Abstract: In order to follow the change in concentration of a redox-active substance, potential suitable for a reducing process or 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 the measuring phase and relaxation phase being predetermined in a suitable manner. In this manner, a rapid relaxation of the concentration gradient is forced electrochemically so that the measurement can be carried out on simple transducer arrays. The device includes a transducer array in addition to a suitable potentiostat. The transducer array may include a planar metal substrate on which at least one flexible insulator having a firm connection between the metal surface and the insulator surface is located. The array is generated by suitably structuring the substrate.

Abstract: A DNA isolation method by removal of constituents, interfering with a subsequent PCR is disclosed. According to an embodiment of the method, all substances and method steps are fully integrated into a closed unit (cartridge) for single use, which allows entry of a DNA-containing sample and DNA-binding substrates are used for isolating the released DNA. In particular, when the method is applied to DNA isolation from whole blood by disruption of white blood cells, the reagents, required for carrying out the cell disruption and other reactions, are stored in a form which is stable at room temperature. For disrupting the white blood cells and for DNA isolation, a dry stored lysis reagent is dissolved in an aqueous solution and brought into contact with the white blood cells.

Abstract: In order to avoid problems caused by baseline drift, it is expedient in a method of an embodiment of the present application not to measure a signal rise in a detection space, but to allow a certain time period to elapse in order to enrich a detectable product (enrichment phase), then to measure a first detection signal, and to measure the baseline signal as second detection signal only after rinsing out the detection space and removing the enriched product. In at least one embodiment, the enriched product is not detected from a signal rise with reference to a baseline, but from a signal difference of first and second detection signals.

Abstract: A PCR process for DNA amplification with thermocyclisation of the corresponding reagents is disclosed, in which total integration of all substances and process steps is achieved in a closed, single-use unit (so-called cartridge) in which the reagents are stored in a storage-stable form at room temperature. According to the process, the water-soluble reagents are covered by a water-insoluble medium, then the DNA to be amplified is supplied and the water-insoluble medium is eliminated, so that the water-soluble reagents are dissolved and PCR can start. In the corresponding arrangement, a test unit designed as a single-use produce (a so-called cartridge) has at least one micro-channel or micro-cavity for receiving a PCR reagent. The PCR reagents in the form of a mixture which can be dried at a negligible vapour pressure and forms a storage-stable substance substance at room temperature adhere to the walls of the micro-channel or micro-cavity and form a thin film covered by an insoluble medium.

Abstract: A device is disclosed for extracting a smear sample. The device includes a cavity, into which a sample carrier carrying a smear sample can be introduced. Liquid can be introduced into the cavity through at least one liquid feed connected to the cavity, and the liquid can be removed from the cavity through at least one liquid discharge connected to the cavity.

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: 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: The embodiments relate to an apparatus and a method for detecting liquids or substances from liquids in spatially separate reaction zones. The embodiments further relate to the use of the apparatus in a plug-in module or a chip card which can be used for rapid immunological tests, for example, with the help of a reading device. The liquids or substances from liquids are detected by means of a sensor array which includes at least two sensors and on which at least one diaphragm is arranged. Individual sensors are spatially separated from each other on a plane by means of walls. The diaphragm can be filled with liquid that is to be analyzed. Sealed reaction chambers are created when pressure is applied to the diaphragm. Pores in the diaphragm are completely closed in the zone of the walls while the pores are merely reduced in size and liquid can continue to be exchanged in zones directly above the sensors.

Abstract: Especially in order to carry out the so-called enzyme-coupled DNA hybridization test in a closed cartridge including a microfluid system, using stored dry reagents, the reagents must be dissolved in the microfluid system and transported into the measuring chamber directly before the measurement. During the dissolution of the reagents in water, air cushions that cannot reach the measuring chamber must absolutely be prevented from forming upstream of the reagent liquid. According to an embodiment of the invention, the liquid measuring sample and the liquid reagents are transported in such a way that the air cushion is directed into the waste line and the measuring sample and the reagents are then introduced into the measuring chamber without any air bubbles. In this way, measuring errors can be avoided.

Abstract: A method for biochemical analysis uses a micro-reaction array with at least two reaction chambers for materials which react together chemically or biochemically. The reaction chambers are smaller than 1 ?l, the reaction chambers are filled together by throughflow, the chemical or biochemical reactions of the substances retained therein then occurs in the individual isolated reaction chambers, thus preventing an interference between the reactions in the individual reaction chambers and the reaction products remain enclosed in the relevant reaction chambers. In the system the planar array has at least two reaction chambers for substances, whereby the reaction chambers are closed with the goal of preventing an exchange of substances.

