Abstract: A micromechanical sound transducer system and a corresponding manufacturing method, in which the micromechanical sound transducer system includes a substrate having a front side and a back side, the substrate having a through opening extending between the back side and the front side, and a coil configuration on the front side having a coil axis, which runs essentially parallel to the front side, the coil configuration covering the through opening at least partially. Also provided is a magnet device, which is situated so as to allow for an axial magnetic flux to be generated through the coil configuration. The coil configuration has a winding device which has at least first winding sections made from at least one layer of a low-dimensional conductive material, the coil configuration being configured to inductively detect and/or generate sound.

Abstract: A microneedle array applicator is configured to apply a microneedle array in cosmetic and medical applications. The microneedle array applicator has a holding apparatus configured to define detachable holding of a microneedle array comprising a planar substrate. The microneedle array applicator also has a drive mechanism for driving the microneedle array in a first direction perpendicular to the planar substrate and in a second direction parallel to the planar substrate. A method for applying a microneedle array includes the microneedle array applicator enabling safe breaking off of the microneedles, optionally laden with an active ingredient, in the skin.

Abstract: A microfluidic cell for the dielectrophoretic separation, accumulation, and/or lysis of polarizable bioparticles, including an interdigital electrode system composed of two electrode groups having interdigitated electrodes, and a micromixer having microchannels and microelevations. The interdigital electrode system and the micromixer are situated on the same side of the cell to improve the separation, accumulation, and/or lysis characteristics. Moreover, also described is a microfluidic system which includes such a microfluidic cell, and use thereof, and a method for separating, accumulating, and/or lysing polarizable bioparticles.

Abstract: A manufacturing method for a porous microneedle array includes: forming a plurality of porous microneedle arrays, each having at least one microneedle and a porous carrier zone lying beneath it on the face of a semiconductor substrate; forming an interlayer between a non-porous residual layer of the semiconductor substrate located on the back side of the semiconductor substrate and the carrier zone, which has greater porosity than the carrier zone; detaching the residual layer from the carrier zone by breaking up the interlayer; and separating the microneedle arrays into corresponding chips.

Abstract: An applicator for treating skin, includes a housing, in which a device for perforating an area of skin is arranged, wherein the device for perforating the skin can be brought into contact with the area of skin through an opening in the housing. At least one device for disinfecting is additionally arranged in the housing, and the device for disinfecting acts upon the area of skin through the same opening. With the applicator, a particularly secure and simple handling can be achieved.

Abstract: A system having a medication reservoir for a medication dosing apparatus for administering a liquid medication, and having a medication supply container holding the liquid medication, a filling device being provided for the automatic filling of the medication reservoir with the medication coming from the medication supply container. Fluidic connections may be provided between individual components for transfer and filling of the liquid medication. This system for administering a medication has the advantage that reliable and simple filling of the medication may be performed.

Abstract: A method for manufacturing a micropump, which may be for the metered delivery of insulin, multiple layers being situated on the front side of a first carrier layer, which has a front side and a rear side, and microfluidic functional elements being formed by structuring at least one of the layers. It is provided that the structuring of the at least one layer for manufacturing all microfluidic functional elements is exclusively performed by front side structuring. Furthermore, a micropump is disclosed.

Abstract: A micro valve includes a first valve chamber and a second valve chamber as well as a closing element, which is adjustable between an opening position, in which the valve chambers are connected to each other, and a closing position in which the valve chambers are separated from each other. A reference chamber is provided, which is delimited by the closing element.

Abstract: A method for active hybridization in microarrays includes pumping an already prepared sample through a denaturing unit with a microarray and then through a reaction region which is spatially separate from the denaturing unit. The denatured reactive sample components are hybridized in the reaction region.

Abstract: An array for placement on the skin of a human or animal patient for the purpose of the transdermal application of pharmaceuticals, toxins or active agents, having microneedles that are situated on a carrier substrate, the microneedles having a preset breaking point in the area of the transition to the carrier substrate.

Abstract: A microarray comprises a carrier substrate and a plurality of immobilization particles configured to immobilize capture molecules. Each immobilization particle comprises a first sub-section bonded to the carrier substrate and a second sub-section which is exposed.

Abstract: A method for manufacturing porous microstructures in a silicon semiconductor substrate, porous microstructures manufactured according to this method, and the use thereof.

Abstract: A method for producing porous microneedles (10) situated in an array on a silicon substrate includes: providing a silicon substrate, applying a first etching mask, patterning microneedles using a DRIE process (“deep reactive ion etching”), removing the first etching mask, at least partially porosifying the Si substrate, the porosification beginning on the front side of the Si substrate and a porous reservoir being formed.

Abstract: An applicator for treating skin, includes a housing, in which a device for perforating an area of skin is arranged, wherein the device for perforating the skin can be brought into contact with the area of skin through an opening in the housing. At least one device for disinfecting is additionally arranged in the housing, and the device for disinfecting acts upon the area of skin through the same opening. With the applicator, a particularly secure and simple handling can be achieved.

Abstract: A production process for a microneedle arrangement and a corresponding microneedle arrangement as well as a use for it is disclosed. The process has the following steps: forming an etching mask in grid form, with grid bars with corresponding grid crossing regions and grid openings in between on a substrate; carrying out an etching process to form the microneedle arrangement on the substrate using the etching mask and removing the etching mask. The etching mask in grid form has at least some of the grid crossing regions flat reinforcing regions, which extend beyond the grid bars.

Abstract: A method for manufacturing porous microstructures in a silicon semiconductor substrate, porous microstructures manufactured according to this method, and the use thereof.

Abstract: A medication dosing device for administering a liquid medication, having a housing, the housing having a medication reservoir, a medication dosing unit, a drive for conveying the medication, an administration needle, a power supply unit, and an electrical control system. The medication reservoir, the medication dosing unit, and the administration needle are jointly situated in a unit which may be inserted .into the housing and removed from the housing. The medication dosing device has the advantage that it may be easily manufactured and cost-effectively operated.

Abstract: A microfluidic cell for the dielectrophoretic separation, accumulation, and/or lysis of polarizable bioparticles, including an interdigital electrode system composed of two electrode groups having interdigitated electrodes, and a micromixer having microchannels and microelevations. The interdigital electrode system and the micromixer are situated on the same side of the cell to improve the separation, accumulation, and/or lysis characteristics. Moreover, also described is a microfluidic system which includes such a microfluidic cell, and use thereof, and a method for separating, accumulating, and/or lysing polarizable bioparticles.

Abstract: A microfluidic cell for the dielectrophoretic separation, accumulation, and/or lysis of polarizable bioparticles, including an interdigital electrode system composed of two electrode groups having interdigitated electrodes, a flat electrode in which the interdigital electrode system and the flat electrode are situated on opposite sides of the cell in order to improve the separation, accumulation and/or lysis characteristics. Moreover, a microfluidic system which includes such a microfluidic cell, and use thereof, and a method for separating, accumulating, and/or lysing polarizable bioparticles is also described.

Abstract: A manufacturing method for a porous microneedle array includes: forming a plurality of porous microneedle arrays, each having at least one microneedle and a porous carrier zone lying beneath it on the face of a semiconductor substrate; forming an interlayer between a non-porous residual layer of the semiconductor substrate located on the back side of the semiconductor substrate and the carrier zone, which has greater porosity than the carrier zone; detaching the residual layer from the carrier zone by breaking up the interlayer; and separating the microneedle arrays into corresponding chips.