Abstract: The invention relates to a method and a corresponding arrangement for sequencing at least two biopolymers (6), wherein for each biopolymer (6) a sequence signal is picked up by a respective measured variable pickup on the basis of the sequence of the biopolymer (6), the sequence signals are transferred to a shift register (16) and buffer-stored therein, the buffer-stored sequence signals are transferred from the shift register (16) sequentially to an evaluation device (26) and evaluated therein. Each sequence signal is preferably produced here by means of a nanopore arrangement (10). A corresponding sequencing arrangement (11) has the measured variable pickups and the shift register (16) integrated in it, preferably in an electrical circuit, that is to say on a sensor array, for example. Each sequence signal can be amplified here by a preamplifier (14) prior to transfer to the shift register (16).

Abstract: An arrangement for determining the concentration of nucleic acids in a sample in a microfluidic device. In at least one embodiment, the arrangement having a) a first chamber into which a the sample is introduced, b) an element in the first chamber for carrying out a number of cycles of an amplification reaction to be carried out in cycles for amplifying nucleic acids, c) a second chamber, connectable to the first chamber by way of fluidic communication, equipped with an element to determine concentrations of amplified nucleic acids, d) a control unit to introduce a defined volume of a solution containing reagents for the amplification reaction into the first chamber and to transfer a defined volume from said first chamber to the second chamber.

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. Which valves are actuated being changeable by movement of projections relative to array of valves so as to change which valves the projections are pressed against.

Abstract: At least one embodiment of the invention relates to an arrangement for thermocyclization of a substance. At least one embodiment of the invention also relates to a method for the thermocyclization of a substance, including: the controllable valves automatically close the PCR chamber after the test fluid has been introduced into the PCR-chamber, and the properties for the memory metal or bimetal elements are used for closing the valves when a predetermined temperature has been exceeded. As a result, the mechanical actuator, which is used to actuate the valves, is thermally coupled to the heating/cooling element in order to carry out the thermocyclization.

Abstract: A system for the integrated and automated analysis of DNA or protein, including a single-use cartridge, with an analysis device having a control device, and devices for capturing and processing signals, the control device carrying out a completely automatic process and evaluation of molecular diagnostic analysis via single-use cartridges (Lab-on-a-Chip). Controlling of an analysis process, which occurs in the cartridge, involves the subsequent displacement and thermostatisation of liquids with a first device, and with a second device the signals which are obtained during the analysis are processed. The first and the second devices are synchronized 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: A method for the integrated and automated analysis of DNA or protein, including a single-use cartridge, with an analysis device having a control device, and devices for capturing and processing signals, the control device carrying out a completely automatic process and evaluation of molecular diagnostic analysis via single-use cartridges (Lab-on-a-Chip). Controlling of an analysis process, which occurs in the cartridge, involve the subsequent displacement and thermostatisation of liquids with a first device, and with a second device the signals which are obtained during the analysis are processed. The first and the second devices are synchronized 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: An apparatus for detecting liquids or substances from liquids in spatially separate reaction zones using a plug-in module or a chip card for rapid immunological tests, for example, with the help of a reading device. The liquids or substances from liquids are detected by a sensor array 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 is 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. No liquid can be exchanged between adjacent reaction chambers as long as pressure is applied to and compresses the diaphragm.

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: An assembly for nucleic acid sequencing by tunnel current analysis has at least two electrically conductive particles having a diameter from 1 nm to 100 nm and at least two electrically insulating particles having a diameter from 1 nm to 100 nm. The particles are in particular spherically shaped. The assembly also has at least two first electrodes for contacting the electrically conductive particles and a substrate on which the first electrodes and the particles are arranged. The four particles are arranged substantially in a planar square. The conductive particles lie diagonally opposite each other, and the insulating particles lie diagonally opposite each other. The gap between the four particles is used as a solid-state nanopore for nucleic acid sequencing.

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 synchronized 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: 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: 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 assembly and a method are disclosed for analyzing nucleic acid sequences by way of so-called sequencing-by-synthesis. According to an embodiment of the invention, a chemical substance group that is released when a nucleotide bonds to a nucleic acid sequence to be sequenced is detected. The reagents are applied by way of a spraying device to a sensor that detects the released substance group. This has the advantage that no lateral flow occurs. The rate of false-negative and false-positive results is significantly reduced. Furthermore, a small amount of the reagent is sufficient to completely wet the sensor. Filling of the supply and discharge lines as for a flow cell is not necessary.

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: The invention relates to an arrangement (1) and to a method for the electrical detection of liquid samples (5) by means of lateral flow assays. The lateral flow assay comprises a membrane (4) that is arranged on a front side of a first carrier (2). The first carrier (2) is electrically insulating. On the front side of the first carrier (2) between the carrier (2) and the membrane (4), electrically conductive electrodes (3) are arranged in direct contact with the membrane (4).

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 center-to-center in the range of micrometers. The pH and/or pO2 can be measured in the environment of a living cell.

Abstract: A method for identification and quantification of at least one single-stranded target nucleic acid and a kit for detection of at least one single-stranded target nucleic acid in a sample are described. The method includes contacting at least one solid carrier that includes at least one capture oligonucleotide immobilized thereon with at least one complementary-strand oligonucleotide, at least one single-stranded target nucleic acid, and at least one reporter oligonucleotide that includes a label. The target nucleic acid is identified by reading the label of the reporter oligonucleotide on the carrier.

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: 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: A module for processing a biological sample for an analysis test is disclosed. The processing module includes, in at least one embodiment, an interface at which the processing module can be connected to a cartridge with a lab-on-a-chip, in which cartridge the analysis steps are carried out. A biochip kit is also disclosed. In at least one embodiment, the biochip kit includes one or more processing modules which are intended for different sample materials and which can be connected to the same cartridge type.