Abstract: A filtered feedthrough assembly includes a capacitor comprising a top portion, a bottom portion, an outer diameter portion and an inner diameter portion. The inner diameter portion defines at least one aperture extending from the top portion to the bottom portion. A conductive annular member is placed onto the top portion around the at least one aperture. A feedthrough pin extends through each of the apertures and is soldered to the inner diameter portion of the capacitor by application of a solder preform upon the conductive pad of conductive material.

Abstract: In one example, a capacitor structure may include a capacitor comprising a surface that defines at least one feedthrough aperture and a ceramic insulator layer attached to the surface. The surface of the capacitor may include a capacitor registration feature, and the ceramic insulator layer may include a ceramic insulator layer registration feature. The capacitor registration feature and the ceramic insulator layer registration feature may cooperate to substantially align the ceramic insulator layer to the capacitor, e.g., prior to the ceramic layer being attached to surface of the capacitor.

Abstract: An electrical interconnect structure for an implantable medical device includes a feedthrough that has a pin extending therefrom. The pin defines a first end and a middle portion. A bonding surface is formed at the first end of the pin, and the bonding surface has a surface area greater than a cross-sectional area of the pin at its middle portion.

Abstract: An implantable medical device is provided including a housing, an external circuit element extending outwardly from the housing, an internal circuit enclosed by the housing, a feedthrough array disposed along the housing having at least one filtered feedthrough and at least one unfiltered feedthrough, wherein the unfiltered feedthrough is adapted for connection to the outwardly extending circuit element; and including means for minimizing electromagnetic coupling between the filtered feedthrough and the unfiltered feedthrough.

Abstract: A capacitive element for an implantable medical device feedthrough element includes a bore, to receive a feedthrough member, or pin of the filtered feedthrough element, an external surface extending laterally outward from a first opening of the bore, and a recessed area formed in the external surface and extending about an outer perimeter thereof. The recessed area may provide a location on which to apply a conductive material to form a joint that electrically couples the capacitive element to a ferrule of the filtered feedthrough element.

Abstract: The present invention is directed to a ceramic monolith for use as a feedthrough in medical devices and method of making. The monolith includes a first surface, a second surface, and a passageway extending from the first surface to the second surface. The first surface is high temperature co-fired ceramic and the second surface is low temperature co-fired ceramic, and the two ceramics are intermixed in a blended interface located between the first and second surfaces.

Abstract: A capacitive element for an implantable medical device feedthrough element includes a bore, to receive a feedthrough member, or pin of the filtered feedthrough element, an external surface extending laterally outward from a first opening of the bore, and a recessed area formed in the external surface and extending about an outer perimeter thereof. The recessed area may provide a location on which to apply a conductive material to form a joint that electrically couples the capacitive element to a ferrule of the filtered feedthrough element.

Abstract: A capacitor assembly for use in, and a method of assembling, a filtered feedthrough. The termination material present on the inner and outer diameters of the capacitor is absent from a portion of the outer diameter of the capacitor proximate an unfiltered terminal pin, such that high voltage arcing between the unfiltered terminal pin and capacitor is inhibited.

Abstract: A solder joint between a capacitive element and a ferrule of a filtered feedthrough assembly for an implantable medical device is formed from a solder pre-form mounted on a portion of an external surface of the capacitive element, which portion of the external surface may be overlaid with a layer including a noble metal. Another solder joint may be formed between the capacitive member and each feedthrough pin; and, for an assembly including a plurality of feedthrough pins, each of the other solder joints may be formed from a solder pre-form mounted onto the external surface of the capacitive element by inserting each pin through a corresponding ring of a plurality of rings connected together to form the solder pre-form.

Abstract: A capacitor assembly for use in, and a method of assembling, a filtered feedthrough. The capacitor includes an insulative member fixedly attached to its bottom portion to inhibit high voltage arcing. The termination material present on the inner and outer diameters of the capacitor is absent from a portion of the capacitor proximate the bottom portion, e.g., at the insulative member.

