Abstract: A method of measuring a capacitance (C) of a sensor having a working electrode that is coated by an insulating layer and a ligand forming an affinity surface. The method involves the steps of bringing the electrode into contact with an analyte, supplying a constant first current (I1), and a constant second current (I2) of opposite direction to the first current (I1), and a constant third current (I3) of same direction as the first current (I1) during determined time periods to the sensor. Further the method includes sampling the potential (V) built up across the sensor, and calculating the capacitance of the sensor from the inclination (B, D, F, H) of a potential curve received in response to the current supply. A method used for detection of an interaction between a ligand and an analyte is also disclosed.

Abstract: A method of measuring a capacitance (C) of a sensor having a working electrode that is coated by an insulating layer and a ligand forming an affinity surface. The method involves the steps of bringing the electrode into contact with an analyte, supplying a constant first current (I1), and a constant second current (I2) of opposite direction to the first current (I1), and a constant third current (I3) of same direction as the first current (I1) during determined time periods to the sensor. Further the method includes sampling the potential (V) built up across the sensor, and calculating the capacitance of the sensor from the inclination (B, D, F, H) of a potential curve received in response to the current supply. A method used for detection of an interaction between a ligand and an analyte is also disclosed.

Abstract: A process for adsorption-based separation of bioparticles from an aqueous suspension containing such bioparticles is disclosed which process comprises a) bringing said aqueous suspension into contact with a macroporous cryogel monolith carrying on its surface a ligand capable of interacting specifically or non-specifically with a receptor on the surface of a bioparticle to be separated to adsorb said bioparticle to said macroporous cryogen monolith; and b) liberating said bioparticle from said macroporous cryogel monolith by elution, wherein said macroporous cryogel monolith is subjected to a physical deformation in conjunction with exposure to eluting medium.

Abstract: A composite sorbent material is disclosed which comprises A) a housing of a dense, insoluble material having openings therein and B) a porous polymer gel housed within said housing, said housing being provided with openings therein for fluid communication between said porous monolithic polymer gel and the surroundings, and said porous monolithic polymer gel occupying the inner space of said housing and being kept on place within said housing by mechanical means. Processes for the preparation of composite sorbent materials by cryoprecipitation are also disclosed as well as the use of the composite sorbent material according to the invention e.g. for the removal of pollutants from gases or liquids, for the enrichment or separation of molecules and for cell culture.

Abstract: A process for adsorption-based separation of bioparticles from an aqueous suspension containing such bioparticles is disclosed which process comprises a) bringing said aqueous suspension into contact with a macroporous cryogel monolith carrying on its surface a ligand capable of interacting specifically or non-specifically with a receptor on the surface of a bioparticle to be separated to adsorb said bioparticle to said macroporous cryogen monolith; and b) liberating said bioparticle from said macroporous cryogel monolith by elution, wherein said macroporous cryogel monolith is subjected to a physical deformation in conjunction with exposure to eluting medium.

Abstract: A macroporous cryogen is disclosed which has grafted thereon polymer chains formed by polymerizing at least one monomer of the general formula (I) CR1R2=CR3R4 (I) wherein R1 and R2 are equal of different and each represents a hydrogen atom or substituent group which is not detrimental to the polymerization reaction; and R3 and R4 each represents a hydrogen atom or a substituent group which is not detrimental to the polymerization reaction, provided that R3 and R4 are not both a hydrogen atom, on said macroporous cryogel. A method for the preparation of said macroporous cryogel by graft (co)polymerization and the use of said macroporous cryogel in a separation process are also disclosed.

Abstract: A separation medium in macroporous gel form is disclosed which is obtainable by cooling an aqueous solution of at least one gel forming polymer to a temperature, at which the solvent in the system is partially frozen with the dissolved substances concentrated in the non-frozen fraction of the solvent, said gel forming polymer being selected from the group consisting of polymers normally forming gels too fast when an aqueous solution thereof is cooled to a temperature within a range below 0° C. to enable the formation of a cryogel and said cooling being carried out in the presence of at least one chaotropic agent in said aqueous solution in order to prevent gel formation before the polymer solution is frozen. The use of said separation medium for diverse separation purposes is also disclosed.

Abstract: A separation medium in macroporous gel form is disclosed which is obtainable by cooling an aqueous solution of at least one gel forming polymer to a temperature, at which the solvent in the system is partially frozen with the dissolved substances concentrated in the non-frozen fraction of the solvent, said gel forming polymer being selected from the group consisting of polymers normally forming gels too fast when an aqueous solution thereof is cooled to a temperature within a range below 0° C. to enable the formation of a cryogel and said cooling being carried out in the presence of at least one chaotropic agent in said aqueous solution in order to prevent gel formation before the polymer solution is frozen. The use of said separation medium for diverse separation purposes is also disclosed.

