Abstract: A biochip includes a flat carrier and an array of spots containing catcher molecules which are arranged on the carrier. Each spot is associated with a microelectrode arrangement for impedance spectroscopic detection of binding events occurring between the catcher molecules and the target molecules applied via an analyte solution. In order to increase the sensitivity or the binding-specific measuring effects of the bio-chip, the electrode arrangement is at least partially embedded in a hydrophilic reaction layer containing catcher molecules and which is permeable to target molecules.

Abstract: Disclosed is an apparatus that is used for detecting liquids or substances from liquids and includes a plunger that has a porous plunger layer which is pressed onto a sensor array. Each sensor of the sensor array is surrounded by elevations which spatially separate the sensors from each other like walls. In at least one embodiment, when the plunger layer is pressed onto the sensor array, the walls are pressed into the pores of the plunger layer. Liquid-tight connections are created between the walls and the plunger layer while liquid remains over the sensors. The liquid can be measured. In at least one embodiment, when there is direct mechanical contact between the plunger layer and the sensors, the liquid over the sensors is located in open pores on the surface of the plunger layer. No liquid flows between the pores and across the walls when pressure is applied to the plunger layer such that closed reaction chambers are created.

Abstract: A process is disclosed for determining the concentration of nucleic acids in a sample in a microfluidic device. In at least one embodiment, the method includes a) introducing the sample into a first chamber, b) carrying out a number of cycles of an amplification reaction to be carried out in cycles for amplifying nucleic acids, c) transferring a defined volume which is a fraction of the volume of the first chamber and which has amplified nucleic acids into a second chamber and replacing the transferred defined volume with fresh reagents for the amplification reaction, d) determining the concentration of the amplified nucleic acids in a second chamber equipped with an element to determine concentrations, and e) repeating steps b)-d) until a concentration of the amplified nucleic acids which is within a range is determined in the second chamber. An arrangement is further disclosed.

Abstract: An assembly and a method for filtration are disclosured, which are suitable in particular for the filtration of cells, for example tumor cells, from a sample, for example a blood sample. In the method, a pressure differential between the pressure upstream and the pressure downstream of a filter is determined; and the pressure differential between upstream and downstream of the filter is adjusted such that the pressure differential does not exceed a predetermined value.

Abstract: A process is disclosed for detecting cells in a liquid sample, which includes: i) filtration of the liquid sample through a porous membrane which is suitable for retaining detectable cells, where at least one subregion of a support is configured as transparent supporting body and the membrane is arranged over its area on the transparent supporting body in such a way that detectable cells are retained on at least part of the surface of the membrane and that at least part of the sample liquid passes through the membrane, ii) application of a liquid optical medium which has essentially the same refractive index as the supporting body, and iii) optical measurement of at least a subarea of the membrane in order to detect detectable cells.

Abstract: An embodiment relates to a method and to an array for detecting live circulating or disseminated cells in body fluids (for example blood, urine) or tissue samples (for example bone marrow) mixed with liquid. The method includes: a) filtering the liquid sample through a porous membrane that is suitable for retaining cells to be detected, such that cells to be detected come to rest upon at least a part of the surface of the membrane and the sample liquid passes the membrane; b) applying a first process liquid containing a first agent for marking the cells to be detected with a first marker; c) incubating the process liquid on the membrane for a predetermined time period, wherein the cells to be detected are marked; and d) detecting the marked cells to be detected on the surface of the membrane.

Abstract: A microfluidic diagnosis kit used in biochemical analysis obtains a premeasured amount of reagents in an applicator for an analysis system. The required reagents are proportioned as non-volatile agents and a microfluidic system is provided, whereby the reagents are automatically dissolved in a solvent and fed to a sensor module to carry out measurement.

Abstract: An apparatus is disclosed for processing a sample which stores processing reagents required for processing in a dry form. The processing reagents are covered by a biologically degradable medium or embedded in said biologically degradable medium.

Abstract: An example embodiment of the present invention discloses a method for analyzing nucleic acids in a microfluidic device. The method includes the following steps: a) nucleic acids are amplified in a first chamber in the microfluidic device; b) the amplified nucleic acids are brought into contact with an additive including: i) monovalent cations and ii) an Mg2+ ion-binding agent, the additive being provided in a second chamber in the microfluidic device; and c) the amplified nucleic acids are hybridized on at least one probe oligonucleotide.

Abstract: Solid matter in a cavity is used to produce a solution of at least one solid matter in a solvent. The solid matter which is soluble in the solvent in initially covered and/or surrounded in the cavity by a medium which is insoluble in a solvent, such that dissolving of the solid matter is prevented. Subsequently the solvent is guided to the cavity and the medium which is insoluble in the solvent is treated in such a manner that contact is made between the solvent and the soluble solid matter, enabling the solid matter to dissolve in the solvent. Solutions including two or more solid matter can be produced in an advantageous manner.