Abstract: A determination of an equivalent series resistance (ESR) effect for high frequency filtering performance of a filtered feed-through assembly is described. A low frequency signal is introduced to a filtered feed-through assembly. ESR limit of the filtered feed-through is determined based on the low frequency signal.

Abstract: An electronic module assembly (EMA) for an implantable medical device is disclosed. The EMA includes conductive strips connected to a non-conductive block. The non-conductive block possesses, a top side, a bottom side, a front side and a back side. A seamless non-conductive barrier extends from the bottom side and between the front side and the back side. The barrier prevents a pin from contacting another pin and eliminates welding of the ground pin to the side of the ferrule.

Abstract: An electronic module assembly (EMA) for an implantable medical device is disclosed. The EMA comprises a non-conductive block having a top side, a bottom side, a front side and a back side. A plurality of conductive strips are coupled to the non-conductive block. Each conductive strip possesses a front side and a back side. The back side of each conductive strip extends from the front side across the top side and over to back side of the non-conductive block.

Abstract: A system and method for sealing a capacitor bottom in a filtered feedthrough. The feedthrough comprises a ferrule, a capacitor, at least one terminal pin and a support structure. The support structure includes at least one projection that extends into an aperture of the capacitor. The projection includes an opening through which the at least one terminal pin extends such that, in an assembled state, the terminal pin extends through the opening of the projection and the aperture of the capacitor.

Abstract: A filtered feedthrough assembly includes a capacitor comprising a top portion, a bottom portion, an outer diameter portion and an inner diameter portion. The inner diameter portion defines at least one aperture extending from the top portion to the bottom portion. An conductive pad of conductive material is applied to the top portion around the at least one aperture. A feedthrough pin extends through each of the apertures and is soldered to the inner diameter portion of the capacitor by application of a solder preform upon the conductive pad of conductive material.

Abstract: A filtered feedthrough assembly includes a capacitor comprising a top portion, a bottom portion, an outer diameter portion and an inner diameter portion. The inner diameter portion defines at least one aperture extending from the top portion to the bottom portion. A conductive annular member is placed onto the top portion around the at least one aperture. A feedthrough pin extends through each of the apertures and is soldered to the inner diameter portion of the capacitor by application of a solder preform upon the conductive pad of conductive material.

Abstract: A filtered feedthrough assembly having at least one terminal pin therethrough is provided. The feedthrough assembly comprises a ferrule having a cavity therethrough for receiving the terminal pin, and insulating structure having an upper surface. The insulating structure is disposed within the cavity and around the terminal pin for electrically isolating the pin from the ferrule. A capacitor is disposed around the pin and electrically coupled thereto. The capacitor has a lower surface that is disposed proximate the upper surface, and at least one washer is disposed between the upper surface and the lower surface. To attach the capacitor to the insulating structure, a body of epoxy is substantially confined between the upper surface and the lower surface by the ferrule, the insulating structure, the capacitor, and the at least one washer.

Abstract: A feedthrough assembly for an implantable medical device includes an insulator element hermitically sealed to a ferrule and a feedthrough member, and a capacitive element spaced apart from the insulator element within the ferrule and coupled to the feedthrough member by a conductive material; the conductive material extends in an area between the capacitive element and the feedthrough member. The assembly further includes a heat and pressure deformed thermoplastic adhesive member that extends around the feedthrough member within the ferrule, is located between the capacitive element and the insulator element, and is sealed to an external surface of the capacitive element in order to isolate the conductive material.

Abstract: A medical device feedthrough assembly includes a flange plate formed with a plurality of receptacles. A feedthrough subassembly is mounted within each of the receptacles, and a ferrule of each subassembly is coupled to the flange plate.

Abstract: An electronic module assembly for an implantable medical device includes a non-conductive block having an opening for accepting a feedthrough conductor. The block has opposite first and second ends and opposite first and second sides. A bond pad is located on the first end of the block for electrical connection to a feedthrough conductor, and the bond pad extends to the first side of the block to provide an electrical connection region there.