公开(公告)号：US20130184796A1

公开(公告)日：2013-07-18

申请号：US13742781

申请日：2013-01-16

Applicant: Greatbatch Ltd.

Inventor： Thomas Marzano ,  Keith W. Seitz ,  Robert A. Stevenson ,  Xiaohong Tang ,  William C. Thiebolt ,  Christine A. Frysz ,  Richard L. Brendel ,  Jason Woods ,  Steven W. Winn ,  Dominick J. Frustaci ,  Buehl E. Truex ,  Donald Hickel, Jr.

IPC: A61N1/05

CPC classification number: A61N1/3754 ,  A61N1/05 ,  A61N1/08 ,  A61N1/372 ,  A61N1/375 ,  B23K35/3013 ,  C22C29/12 ,  H01G2/103 ,  H01G4/005 ,  H01G4/12 ,  H01G4/30 ,  H01G4/35 ,  H01G4/40 ,  H01R43/00 ,  H02G3/22 ,  Y10T156/1052

Abstract: An elevated feedthrough is attachable to a top or a side of an active implantable medical device. The feedthrough includes a conductive ferrule and a dielectric substrate. The dielectric substrate is defined as comprising a body fluid side and a device side disposed within the conductive ferrule. The dielectric substrate includes a body fluid side elevated portion generally raised above the conductive ferrule. At least one via hole is disposed through the dielectric substrate from the body fluid side to the device side. A conductive fill is disposed within the at least one via hole forming a hermetic seal and electrically conductive between the body fluid side and the device side. A leadwire connection feature is on the body fluid side electrically coupled to the conductive fill and disposed adjacent to the elevated portion of the dielectric substrate.

Abstract translation: 升高的馈通可附接到有源可植入医疗装置的顶部或侧面。 馈通包括导电套圈和电介质基片。 电介质基板被定义为包括体液侧和设置在导电套圈内的器件侧。 电介质基片包括通常在导电套圈上方升高的体液侧提升部分。 至少一个通孔穿过电介质基底从体液侧设置到器件侧。 导电填料设置在至少一个通孔内，形成气密密封并在体液侧和装置侧之间导电。 引线连接特征在体液侧电耦合到导电填充物并且邻近电介质基底的升高部分设置。

公开(公告)号：US12272899B2

公开(公告)日：2025-04-08

申请号：US18736643

申请日：2024-06-07

Applicant: Greatbatch Ltd.

Inventor： Thomas Marzano ,  Keith W. Seitz ,  Robert A. Stevenson ,  Christine A. Frysz ,  Marc Gregory Martino

IPC: H01R13/52 ,  A61N1/375 ,  H01G4/35 ,  H01R13/426 ,  H01R13/719

Abstract: A feedthrough terminal pin connector assembly for an active implantable medical device (AIMD) includes first and second terminal pin connectors, each comprising a sidewall having an exterior surface spaced from an interior surface defining a connector opening extending along a longitudinal axis. At least a first portion of the sidewall is electrically conductive. An electrically conductive compliant structure is supported by the electrically conductive portion of the sidewall in each of the first and second connector openings. A common housing contains the first and second terminal pin connectors with an insulative material electrically isolating the first and second electrically conductive sidewall portions from each other. The common housing is configured to be supported on a circuit board having at least a first and a second electrical circuits with the first and second electrically conductive portions being electrically connected to the respective first and second electrical circuits.

公开(公告)号：US12246183B1

公开(公告)日：2025-03-11

申请号：US18631709

申请日：2024-04-10

Applicant: Greatbatch Ltd.

Inventor： Jason Woods ,  Robert A. Stevenson ,  Christine A. Frysz ,  Thomas Marzano ,  Keith W. Seitz

IPC: A61N1/375 ,  F16B43/00 ,  H01G4/35 ,  H01R13/52 ,  H01R13/533 ,  H05K1/02

Abstract: A self-centering washer is positioned between a feedthrough and a filter circuit board. The washer has openings through which first and second terminal pins extend. A first opening has an inner arcuate portion contacting the first terminal pin and an outer perimeter portion exposing the braze sealing the terminal pin to the insulator. A second opening has an inner arcuate portion contacting the second terminal pin and an outer perimeter portion exposing the braze sealing the terminal pin to the insulator. In an imaginary configuration with the first and second washer openings superimposed one on top of the other, the cumulative arcuate distance of the inner arcuate portions about one of the terminal pins, subtracting overlap, results in a gap between the superimposed washer openings that is less than a diameter of the first and second terminal pins so that the washer is prevented from lateral movement.

公开(公告)号：US12149021B2

公开(公告)日：2024-11-19

申请号：US17561048

申请日：2021-12-23

Applicant: Greatbatch Ltd.

