Abstract: Disclosed is a mechanical circulatory support system for transcatheter delivery to the heart, having a removable guidewire aid to assist with inserting the guidewire along a path that avoids a rotating impeller. The system may comprise a catheter shaft and a circulatory support device carried by the shaft. The device may comprise a tubular housing, an impeller and the guidewire aid. The guidewire aid may include a removable guidewire guide tube. The guide tube may enter a first guidewire port of the tubular housing, exit the tubular housing via a second guidewire port on a side wall of the tubular housing on a distal side of the impeller, enter a third guidewire port on a proximal side of the impeller, and extend proximally through the catheter shaft.

Abstract: Disclosed is a minimally invasive miniaturized percutaneous mechanical circulatory support system. The system may be placed across the aortic valve via a single femoral arterial access point. The system includes a low profile axial rotary blood pump carried by the distal end of a catheter. The system can be percutaneously inserted through the femoral artery and positioned across the aortic valve into the left ventricle. The device actively unloads the left ventricle by pumping blood from the left ventricle into the ascending aorta and systemic circulation. A magnetic drive and encased motor housing allows for purgeless operation for extended periods of time to treat various ailments, for example more than six hours as acute therapy for cardiogenic shock.

Abstract: A minimally invasive miniaturized percutaneous mechanical circulatory support system for transcatheter delivery of a pump to the heart that actively unloads the left ventricle by pumping blood from the left ventricle into the ascending aorta and systemic circulation. The pump may include a tubular housing, a motor, an impeller configured to be rotated by the motor. The impeller may be rotated by the motor, via a shaft with an annular polymeric seal around the shaft, or via a magnetic drive. The system may have an insertion tool having a tubular body and configured to axially movably receive the circulatory support device, and an introducer sheath configured to axially movably receive the insertion tool.

Abstract: The invention relates to an electronics module (102) for a ventricular assist device, wherein the ventricular assist device has a motor housing for accommodating a pump motor. The electronics module (102) comprises an electronics section (204) for accommodating at least one electronic component (206) and/or at least one electrically conductive contacting element (208), and a coupling section (202) designed as a joint between the motor housing (104) and the electronics section (204) or as a separate component to be joined, wherein the motor housing (104) and the electronics section (204) are combined or can be combined via the coupling section (202) with one another to form a fluid-tight module housing (104) to be arranged in a blood vessel.

Abstract: A sensor element for detecting at least one property of a measuring gas in a measuring gas chamber, in particular for detecting a portion of a gas component in the measuring gas or a temperature of the measuring gas. The sensor element includes a first substrate, a second substrate, and a sensor chip. The sensor chip includes at least one solid electrolyte diaphragm, a first electrode, and a second electrode. The first substrate and the second substrate are connected to each other via at least one glass ceramic. The glass ceramic is manufactured from a material which includes at least SiO2, MgO, Al2O3, as well as ZnO and/or B2O3.

Abstract: A device for detecting at least one gaseous analyte comprises a detection section including a semiconductor substrate and at least one sensor element, which is arranged on the semiconductor substrate. The at least one sensor element includes two electrodes and a solid electrolyte layer arranged between the electrodes. The device also comprises a protective cap configured to cover the at least one sensor element, and at least one temperature-control unit configured for temperature control of the protective cap. The at least one temperature-control unit is arranged on the protective cap. The protective cap is formed from a semiconductor material. The device further comprises a diffusion section having a plurality of passage openings for the gaseous analyte arranged at least in a partial section of the protective cap.

Abstract: A device for detecting at least one gaseous analyte comprises a detection section including a semiconductor substrate and at least one sensor element, which is arranged on the semiconductor substrate. The at least one sensor element includes two electrodes and a solid electrolyte layer arranged between the electrodes. The device also comprises a protective cap configured to cover the at least one sensor element, and at least one temperature-control unit configured for temperature control of the protective cap. The at least one temperature-control unit is arranged on the protective cap. The protective cap is formed from a semiconductor material. The device further comprises a diffusion section having a plurality of passage openings for the gaseous analyte arranged at least in a partial section of the protective cap.

Abstract: A sensor element is described that includes at least one semiconductor component having a gas-sensitive layer which is attached to a substrate by the flip-chip method, the gas-sensitive layer facing the substrate and a supply arrangement being provided to supply a gas to be examined to the gas-sensitive layer. The semiconductor component is enclosed in a casing. Also described is a method for manufacturing the sensor element, in which a semiconductor component having a gas-sensitive layer is attached by the flip-chip method to a substrate in such a way that the gas-sensitive layer faces the substrate. After that, the casing is applied by a plasma sputtering method, in particular an atmospheric plasma sputtering method. Finally, a use of the sensor element in the exhaust system of an internal combustion engine is also described.

Abstract: An ignition laser, includes a laser-active solid-state body, a housing and a combustion chamber window, the housing having an inner sleeve and an outer sleeve. An insert is provided between the inner sleeve and the outer sleeve, the insert and the combustion chamber window being joined sealingly and integrally.

Abstract: A sensor element of a gas sensor for determining gas components in gas mixtures includes a field effect transistor and/or a diode which has a current flow which changes upon contact with a gas to be detected, and which is positioned in a manner protected, by a protective cap, from direct access by the gas mixture. The protective cap has a heating element, a glass former, and/or an oxidation catalyst.

