Abstract: The system invention describes a support and improved method of application and removal. The support, comprised of a network of flexible, non-porous, multi-lumen tubing interlaces at a plurality of junctions to form a lattice structure. Apertures designed to accommodate boney prominences also permit air or water to reach the skin underneath and encourage rapid fluid flow internally through the lattice. A hydrophobic, thermal-resistant, flowable padding layer is injected within a secondary lumen to the lattice structure, spanning its complete surface area. As a result, the breathability of the support is not affected by this padding layer because it mirrors the apertures of the lattice. At least one liquid is injected into the structure and configured to transform into a solid when acted on by an external mechanical stimulus.

Abstract: The system invention describes a support and improved method of application and removal. The support, comprised of a network of flexible, non-porous, multi-lumen tubing interlaces at a plurality of junctions to form a lattice structure. Apertures designed to accommodate boney prominences also permit air or water to reach the skin underneath and encourage rapid fluid flow internally through the lattice. A hydrophobic, thermal-resistant, flowable padding layer is injected within a secondary lumen to the lattice structure, spanning its complete surface area. As a result, the breathability of the support is not affected by this padding layer because it mirrors the apertures of the lattice. At least one liquid is injected into the structure and configured to transform into a solid when acted on by an external mechanical stimulus.

Abstract: Implantable medical devices, and methods of coating same, including a plurality of components disposed on a substrate, and a low surface energy layer deposited as a liquid over at least a first portion of the components and the substrate, the low surface energy layer becoming solidified after deposition and conforming to at least the first portion of the components. The devices further include a biocompatible hermetic coating conforming to and sealingly covering at least a portion of the low surface energy layer.

Abstract: The system invention describes an support and improved method of application and removal. The support, comprised of a network of flexible, non-porous, multi-lumen tubing interlaces at a plurality of junctions to form a lattice structure. Apertures designed to accommodate boney prominences also permit air or water to reach the skin underneath and encourage rapid fluid flow internally through the lattice. A hydrophobic, thermal-resistant, flowable padding layer is injected within a secondary lumen to the lattice structure, spanning its complete surface area. As a result, the breathability of the support is not affected by this padding layer because it mirrors the apertures of the lattice. At least one liquid is injected into the structure and configured to transform into a solid when acted on by an external mechanical stimulus.

Abstract: A support for application to a body area. The support has a network of flexible non-porous tubing interlaced at a plurality of junctions to form a lattice structure. The lattice structure includes apertures to allow for the flow of air and water to the body area. At least one liquid is contained within the network of flexible non-porous tubing and is configured to transform into a solid when acted on by an external stimulus. A padding layer is secured to an internal surface defined on the lattice structure. The padding layer further includes apertures corresponding to the lattice structure apertures such that the flow of air and water to the body area is not impeded by the padding layer.

Abstract: Implantable medical devices, and methods of coating same, including a plurality of components disposed on a substrate, and a low surface energy layer deposited as a liquid over at least a first portion of the components and the substrate, the low surface energy layer becoming solidified after deposition and conforming to at least the first portion of the components. The devices further include a biocompatible hermetic coating conforming to and sealingly covering at least a portion of the low surface energy layer.

Abstract: Implantable medical devices, and methods of coating same, including a plurality of components disposed on a substrate, and a low surface energy layer deposited as a liquid over at least a first portion of the components and the substrate, the low surface energy layer becoming solidified after deposition and conforming to at least the first portion of the components. The devices further include a biocompatible hermetic coating conforming to and sealingly covering at least a portion of the low surface energy layer.

Abstract: Implantable medical devices, and methods of coating same, including a plurality of components disposed on a substrate, and a low surface energy layer deposited as a liquid over at least a first portion of the components and the substrate, the low surface energy layer becoming solidified after deposition and conforming to at least the first portion of the components. The devices further include a biocompatible hermetic coating conforming to and sealingly covering at least a portion of the low surface energy layer.

Abstract: An exhaust-gas turbocharger (1), having a shaft (2) on which are arranged a compressor wheel (3) and a turbine wheel (4), a bearing housing (5) in which are arranged a compressor-side bearing arrangement (6) and a turbine-side bearing arrangement (7) for the shaft (2), an oil inflow line (8) and an oil outflow line (9), and an additional oil accumulator (10) for the bearing arrangements (6, 7) of the shaft (2). The oil accumulator (10) is a pressure accumulator arranged in a branch line (11) of the oil inflow line (8), and a controllable valve (13) is arranged between the oil accumulator (10) and the opening-in point (12) of the branch line (11) into the oil inflow line (8).

Abstract: An implantable medical device including a plurality of components on a substrate, and a biocompatible multi-layer coating applied at least in part by vapor deposition to conform to and sealingly cover at least a portion of the components and/or the substrate. The coating is applied in at least two sets of layers, wherein each set has at least one layer formed by dissociation of a polymeric precursor and then deposition of that precursor, and another layer is a biocompatible liquid.

Abstract: An implantable medical device including a plurality of components on a substrate, and a biocompatible multi-layer polymeric coating applied by vapor deposition to conform to and sealingly cover at least a portion of the components and/or the substrate. The coating is applied in at least two pairs of layers, wherein each pair has one layer formed by dissociation of a precursor and then simple deposition of that precursor, and the other layer is formed by at least one of plasma dissociation and excitation of the precursor to form a plasma-enhanced precursor, and then deposition of the plasma-enhanced precursor.

Abstract: An implantable medical device including a plurality of components on a substrate, and a biocompatible multi-layer coating applied by vapor deposition to conform to and sealingly cover at least a portion of the components and/or the substrate. The coating is applied in at least two sets, each set having first, second and third layers. At least one of the first, second and third layers consist essentially of a polymer such as parylene and at least one of the other two layers of the set consist essentially of inorganic material such that each layer differs in at least one diffusion barrier property from the other layers in the set and adds to an overall barrier effect of the coating.

Abstract: An implantable medical device including a plurality of components on a substrate, and a biocompatible multi-layer coating applied by vapour deposition to conform to and sealingly cover at least a portion of the components and/or the substrate. The coating is applied in at least two sets, each set having first, second and third layers. At least one of the first, second and third layers consist essentially of a polymer such as parylene and at least one of the other two layers of the set consist essentially of inorganic material such that each layer differs in at least one diffusion barrier property from the other layers in the set and adds to an overall barrier effect of the coating.

Abstract: An implantable medical device including a plurality of components on a substrate, and a biocompatible multi-layer polymeric coating applied by vapour deposition to conform to and sealingly cover at least a portion of the components and/or the substrate. The coating is applied in at least two pairs of layers, wherein each pair has one layer formed by dissociation of a precursor and then simple deposition of that precursor, and the other layer is formed by at least one of plasma dissociation and excitation of the precursor to form a plasma-enhanced precursor, and then deposition of the plasma-enhanced precursor.

Abstract: An implantable medical device including a plurality of components on a substrate, and a biocompatible multi-layer coating applied at least in part by vapour deposition to conform to and sealingly cover at least a portion of the components and/or the substrate. The coating is applied in at least two sets of layers, wherein each set has at least one layer formed by dissociation of a polymeric precursor and then deposition of that precursor, and another layer is a biocompatible liquid.