Abstract: A titer plate and a method for detecting an analyte, and the use thereof are disclosed. According to at least one embodiment of the invention, it is proposed that a plurality of depressions and a biochip of the titer plate sposed adjacent thereto be surrounded by a wall in order to effectively prevent sample contamination when there is a high degree of spatial integration.

Abstract: An assembly and method are disclosed for the filtration of a liquid and the use thereof, wherein a supporting body is designed in a recess of a carrier and a filter membrane lies flat on the supporting body. The filter membrane and the supporting body are designed to be permeable to liquids and thus serve as filters, in particular for filtering tumor cells from blood. The carrier can having standard shapes of an object carrier for microscopy and the filtration residue on the filter membrane can be easily handled and examined in the microscope. As a result of the filter membrane lying level on the supporting body, the filtration residue can be particularly well examined microscopically.

Abstract: Electrochemical transducer arrays are already known from the prior art. According to the invention, the transducer array is provided with at least one flexible, planar metal substrate on which at least one flexible insulator having a firm connection between the metal surface and the insulator surface is disposed. The metal substrate and the insulator disposed thereon are structured in such a manner as to give metal areas which are electrically insulated the one from the other and which serve as sensor areas. The metal substrate used is self-contained so that the structured metal areas can be contacted from the lower side.

Abstract: An arrangement and a method measures cell vitalities with a sensor array. The sensor array is formed on a surface of a semiconductor chip. The semiconductor chip has integrated circuits and an integrated circuit is associated with each sensor of the sensor array, for processing the measurement signals of the respective sensor. The integrated circuits are formed in the semiconductor chip spatially in each case below the associated sensor and neighboring sensors of the sensor array have a centre-to-centre in the range of micrometers. The pH and/or pO2 can be measured in the environment of a living cell.

Abstract: The method includes binding living cells to magnetic particles, adding them to a sensor array, uniformly distributing over the sensor array, magnetically fixing the magnetic particles having the bound cells over the sensor array, and adding substances to maintain and/or improve the cell vitality to the sensory array, and/or adding substances to worsen the cell vitality to the sensor array. The assembly includes a sensor array composed of sensors, which are designed to be in direct fluidic contact with a fluid, and a device for generating a magnetic field over the sensor array. A layer that comprises magnetic particles and living cells is formed on the sensor array.

Abstract: At least two microfluidic devices and at least one sensor chip are formed in a flat body. The at least one sensor chip is in direct contact with at least one first microfluidic device. A second microfluidic device in the manner of a pipette is integral with the flat body or connected thereto. The flat body may be used by docking an E-cup by way of a clamping device of the flat body to the flat body and exchanging fluid between the E-cup and the flat body by way of the second microfluidic device.

Abstract: A device for detecting chemical or biochemical substances in fluids includes a first carrier having a sensor array with a plurality of electrochemical sensors. A second carrier includes a porous layer having at least one functional region, in which specifically binding capturing molecules are immobilized. The at least one functional region is arranged directly adjacent to at least one non-functionalized region. Assigned to the at least one functional region and the at least one non-functionalized region are several sensors of the sensor array, for use as an electrochemical camera.

Abstract: A substrate of a lab-on-a-chip system has two adjacent recesses, one serving as a flow channel and the other one being filled with an elastomer compound. In a first state, the elastomer compound and the substrate delimit the flow channel in a section. In a second state, the elastomer compound takes up the space in the recess in the substrate along a cross-section of the flow channel, thereby completely closing the flow channel. The substrate and the elastomer compound may be produced by injection molding techniques.

Abstract: An array of valves are arranged in n columns and m lines and which are each designed to control a fluid flow in an associated flow channel in a lab-on-a-chip system. The array includes at least two valves, every column having not more than one valve and every line having from zero to n valves. A device is used for actuating the valves. The valves are pressure-actuated. To produce the device, the flow channels are arranged in accordance with the arrangement of the valves.

Abstract: A method follow the change in concentration of a redox-active substance, whereby suitable potentials for a reduction process or an oxidation process are applied to the working electrode of a measuring device. The potential of the working electrode is pulsed and measuring phases and relaxation phases are alternately produced, the pulse lengths of measuring phase and relaxation phase being determined in a suitable manner. A rapid relaxation of the concentration gradient is electrochemically forced so that the measurement can be carried out on simple transducer arrays. A device for carrying out the method includes a transducer array in addition to a suitable potentiostat. The transducer array can be formed of a planar metal substrate on which at least one flexible insulator is disposed, the metal surface and the insulator surface being firmly linked. The transducer array can also be formed of silicone-based CMOS structures.