Abstract: An anchor fir maintaining a portion of a therapy delivery element within a desired location of a patient has (i) a first opening, (ii) a second opening, (iii) a body member formed of elastic material disposed between the first and second opening, (iv) and a lumen extending though the body member from the first opening to the second opening, and (v) a retention element secured to or integrally formed with the body member for retaining the anchor within a tissue location of a patient.

Abstract: An anchor for maintaining a portion of a therapy delivery element within a desired location of a patient has (i) a first opening, (ii) a second opening, (iii) a body member formed of elastic material disposed between the first and second opening, (iv) and a lumen extending though the body member from the first opening to the second opening, and (v) a retention element secured to or integrally formed with the body member for retaining the anchor within a tissue location of a patient. The therapy delivery element has an outer diameter and an outer surface about which the anchor is disposable. The body member has a first inner diameter defined by the lumen in a relaxed state and a second inner diameter defined by the lumen in a radially stretched state. The first inner diameter is smaller than the outer diameter of the therapy delivery element, which is smaller that the second inner diameter. The lumen is configured to be disposed about at least a portion of the therapy delivery element.

Abstract: An anchor for maintaining a portion of a therapy delivery element within a desired location of a patient has (i) a first opening, (ii) a second opening, (iii) a body member formed of elastic material disposed between the first and second opening, (iv) and a lumen extending though the body member from the first opening to the second opening, and (v) a retention element secured to or integrally formed with the body member for retaining the anchor within a tissue location of a patient. The therapy delivery element has an outer diameter and an outer surface about which the anchor is disposable. The body member has a first inner diameter defined by the lumen in a relaxed state and a second inner diameter defined by the lumen in a radially stretched state. The first inner diameter is smaller than the outer diameter of the therapy delivery element, which is smaller that the second inner diameter. The lumen is configured to be disposed about at least a portion of the therapy delivery element.

Abstract: A battery for use with implantable medical devices, and a method of making the battery. The battery includes a battery housing, a connector block connected to the battery housing, a feedthrough assembly having a ferrule, where at least a portion of the ferrule extends outside the battery housing, and within the connector block.

Abstract: A battery having an electrode assembly located in a housing that efficiently utilizes the space available in many implantable medical devices is disclosed. The battery housing provides a cover and a shallow case a preferably planar, major bottom portion, an open top to receive the cover opposing the bottom portion, and a plurality of sides being radiused at intersections with each other and with the bottom to allow for the close abutting of other components located within the implantable device while also providing for efficient location of the battery within an arcuate edge of the device. The cover and the shallow case being substantially hermetically sealed by a laser weld technique and an insulator member disposed within the case to provide a barrier to incident laser radiation so that during welding radiation does not impinge upon radiation sensitive component(s) disposed within the case.

Abstract: According to the present invention an improved insulator cup, or case liner, enhances electrode coil insertion by reducing the possibility of damage to the coil during insertion, protects electrode and separator from laser radiation during welding, and eases manual inspection of partially assembled components, among other advantages. The improved insulator cup includes a mechanical joint, or hinge-like feature, which pivotably couples opposing parts of the cup and greatly enhances coiled electrode insertion and subsequent component inspection prior to sealing a cover member over an electrode assembly disposed within a housing. The mechanical joint can comprise additional parts that adhere to a divided insulator cup or can be formed as an integral part of an insulator cup (e.g., a linear area of reduced thickness, of apertures, and/or perforations, etc.).

Abstract: Embodiments of the invention provide electrochemical cells for use in implantable medical devices. Embodiments of the invention provide an anode or cathode with a connection tab or tabs that extend a sufficient distance from separation material between the anode and cathode to reduce the heat transferred back to the separation material when the tab is electrically connected to the battery case, cover, or feedthrough pin.

Abstract: A method of forming a head space insulator for an electrochemical cell is presented. A polymer is selected. The polymer has a melting point lower than the melting point of separator material. The polymer is heated to place the polymer into a liquid state. The liquid polymer is introduced over one or more tabs associated with one or more electrode plates.

Abstract: An anode subassembly for use in an implantable electrochemical cell includes a solid anode current collector and an alkali metal anode pressed onto the solid anode current collector such that the solid anode current collector is located on the outer side of the outermost winding of a coiled electrode assembly formed when the anode subassembly is wound with a cathode subassembly. The anode subassembly may further include a spacer formed from a microporous, non-conductive material pressed onto the alkali metal anode on the opposite side from the solid anode current collector.

Abstract: An anode subassembly is provided for use in an implantable electrochemical cell wherein the anode subassembly includes an anode current collector designed to eliminate perforation edges in the final, outermost turn of a coiled electrode assembly. The anode current collector may be of a reduced size, discontinuous, or formed from alternating perforated and solid areas. The anode subassembly may further include reinforcing elements to support a thin anode layer in the outermost coil of a coiled, anode-limited cell. Reinforcing elements may take the form of a spacer, extensions extending from a reduced-size anode current collector, or strips of alkali metal.

Abstract: An anode-limited battery and method of assembly are provided in which a lithium anode subassembly is constructed from two pieces of lithium foil. An elongated thicker piece of lithium foil is cohesively bonded at one end to a shorter, thinner piece of lithium foil. An optional current collector stabilizes the area of the cohesive bond. The thicker lithium foil forms the inner windings of a coiled electrode, which face reactive cathode material on both sides. The thinner foil forms the outermost winding, which faces reactive cathode material on only one side. Thus, an appropriate amount of lithium is available for cathode discharge. The method of electrode assembly allows a narrow tolerance of the lithium anode such that the benefits of an anode-limited cell may be realized.

Abstract: An anode-limited battery and method of assembly are provided in which a lithium anode subassembly is constructed from two pieces of lithium foil. An elongated thicker piece of lithium foil is cohesively bonded at one end to a shorter, thinner piece of lithium foil. An optional current collector stabilizes the area of the cohesive bond. The thicker lithium foil forms the inner windings of a coiled electrode, which face reactive cathode material on both sides. The thinner foil forms the outermost winding, which faces reactive cathode material on only one side. Thus, an appropriate amount of lithium is available for cathode discharge. The method of electrode assembly allows a narrow tolerance of the lithium anode such that the benefits of an anode-limited cell may be realized.

Abstract: The present invention relates to an improved system and method for cooling electronic devices. The present system is particularly adapted for cooling computer equipment. The system comprises a sealed enclosure which houses one or more heat generating electronic devices; a blower; and a heat exchanger. The sealed enclosure may be pressurized with a gas medium such as dry nitrogen up to a pressure of approximately two atmospheres. The elevated pressure increases the gas density, effectively increasing the mass flow rate and heat carrying capacity of the gas. The blower is also a constant volume device such that it can move the same volume of gas regardless of density. Accordingly, for a given heat load, the size of the blower may be reduced. Or, alternatively, a given blower can cool a device having a higher heat load. Finally, by pressurizing the enclosure, the present invention eliminates the need to size a forced air cooling system based on high elevation requirements.