Abstract: A method is disclosed for calibrating a sensor element, which has an immobilized probe oligonucleotide, via which the bonding of a target nucleic acid (Z) can be detected by the sensor. In at least one embodiment, the method includes: a) bringing the sensor element into contact with a control nucleic acid (K), the melting temperature Tm(K) of which is less than the melting temperature Tm(Z) of the target nucleic acid (Z); b) hybridizing the control nucleic acid (K) to the probe oligonucleotide at a temperature T[p]<Tm(K), and detecting a positive control signal; and optionally c) modifying the stringent conditions such that T[n]>Tm(K) and detecting a negative control signal at a temperature T[n]. According to a refinement of at least one embodiment of the invention, a measuring signal of the target nucleic acid (Z) is measured at a measuring temperature T [mess], where Tm(K)<T[mess]<Tm(Z). The method is suited in particular for the calibration and quality control of microarrays.

Abstract: A process concentrates nucleic acid molecules to be detected of a sample on a surface, with capture molecules that specifically bind the nucleic acid molecules. A support material has a capture probe that can specifically be linked to the nucleic acid molecules to be detected to give complexes. The support material and the nucleic acid molecules of the sample are incubated to form the complexes. The complexes are moved to the surface. At least one portion of the complexes becomes bound to the capture molecules via the capture probe.

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.

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

Abstract: An embodiment of the present invention relates to a system for the integrated and automated analysis of DNA or protein, including a single-use cartridge, an analysis device comprising a control device, and devices for capturing and processing signals. An embodiment of the present invention relates, in particular, to the control device for carrying out a completely automatic process and evaluation of molecular diagnostic analysis via single-use cartridges (Lab-on-a-Chip). The first devices are provided for controlling an analysis process which occurs in the cartridge, subsequently the displacement and the thermostatisation of liquids, and the second devices are provided for processing the signals which are obtained during the analysis. The first and the second devices are synchronised in such a manner that the analysis process of the sample can be carried out in a totally integrated manner thus producing an immediate result.

Abstract: Electrically charged molecules need to be transported in order to create a DNA sensor. The following measures are undertaken: base metals are introduced into a solution as a positive ion; negatively charged molecules are transported in an opposite direction and are enriched in the vicinity of the measuring electrodes. Binding-specific separation of the charged molecules can be achieved by forming metal layers on the measuring electrodes by depositing metal ions from the solution when a suitable potential is selected. Target DNA can more particularly be introduced into the vicinity of the catcher molecules on the measuring electrodes and non-specifically bound DNA can be removed. According to the associated device, the electrode arrangement may be associated with a sacrificial electrode made of more base metal than the material of the measuring electrodes. The measuring electrodes in particular may be made of noble metal, preferably gold, and the sacrificial electrode may be made of copper.

Abstract: A DNA chip includes a carrier and a microarray of spots containing immobilised catcher molecules which are arranged on the carrier. Each spot contains a microelectrode system for the impedance spectroscopic detection of binding events occurring between the catcher molecules and target molecules of an analyte solution applied to the spots. The microelectrode system has a pair of polarisation electrodes in order to produce an alternating electromagnetic field and a pair of sensor electrodes for measuring a voltage drop in the analyte.

Abstract: Especially in order to carry out the so-called enzyme-coupled DNA hybridisation test in a closed cartridge including a microfluid system, using stored dry reagents, the reagents must be dissolved in the microfluid system and transported into the measuring chamber directly before the measurement. During the dissolution of the reagents in water, air cushions that cannot reach the measuring chamber must absolutely be prevented from forming upstream of the reagent liquid. According to an embodiment of the invention, the liquid measuring sample and the liquid reagents are transported in such a way that the air cushion is directed into the waste line and the measuring sample and the reagents are then introduced into the measuring chamber without any air bubbles. In this way, measuring errors can be avoided.

Abstract: A cartridge (card) having a system of microchannels and/or microcavities is used for automated DNA or protein analysis. In at least one embodiment, the microchannels or microcavities include geometrical structures for receiving dry reagents. For the purpose of industrial production, the cartridge is produced from a flat card support, e.g., by injection moulding. The reagents are spotted into the open channels, dried and then the channels are sealed by way of a film. A finished cartridge can thus be provided with a test sample and the fully automated measuring sequence can be initiated by inserting said cartridge into a read-out device.