| Patent application number | Description | Published |
|---|
| 20080218989 | THIN FILM DEPOSITION AS AN ACTIVE CONDUCTOR AND METHOD THERFOR - A method includes populating components in a cavity of a substrate, disposing a polymer over the components and within the cavity. The polymer is cured and a thin film is formed on the polymer. In addition, a method includes forming an EMI shield within a medical device by depositing a thin film of metal on a surface within the medical device. The thin film of metal, of gold, aluminum, or copper, is formed by vapor deposition or sputtering. An apparatus includes a first substrate assembly including a first substrate having a cavity. A first set of electronic components are disposed within the cavity, and a first polymer is disposed over the first set of components. Deposited on an outer surface of the first polymer by vapor deposition is a thin film of metal. The thin film of metal is electrically coupled with a ground. A second substrate assembly including a second substrate is coupled with the first substrate assembly. | 09-11-2008 |
| 20080293168 | Method and system of tape automated bonding - A tape automated bonding (TAB) structure which includes a flex tape having a conductive lead pattern formed thereon. The conductive lead pattern includes a plurality of leads configured to form an inner lead bond (ILB) portion of the TAB structure. At least one of the plurality of leads is internally routed and has a contact exposed interior to the ILB portion of the TAB structure. | 11-27-2008 |
| 20090025207 | METHOD AND APPARATUS FOR AN IMPLANTABLE PULSE GENERATOR WITH A STACKED BATTERY AND CAPACITOR - The present subject matter includes one embodiment of an apparatus, comprising: a battery including a plurality of flat battery layers disposed in a battery case, the battery case having a planar battery surface which has a battery perimeter; and a capacitor including a plurality of flat capacitor layers disposed in a capacitor case, the capacitor case having a planar capacitor surface which has a capacitor perimeter, the capacitor stacked with the battery such that the planar battery surface and the planar capacitor surface are adjacent, with the capacitor perimeter and the battery perimeter substantially coextensive; a hermetically sealed implantable housing having a first shell and a lid mated to the first shell at a first opening, the first opening sized for passage of the battery, the capacitor, and the programmable electronics, wherein the battery and the capacitor are disposed in the hermetically sealed implantable housing. | 01-29-2009 |
| 20100318156 | HEADER ASSEMBLIES FOR IMPLANTABLE MEDICAL DEVICES - Embodiments of the invention are related to header assemblies for implantable medical devices, amongst other things. In an embodiment the invention includes a medical device including a header assembly housing. The header assembly housing can include a dielectric material, the header assembly housing can define a port aperture for receiving a connector pin of a stimulation lead. The port aperture can have a first end and a second end and a reflective insert disposed within the header assembly housing proximate to the second end. The reflective insert can be configured to enhance the view of the second end from outside of the header assembly housing. Other embodiments are also included herein. | 12-16-2010 |
| 20110082509 | METHOD AND APPARATUS FOR A SMALL POWER SOURCE FOR AN IMPLANTABLE DEVICE - One example includes a battery that includes a stack of at least one substantially planar anode and at least one substantially planar cathode, wherein the stack defines a contoured exterior, and a battery housing enclosing the stack, the battery housing defining a battery housing exterior, wherein the contoured exterior of the stack is shaped to conform to a contoured interior of the battery housing that approximately conforms to the battery housing exterior, the battery produced by the process of modeling, using fluid dynamics, an exterior of a biocompatible housing and shaping the battery housing to conform to at least some of the exterior of the biocompatible housing. | 04-07-2011 |
| 20110082531 | SIDE MOUNT FEEDTHROUGH SYSTEM FOR SEALED COMPONENTS - The present subject matter provides apparatus and methods for manufacturing an encasement for a component of an implantable medical device having a main circuit board. The method includes forming an encasement aperture on a lateral side of the encasement. The lateral side of the encasement is adapted to be placed substantially parallel to a surface of the main circuit board. A feedthrough assembly is connected through the encasement aperture. The feedthrough assembly includes at least one terminal conductor at least partially passing through the encasement aperture. | 04-07-2011 |
| 20110098763 | VENTED SET SCREW FOR IMPLANTABLE MEDICAL DEVICE - A vented set screw is used to secure a connection between an implantable medical device and an implantable lead. The vented set screw includes one or more venting channels that allow liquid and/or gas to flow out of the implantable medical device when the implantable lead is being inserted into the implantable medical device and secured during an implantation procedure. This prevents pressure from building up at the connection, thereby ensuring proper performance of sensing and/or therapy delivery functions of the implantable medical device. | 04-28-2011 |
| 20110134593 | MEDICAL DEVICE PROFILE MODELED USING FLUID DYNAMICS - The present subject matter, in an example, includes an apparatus for positioning in an implant site. In the example, the apparatus includes a hermetically sealed shell having an exterior shaped as a function of hydrodynamic drag at the implant site. | 06-09-2011 |
| 20110160812 | IMPLANTABLE PULSE GENERATOR WITH A STACKED BATTERY AND CAPACITOR - One example includes a configurable power source system for an implantable device having a predetermined power requirement, the system comprising a housing for a battery and a capacitor, the housing including a distance D between a first internal face and a second internal face, the housing adapted to fit within dimensions of the implantable device, a plurality of batteries of different thicknesses, each battery adapted to fit within a perimeter of the housing, a plurality of capacitors of different thicknesses, each capacitor adapted to fit within the housing and adjacent the battery and a pick and place system adapted to assemble a selected battery from the plurality of batteries and a selected capacitor from the plurality of capacitors with the housing to form a configurable power source at least meeting the predetermined power requirement for the implantable device. | 06-30-2011 |
