Systems and methods for measuring analytes in fluid samples are disclosed. The systems and methods employ test strips which are generally comprised of a substrate, at least one electrical connection, at least one sensing chemistry and at least one additional layer. The test strips can be batch calibrated.

Silica-based biomolecule carriers, compositions comprising the same and preparation methods and uses thereof for delivering biomolecules into a cell are provided. The silica-based biomolecule carrier comprises a porous core; a first bioactive moiety; a second bioactive moiety functionally associated with the first bioactive moiety; and linkers for respectively conjugating the first bioactive moiety and the second bioactive moiety to the porous core.

Silica-based biomolecule carriers, compositions comprising the same and preparation methods and uses thereof for delivering biomolecules into a cell are provided. The silica-based biomolecule carrier comprises a porous core; a first bioactive moiety; a second bioactive moiety functionally associated with the first bioactive moiety; and linkers for respectively conjugating the first bioactive moiety and the second bioactive moiety to the porous core.

A hydroxyl-covered silicon quantum dot nanoparticle having a silicon core, a plurality of silicon quantum dots, and a plurality of hydrocarbon chains is illustrated. A first portion of a surface associated with the silicon core is passivated by a plurality of silicon hydroxyl groups (Si—OH). The silicon quantum dots are attached to a second portion of the surface associated with the silicon core. The hydrocarbon chains are bonded to each of the silicon quantum dots through a plurality of silicon carbide bonds (Si—C), wherein each termination of the hydrocarbon chains has a carbon hydroxyl group (C—OH), such that the hydroxyl-covered silicon quantum dot nanoparticle is thoroughly covered by the carbon hydroxyl groups (C—OH) and the silicon hydroxyl groups (Si—OH).

The present invention belongs to the field of nucleic acid detection, particularly in-vitro diagnostics. The invention concerns amongst others the amplification of at least one or more target nucleic acid that may be present in at least one sample using an inventive control, which comprises a particle comprising a polycationic compound and a nucleic acid. The present invention relates also to uses of the inventive controls, methods for the preparation, diagnostic tools and kits.

The present invention relates to a method for single-cell imaging mass spectrometry (MS) by correlating an optical image of a cell sample with an MS image. The method of the invention is in particular useful in research to test concomitantly optical and molecular phenotypes at a single-cell resolution.

The present invention relates to a method for single-cell imaging mass spectrometry (MS) by correlating an optical image of a cell sample with an MS image. The method of the invention is in particular useful in research to test concomitantly optical and molecular phenotypes at a single-cell resolution.

The invention relates to a method for detecting various analytes, characterized by the following steps: a) providing separation particles containing, on their surface, firstly means of binding the analyte to be identified and secondly means of separating the analyte bound to the particles; b) providing identification particles firstly having, on their surface, means for binding the analyte to be identified and secondly containing on their surface or enclosed therein, means which are capable, after they have been detached or released from the particles, by virtue of their labeling, of generating a signal which serves for identification of the analyte; c) combining analyte, separation particles and identification particles; d) removing and washing the identification particles bound via the analyte by means of the separation particles; e) releasing the means which serve to identify the analyte, characterized in that the means which serve to identify the analyte are coupled reversibly to the identification particles and in that the identification molecules serve simultaneously for identification of the analyte and for detection.

The invention relates to a method for detecting various analytes, characterized by the following steps: a) providing separation particles containing, on their surface, firstly means of binding the analyte to be identified and secondly means of separating the analyte bound to the particles; b) providing identification particles firstly having, on their surface, means for binding the analyte to be identified and secondly containing on their surface or enclosed therein, means which are capable, after they have been detached or released from the particles, by virtue of their labeling, of generating a signal which serves for identification of the analyte; c) combining analyte, separation particles and identification particles; d) removing and washing the identification particles bound via the analyte by means of the separation particles; e) releasing the means which serve to identify the analyte, characterized in that the means which serve to identify the analyte are coupled reversibly to the identification particles and in that the identification molecules serve simultaneously for identification of the analyte and for detection.

The invention relates to coloured particles with particular mass density, diameters and surface charge comprising pathogen ligands immobilized. The particles are used in methods for detecting and/or characterizing pathogens present in isolated test samples, as well as in methods for detecting and/or characterizing pathogen-binding antibodies present in isolated test samples. A kit comprising the particles is also disclosed.