Abstract: The present application discloses a planar enzyme sensor for measuring the concentration of an analyte in a solution comprising a substrate of an electrically insulating material supporting an electrode layer of an electrically conductive material. The substrate and electrode layer have a plurality of layers disposed thereon which include an enzyme layer and a microporous outer layer covering the enzyme layer, wherein the outer layer comprises a continuous phase of a water-resistant polymer (e.g. a polyvinylacetate or an acrylate copolymer), a protein (e.g. an enzyme) embedded in the continuous phase, and possibly polytetrafluoroethylene particles. The enzyme and the polytetrafluoroethylene particles provide a controlled porosity to the outer membrane.

Abstract: Ion selective membranes and the preparation thereof, such as magnesium ion selective membranes and the preparation thereof. In particular, the invention describes improved PVC polymer blends for use in ion selective membranes. The invention furthermore relates to electrodes and potentiometric sensors comprising such membranes and the use thereof for determining ion concentrations in samples.

Abstract: The present invention relates to methods for analyzing at least one blood parameter in a whole blood sample of a patient, wherein the in vitro hemolysis of a whole blood sample is determined. The present invention also relates to a corresponding analysis apparatus, a system for analysing a whole blood sample and a computer program element for controlling the analysis apparatus as well as a computer readable medium storing the computer program element. A method is provided for differentiating the contributions from in-vivo hemolysis and in-vitro hemolysis of an overall hemolysis level determined for the whole blood sample. Blood parameters like potassium or lactate dehydrogenase can then be corrected for hemolytic interference factors.

Abstract: The present application discloses a planar enzyme sensor for measuring the concentration of an analyte in a solution comprising a substrate of an electrically insulating material supporting an electrode layer of an electrically conductive material. The substrate and electrode layer have a plurality of layers disposed thereon which include an enzyme layer and a microporous outer layer covering the enzyme layer, wherein the outer layer comprises a continuous phase of a water-resistant polymer (e.g. a polyvinylacetate or an acrylate copolymer), a protein (e.g. an enzyme) embedded in the continuous phase, and possibly polytetrafluoroethylene particles. The enzyme and the polytetrafluoroethylene particles provide a controlled porosity to the outer membrane.

Abstract: The present disclosure relates to an improved enzyme sensor comprising a cover membrane layer of a porous polymeric material, the outer surface and pore mouths of at least one face of the porous polymeric material being covered by a hydrophilic polymer. The sensor is useful determining the presence or amount of biological analytes, e.g., glucose, lactate, creatine, creatinine, etc.

Abstract: In a sensor for measuring an analyte in a biological sample whose measuring surface is covered by or comprises a membrane, the membrane has free groups on the surface facing the sample. The surface is modified such that a hydrophilic component is immobilized on the surface in such a manner that chains of the hydrophilic component are chemically bonded to free groups on the surface. Thus, the surface is provided with a more hydrophilic character relative to its unmodified state.

Abstract: A method for producing cardable, hydrophobic polyolefin-based staple fibers by applying to spun filaments a first spin finish comprising at least one cationic antistatic agent, in particular a quaternary ammonium salt, stretching the filaments, applying to the stretched filaments a second spin finish in the form of a dispersion comprising at least one hydrophobic lubricant selected from a fatty acid amide condensation product and a hydrocarbon wax, the second spin finish optionally further comprising a polydiorganosiloxane in an amount of up to 15% by weight, and crimping, drying and cutting the filaments to obtain staple fibers; as well as textured, cardable, polyolefin-based staple fibers prepared by the method and hydrophobic nonwoven materials produced from such fibers.