Abstract: Disclosed are a microfluidic system (1) configured to receive cell populations and further configured to simultaneously isolate and quantify at least one sub-population of cells for each cell population, and related methods of using the system. The system comprises a substrate having networks of microchannels comprising a first sorting unit configured to isolate, by magnetic attraction, cells of interest in the population in at least one first sorting microchannel. The network comprises a second unit for simultaneous sorting and counting comprising at least one second sorting microchannel defined by a closed wall having an inner face provided with at least one functionalised electrode configured to trap a sub-population. The second unit further comprising means for counting the sub-population by impedance spectroscopy.

Abstract: Disclosed are a microfluidic system (1) configured to receive cell populations and further configured to simultaneously isolate and quantify at least one sub-population of cells for each cell population, and related methods of using the system. The system comprises a substrate having networks of microchannels comprising a first sorting unit configured to isolate, by magnetic attraction, cells of interest in the population in at least one first sorting microchannel. The network comprises a second unit for simultaneous sorting and counting comprising at least one second sorting microchannel defined by a closed wall having an inner face provided with at least one functionalised electrode configured to trap a sub-population. The second unit further comprising means for counting the sub-population by impedance spectroscopy.

Abstract: The invention concerns the field of microfluidics and in particular that of electrophoresis on a micro- or nanofluidic device. More particularly, the invention concerns the use of a reactive polymer coating adapted to be submitted to a phase separation under the influence of an external stimulation of chemical or physical type, to modulate the electrokinetic flows (electroosmotic or electrophoretic flows during electrophoresis for example) in a micro- or nanofluidic device. The invention also concerns a method for varying the electrokinetic flows in such a device using said coating, as well as the micro- or nanofluidic devices comprising at least one channel or one capillary tube whereof the inner surface is covered at least partly with such a coating.

Abstract: This invention relates to methods for enhancing the efficiency of biological processes that involve successive enzymatic reactions. More specifically, the invention relates to methods for enhancing the efficiency of an enzymatic purification process by increasing the temperature between successive enzymatic purification steps.

Abstract: Methods and devices for attaching biomolecules to a solid substrate surface for example to the inner surface of a capillary. In particular, the invention relates to compounds and methods for creating patterned arrays of biomolecules inside fused silica capillaries so that a plurality of bioassays can be conducted simultaneously.

Abstract: The invention relates to water-soluble N,N-dialkylacrylamide-based high molecular weight random polymers and monomers laterally functionalised by molecules of interest and to the use thereof for preparing solid supports provided with at least one surface on which said polymers are adsorbed. Said invention also relates to the thus modified solid supports, to a method for the production thereof and to different uses thereof, in particular for immobilising molecules of interest or for carrying out chemical, biochemical or biological reactions.

Abstract: This invention relates to methods for enhancing the efficiency of biological processes that involve successive enzymatic reactions. More specifically, the invention relates to methods for enhancing the efficiency of an enzymatic purification process by increasing the temperature between successive enzymatic purification steps.

Abstract: A medium comprises an electrolyte wherein is dissolved at least an assembly of block copolymers characterized in that the block copolymers: are present in the electrolyte at a concentration level to provide the medium with the property of reversibly passing from a state of viscosity V1, obtained at a temperature T1, to a viscosity state V2 greater by at least 100% than V1, obtained at a temperature T2, and comprise in their structure at least: two non-contiguous polymeric segments having in the electrolyte a lower critical solubility temperature (LCST) and having an average number of atoms along their skeleton more than 50; and a polymeric segment soluble in the electrolyte at temperatures T1 and T2. The invention also concerns the use of the medium for separating analytes.

Abstract: The invention provides methods for the treatment of surfaces using surface adsorbing polymers, methods for decreasing the adsorption of organic materials onto the surface of treated devices or vessels, methods for performing fluid operations involving the treatment of surfaces, and apparatus and systems comprising the treated surfaces. Further, the present invention provides a method for treating the surface of microfluidics channel wherein the microfluidics surface is coated for deactivation and wherein this coating can be easily regenerated. The present invention also provides a method for treating the surface of a plastic device. The surface adsorbing polymers of the invention are particularly stable at temperatures and conditions required for biochemical reactions, especially in applications involving temperature cycling or polymerization of polynucleotides or polypeptides.

Abstract: The invention provides methods for the treatment of surfaces using surface adsorbing polymers, methods for decreasing the adsorption of organic materials onto the surface of treated devices or vessels, methods for performing fluid operations involving the treatment of surfaces, and apparatus and systems comprising the treated surfaces. Further, the present invention provides a method for treating the surface of microfluidics channel wherein the microfluidics surface is coated for deactivation and wherein this coating can be easily regenerated. The present invention also provides a method for treating the surface of a plastic device. The surface adsorbing polymers of the invention are particularly stable at temperatures and conditions required for biochemical reactions, especially in applications involving temperature cycling or polymerization of polynucleotides or polypeptides.

Abstract: The invention provides methods for the treatment of surfaces using surface adsorbing polymers, methods for decreasing the adsorption of organic materials onto the surface of treated devices or vessels, methods for performing fluid operations involving the treatment of surfaces, and apparatus and systems comprising the treated surfaces. Further, the present invention provides a method for treating the surface of microfluidics channel wherein the microfluidics surface is coated for deactivation and wherein this coating can be easily regenerated. The present invention also provides a method for treating the surface of a plastic device. The surface adsorbing polymers of the invention are particularly stable at temperatures and conditions required for biochemical reactions, especially in applications involving temperature cycling or polymerization of polynucleotides or polypeptides.

Abstract: Polysaccharides are separated in a capillary using pulsed-field electrophoresis.