Abstract: A method for the chromatographic separation of substances contained in a liquid sample is disclosed which method comprises providing a one piece separation tray having a spaced array of discrete identical upstanding chambers each exhibiting an open upper end and an open lower end and a separation medium placed in at least part of each upstanding chamber; applying a liquid sample to said open upper end of at least one of said upstanding chambers; then applying an eluting liquid to said open upper end of said at least one of said upstanding chambers; and collecting at least one product fraction flowing out from the open lower end of said at least one of said upstanding chambers; wherein a monolith of a compressible macroporous gel having in its liquid-swollen, non-compressed state a cross-sectional area which is 2-15%, preferably 4-12% and most preferably 5-10%, larger than the cross-sectional area of the upstanding chamber in which it is placed is used as said separation medium and is in face-to-face contact w

Abstract: The present invention relates to a novel isolated and purified alkaline protease from Nesterenkonia sp. nov. strain, having the following characteristics: molecular weight of 23 kilodalton, melting temperature of about 74° C. at pH 7-10, calcium independent for activity and stability, maximal protease activity at pH 10, and being a serine protease, as well as a composition comprising the enzyme, method for producing the enzyme, method of degrading proteinaceous material, an isolated strain Nesterenkonia sp. nov..

Abstract: This invention relates to a metal ion specific capacitance sensor with exceptional sensitivity and wide operating range. It is versatile because different kinds of recognition elements can be immobilized directly in a self-assembling monolayer substantially completely covering the surface of the measuring noble metal electrode. The electrode then becomes selective to those metal ions in the solution that show affinity to the recognition element on the surface. Compared to previously described electrochemical sensors, the sensor according to the present invention shows many orders of magnitude better sensitivity because of the unique measuring principle.

Abstract: A separation medium in macroporous gel form is disclosed which is obtainable by cooling an aqueous solution of at least one gel forming polymer to a temperature, at which the solvent in the system is partially frozen with the dissolved substances concentrated in the non-frozen fraction of the solvent, said gel forming polymer being selected from the group consisting of polymers normally forming gels too fast when an aqueous solution thereof is cooled to a temperature wthin a range below OoC to enable the formation of a cryogel and said cooling being carried out in the presence of at least one chaotropic agent in said aqueous solution in order to prevent gel formation before the polymer solution is frozen. The use of said separation medium for diverse separation purposes is also disclosed.

Abstract: A macroporous gel is disclosed which is obtainable by a) polymerizing an aqueous solution of one or more water-soluble monomers selected from the group consisting of: N-substituted and non-substituted (meth)acrylamides; N-alkyl substituted N-vinylamides; hydroxyalkyl (meth)acrylates; vinylacetate; alkylethers of vinyl alcohol; ringsubstituted styrene derivatives; vinyl monomers; (meth)acrylic acid and salts thereof; silicic acid; and monomers capable of forming polymers via polycondensation, under freezing at a temperature below the solvent crystallization point, at which solvent in the system is partially frozen with the dissolved substances concentrated in the non-frozen fraction of solvent to the formation of a cryogel, and b1) modifying the cryogel by introducing a member selected from the group consisting of ligands, charged groups, dyes and hydrophobic groups thereinto (i) in one or more steps by methods known per se subsequent to thawing of the cryogel or (ii), when appropriate, by using appropriately

Abstract: A method for the separation of at least one low molecular weight bioproduct from a cell culture mixture comprising uni-cellular organisms, broth and said at least one bioproduct by passing said cell culture mixture through a bed of an adsorb-ent material to adsorb said at least one bioproduct on said adsorbent material whereas said unicellular organisms and said broth are passing through said bed, whereafter the ad-sorbed bioproduct or bioproducts is/are eluted from said bed of adsorbent material, wherein said adsorbent material on its surface is provided with a material capable of preventing non-specific adsorption of said unicellular organisms to said adsorbent material.

Abstract: A physically cross-linked copolymer comprising hydrophobic monomers, hydrogen bonding monomers, and thermosensitive monomers, said thermosensitive monomers having a distinct phase change at its lower critical solution temperature (LCST) when existing as a homopolymer. The physically cross-linked copolymer is used for drug delivery system or for enzyme delivery system. The physically cross-linked copolymer is also used for casting shapes of cavities, for production of miniaturized, detailed micro-parts or micro-machine parts, or for production of thermal switches.

Abstract: Disclosed is a process which achieves effective separation of components from red blood cells by aggregating cell membranes with an addition of a pH lowering agent, whereupon the solution is made subject to a separation step where a water soluble fraction is separated from cell membranes, and whereupon the cell membranes are extracted, and where lipids may be selectively separated and recovered by lowering the temperature of the extract.