Abstract: A method for determining a concentration of an analyte is provided.

Abstract: The invention is directed to a functional sheet, to a method for preparing said sheet, to a packaging material and to the use of said packaging material. The functional sheet of the invention comprises a porous polymeric carrier having a porosity of at least 60%, preferably at least 80%, more preferably at least 90%, wherein said polymeric carrier comprises one or more functional compounds, which functional compound provides said sheet with at least one function selected from sensing, scavenging and releasing and wherein the polymeric carrier comprises one or more polyolefins and the average pore size of the polymeric carrier is at least 0.11 ?m.

Abstract: The invention relates to a process for the production of an ultra-high molecular weight polyethylene ((U)HMWPE) article comprising: —copolymerizing ethylene with a linear, branched or cyclic polyene having 3 to 100 carbon atoms, resulting in a copolymer of ethylene and polyene ((U)HMWPE-P), using such a content of polyene that the number of polyene branches in (U)HMWPE-P is 0.01 to 15 on the average per 1000 carbon atoms; —cross-link the (U)HMWPE-P during or after molding the (U)HMWPE-P.

Abstract: An article is provided for immobilizing functional organic biomolecules (e.g. proteins, DNA, and the like) through a covalent bond to a thiolate or disulfide monolayer to a metal surface wherein an extra activation step of the surface layer or an activation step of the functional biomolecules or bioreceptors could be avoided. The monolayer can contain, but is not limited to, two moieties. One has a group that resists nonspecific adsorption and another has a group that directly (without activation) reacts with functional groups on the biomolecules. In addition, poly(ethylene oxide) groups are incorporated in the monolayer surfaces to resist the nonspecific adsorption and to enhance the specific affinity interactions. A sensor device including these monolayers is also provided to perform reproducible, sensitive, specific and stable bioanalysis.

Abstract: An article is provided for immobilizing functional organic biomolecules (e.g. proteins, DNA, and the like) through a covalent bond to a thiolate or disulfide monolayer to a metal surface wherein an extra activation step of the surface layer or an activation step of the functional biomolecules or bioreceptors could be avoided. The article comprises mixed self-assembled monolayers of thiol or disulfide molecules of formula X1—(CH2)c—O—([CH2]t—CH2—O)n—R1—S—X2 incorporating poly(ethylene oxide) groups and two functional groups, X1 and X2. Preferably, one functional group resists nonspecific adsorption and the other functional group directly (without activation) reacts with functional groups on the biomolecules. The functional group X1 is selected from the group consisting of flurophenyl, fluorobenzoyl, fluorophenoxycarbonyl, nitrophenoxycarbonyl, C2-12 alkenyl, sulfonyl halide, isothiocyanato, isocyanato, carbonyl halide, haloalkylcarbonyl, and diazonium carbonyl.

Abstract: The present invention discloses an improved method for detecting an analyte. The present invention may be used for sensing devices which have a higher sensitivity and which can be used to detect very low concentration of analyte. In one embodiment, the method comprises the steps of providing a substrate, said substrate comprising a conductive region and a recognition layer, said conductive region having at least a first surface and a second surface, wherein said first surface is operatively associated with said recognition layer; subjecting said substrate to said analyte such that an interaction occurs between said analyte and said recognition layer; directing radiation through said substrate such that said radiation incidents on said conductive region and said recognition layer; and measuring the intensity of said radiation absorbed or transmitted by said substrate as a function of the wavelength in order to determine the presence of an analyte.

Abstract: An article is provided for immobilizing functional organic biomolecules (e.g. proteins, DNA, and the like) through a covalent bond to a thiolate or disulfide monolayer to a metal surface wherein an extra activation step of the surface layer or an activation step of the functional biomolecules or bioreceptors could be avoided. The monolayer can contain, but is not limited to, two moieties. One has a group that resists nonspecific adsorption and another has a group that directly (without activation) reacts with functional groups on the biomolecules. In addition, poly(ethylene oxide) groups are incorporated in the monolayer surfaces to resist the nonspecific adsorption and to enhance the specific affinity interactions. A sensor device including these monolayers is also provided to perform reproducible, sensitive, specific and stable bioanalysis.

Abstract: A metal nanostructure is described. Such a metal nanostructure may comprise a nanometric metal core comprising gold, silver or an assembly or alloy of gold and silver, and one or more molecules attached to one or more surfaces of the nanometric metal core, where each of the molecules has the structural formula W-X-Y-Z, where W is an atom or a chemical group bound to the nanometric metal core, X is a hydrophobic spacer, Y is a hydrophilic spacer and Z is either hydrogen or a reactive group able to bind a reactive substrate or biomolecule. Such a metal nanostructure may be useful in making pharmaceutical compositions.

Abstract: A method for determining a concentration of an analyte is provided.

Abstract: The present invention is related to a device suitable for the preparation of a sensor, comprising a substrate comprising a metal layer, the metal layer comprising at least a first region wherein to a first region is attached a first species comprising a compound of chemical formula: