhibiting progression of tauopathies or symptoms of tauopathies. In particular, synaptogyrin-3 inhibitors for use as a medicament in general, and for treating or inhibiting progression of tauopathies or symptoms of tauopathies are envisaged. The invention further relates to methods for identification of or for screening for inhibitors of synaptogyrin-3.

The invention relates to identification of synaptogyrin-3 as a target for treating or inhibiting progression of tauopathies or symptoms of tauopathies. In particular, synaptogyrin-3 inhibitors for use as a medicament in general, and for treating or inhibiting progression of tauopathies or symptoms of tauopathies are envisaged. The invention further relates to methods for identification of or for screening for inhibitors of synaptogyrin-3.

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.

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.

The invention discloses a separation matrix which comprises a plurality of separation ligands, defined by the formula R.sub.1-L.sub.1-N(R.sub.3)-L.sub.2-R, immobilized on a support, wherein R.sub.1 is a five- or six-membered, substituted or non-substituted ring structure or a hydroxyethyl or hydroxypropyl group; L.sub.1 is either a methylene group or a covalent bond; R.sub.2 is a five- or six-membered, substituted or non-substituted ring structure; L.sub.2 is either a methylene group or a covalent bond; R.sub.3 is a methyl group; and wherein if R.sub.1 is a hydroxyethyl group and L.sub.1 is a covalent bond, R.sub.2 is a substituted aromatic ring structure or a substituted or non-substituted aliphatic ring structure.

The invention discloses a separation matrix which comprises a plurality of separation ligands, defined by the formula R.sub.1-L.sub.1-N(R.sub.3)-L.sub.2-R, immobilized on a support, wherein R.sub.1 is a five- or six-membered, substituted or non-substituted ring structure or a hydroxyethyl or hydroxypropyl group; L.sub.1 is either a methylene group or a covalent bond; R.sub.2 is a five- or six-membered, substituted or non-substituted ring structure; L.sub.2 is either a methylene group or a covalent bond; R.sub.3 is a methyl group; and wherein if R.sub.1 is a hydroxyethyl group and L.sub.1 is a covalent bond, R.sub.2 is a substituted aromatic ring structure or a substituted or non-substituted aliphatic ring structure.

An article that can be used for biomaterial capture comprises (a) a porous substrate; and (b) borne on the porous substrate, a polymer comprising interpolymerized units of at least one monomer consisting of (1) at least one monovalent ethylenically unsaturated group, (2) at least one monovalent ligand functional group selected from acidic groups, basic groups other than guanidino, and salts thereof, and (3) a multivalent spacer group that is directly bonded to the monovalent groups so as to link at least one ethylenically unsaturated group and at least one ligand functional group by a chain of at least six catenated atoms.

An article that can be used for biomaterial capture comprises (a) a porous substrate; and (b) borne on the porous substrate, a polymer comprising interpolymerized units of at least one monomer consisting of (1) at least one monovalent ethylenically unsaturated group, (2) at least one monovalent ligand functional group selected from acidic groups, basic groups other than guanidino, and salts thereof, and (3) a multivalent spacer group that is directly bonded to the monovalent groups so as to link at least one ethylenically unsaturated group and at least one ligand functional group by a chain of at least six catenated atoms.

A method for detecting an amount of an analyte in a solution includes adding an electrochemically active agent to the solution; applying an electrical current to a working electrode in contact with the solution to initiate the electrochemical redox reaction to change a pH of the solution from a first pH value to a second pH value; incubating the solution at the second pH value to allow the analyte to dissociate from the other molecules in the solution and to bind to a capture molecule connected to the working electrode via a linker; reacting a detecting probe with the analyte to allow the detecting probe to bind to the analyte, the detecting probe having a signaling tag attached thereto and configured to produce a signal at the second pH value; and collecting the signal to calculate the amount of the analyte in the solution.

A method for detecting an amount of an analyte in a solution includes adding an electrochemically active agent to the solution; applying an electrical current to a working electrode in contact with the solution to initiate the electrochemical redox reaction to change a pH of the solution from a first pH value to a second pH value; incubating the solution at the second pH value to allow the analyte to dissociate from the other molecules in the solution and to bind to a capture molecule connected to the working electrode via a linker; reacting a detecting probe with the analyte to allow the detecting probe to bind to the analyte, the detecting probe having a signaling tag attached thereto and configured to produce a signal at the second pH value; and collecting the signal to calculate the amount of the analyte in the solution.