Abstract: An electronic component for high-temperature applications includes a ceramic carrier and a semiconductor element. The ceramic carrier comprises a ceramic substrate having a content of alkali metal compounds of ?0.5%, more particularly ?0.05%, and the ceramic substrate is selected from the group consisting of: a ceramic substrate comprising aluminium oxide, anorthite, a filler having a coefficient of thermal expansion of ?4.0*10?6K?1 and glass; a ceramic substrate comprising aluminium oxide, celsian, a filler having a coefficient of thermal expansion of ?4.0*10?6K?1 and glass; and a ceramic substrate comprising an alkaline earth metal silicate glass having a silicon dioxide content of >50 mol %, boron oxide, and a filler having a coefficient of thermal expansion of <4.0*10?6K?1. The component prevents temperature damage at high temperatures and has constant properties, such as electrical insulation properties, up to 500° C.

Abstract: The present invention relates to a method for passivating a semiconductor component having at least one chemosensitive electrode that is blinded by the application of a glass layer. The present invention also relates to a device for detecting at least one substance included in a fluid stream, including at least one semiconductor component acting as a measuring sensor as well as at least one semiconductor component acting as a reference element, the semiconductor components each having a chemosensitive electrode, and the chemosensitive electrode of the semiconductor component acting as the reference element being passivated. For the passivation, a glass layer may be applied at least to the chemosensitive electrode of the semiconductor component acting as reference element.

Abstract: An ignition laser, includes a laser-active solid-state body, a housing and a combustion chamber window, the housing having an inner sleeve and an outer sleeve. An insert is provided between the inner sleeve and the outer sleeve, the insert and the combustion chamber window being joined sealingly and integrally.

Abstract: A sensor element of a gas sensor for determining gas components in gas mixtures includes a field effect transistor and/or a diode which has a current flow which changes upon contact with a gas to be detected, and which is positioned in a manner protected, by a protective cap, from direct access by the gas mixture. The protective cap has a heating element, a glass former, and/or an oxidation catalyst.

Abstract: A sensor element is described that includes at least one semiconductor component having a gas-sensitive layer which is attached to a substrate by the flip-chip method, the gas-sensitive layer facing the substrate and a supply arrangement being provided to supply a gas to be examined to the gas-sensitive layer. The semiconductor component is enclosed in a casing. Also described is a method for manufacturing the sensor element, in which a semiconductor component having a gas-sensitive layer is attached by the flip-chip method to a substrate in such a way that the gas-sensitive layer faces the substrate. After that, the casing is applied by a plasma sputtering method, in particular an atmospheric plasma sputtering method. Finally, a use of the sensor element in the exhaust system of an internal combustion engine is also described.

Abstract: The invention relates to a method for producing a piezoelectric actuator in which a metallization paste is applied to a sintered piezoelectric stack and a flexible metal electrode is arranged on top of the paste. In a subsequent baking or firing step, a base metallic coating is formed from the metallization paste, whereby the base coating is permanently connected to the piezoelectric stack and to the flexible metal electrode. Alternatively, the metallization paste can be applied to a green body which is subsequently sintered so that a first layer of a base metallic coating is formed in the sintering step. A metallization paste is applied to the first layer in a similar manner and a flexible metal electrode is arranged thereon, whereby the metal electrode becomes fixed during a second baking step.

Abstract: The present invention relates to a method for passivating a semiconductor component having at least one chemosensitive electrode that is blinded by the application of a glass layer. The present invention also relates to a device for detecting at least one substance included in a fluid stream, including at least one semiconductor component acting as a measuring sensor as well as at least one semiconductor component acting as a reference element, the semiconductor components each having a chemosensitive electrode, and the chemosensitive electrode of the semiconductor component acting as the reference element being passivated. For the passivation, a glass layer may be applied at least to the chemosensitive electrode of the semiconductor component acting as reference element.

Abstract: A method for preparing ceramic green compacts for ceramic assemblies, especially ceramic multilayer assemblies. First, a dispersing agent solution is prepared by homogenizing a dispersing agent in a solvent mixture. Then, a binder solution is prepared by homogenizing a solvent mixture, a binder made of acrylatemethacrylate polymer and a softener. After preparing a first dispersion by homogenizing a ceramic powder and the dispersing agent solution and subsequent deagglomerization, a second dispersion is prepared by homogenizing the first dispersion and the binder solution, and subsequently removing air and highly volatile solvent components from the second dispersion.

Abstract: A gas sensor, in particular for determining the oxygen content in exhaust gases of internal combustion engines, having a housing, a sensor element having a multi-layer design which is situated in the housing, and connecting lines lead to the outside for contacting the sensor element. A contacting element of a connecting line penetrates a layer of the sensor element and part of an insulating element situated outside the sensor element. For contacting the sensor element, such a contact configuration makes it possible to directly contact the contacting element of the connecting line, which may be arranged as a contacting pin, to the printed conductor which is formed inside the sensor element.

Abstract: A method for preparing ceramic green compacts for ceramic assemblies, especially ceramic multilayer assemblies. First, a dispersing agent solution is prepared by homogenizing a dispersing agent in a solvent mixture. Then, a binder solution is prepared by homogenizing a solvent mixture, a binder made of acrylatemethacrylate polymer and a softener. After preparing a first dispersion by homogenizing a ceramic powder and the dispersing agent solution and subsequent deagglomerization, a second dispersion is prepared by homogenizing the first dispersion and the binder solution, and subsequently removing air and highly volatile solvent components from the second dispersion.