Inventor： Thomas Marzano ,  Keith W. Seitz ,  Robert A. Stevenson ,  Christine A. Frysz ,  Marc Gregory Martino

IPC: H01R13/52 ,  A61N1/375 ,  H01G4/35 ,  H01R13/426 ,  H01R13/719

Abstract: A hermetic feedthrough terminal pin connector for an active implantable medical device (AIMD) includes an electrical insulator hermetically sealed to an opening of an electrically conductive ferrule. A feedthrough terminal pin is hermetically sealed to and disposed through the insulator, the feedthrough terminal pin extending outwardly beyond the insulator on the inside of the casing of the AIMD. A circuit board is disposed on the inside of the casing of the AIMD. A terminal pin connector includes: an electrically conductive connector housing disposed on the circuit board, wherein the connector housing is electrically connected to at least one electrical circuit disposed on the circuit board; and at least one electrically conductive prong supported by the connector housing, the at least one prong contacting and compressed against the feedthrough terminal pin, the at least one prong making a removable electrical connection.

公开(公告)号：US11406817B2

公开(公告)日：2022-08-09

申请号：US16880392

申请日：2020-05-21

Applicant: Greatbatch Ltd.

Inventor： Robert A. Stevenson ,  Christine A. Frysz ,  Thomas Marzano ,  Keith W. Seitz

IPC: A61N1/08 ,  H01G4/005 ,  H01G4/30 ,  H01G4/35 ,  H01G4/236 ,  A61N1/375 ,  H01G4/12 ,  H03H1/00 ,  A61N1/37

Abstract: A filtered feedthrough assembly includes a ferrule configured to be installed in an AIMD housing. An insulator is disposed within a ferrule opening. A conductive pathway is disposed within a passageway through the insulator. A filter capacitor is disposed on a device side having active and ground electrode plates disposed within a capacitor dielectric k greater than 0 and less than 1,000. A capacitor active metallization is electrically connected to the active electrode plates. A ground capacitor metallization is electrically connected to the ground electrode plates. The filter capacitor is the first filter capacitor electrically connected to the conductive pathway coming from a body fluid side into the device side. An active electrical connection electrically connects the conductive pathway to the capacitor active metallization. A ground electrical connection electrically connects the ground capacitor metallization to the ferrule. The filter capacitor is a flat-through or an X2Y attenuator filter capacitor.

公开(公告)号：US20220115806A1

公开(公告)日：2022-04-14

申请号：US17561048

申请日：2021-12-23

Applicant: Greatbatch Ltd.

Inventor： Thomas Marzano ,  Keith W. Seitz ,  Robert A. Stevenson ,  Christine A. Frysz ,  Marc Gregory Martino

IPC: H01R13/52 ,  H01R13/426 ,  H01G4/35 ,  H01R13/719 ,  A61N1/375

Abstract: A hermetic feedthrough terminal pin connector for an active implantable medical device (AIMD) includes an electrical insulator hermetically sealed to an opening of an electrically conductive ferrule. A feedthrough terminal pin is hermetically sealed to and disposed through the insulator, the feedthrough terminal pin extending outwardly beyond the insulator on the inside of the casing of the AIMD. A circuit board is disposed on the inside of the casing of the AIMD. A terminal pin connector includes: an electrically conductive connector housing disposed on the circuit board, wherein the connector housing is electrically connected to at least one electrical circuit disposed on the circuit board; and at least one electrically conductive prong supported by the connector housing, the at least one prong contacting and compressed against the feedthrough terminal pin, the at least one prong making a removable electrical connection.

公开(公告)号：US20210038902A1

公开(公告)日：2021-02-11

申请号：US17077337

申请日：2020-10-22

Applicant: Greatbatch Ltd.

Inventor： Robert A. Stevenson ,  Keith W. Seitz ,  Jason Woods ,  Christine A. Frysz

IPC: A61N1/375 ,  A61N1/39

Abstract: An enhanced RF switchable filtered feedthrough for real-time identification of the electrical and physical integrity of an implanted AIMD lead includes a DOUBLE POLE RF switch disposed on the device side. Additionally, the RF switchable filtered feedthrough can optionally include transient voltage suppressors (TVS) and an MRI mode. In an embodiment, a DOUBLE POLE RF switch selectively disconnects EMI filter capacitors so that an RF test/interrogation signal is sent from the AIMD down into an implanted lead(s). The reflected RF signal is then analyzed to assess implanted lead integrity including lead body anomalies, lead insulation defects, and/or lead conductor defects. The Double Pole switch is configured to be controlled by an AIMD control signal to switch between FIRST and SECOND THROW positions. In the FIRST THROW position a conductive leadwire hermetically sealed to and disposed through an insulator is electrically connected to a filter capacitor, which is then electrically connected to the ferrule of a hermetic feedthrough of an AIMD. In the FIRST THROW position, EMI energy imparted to a body fluid side implanted lead can be diverted to the housing of the AIMD. In the SECOND THROW position the conductive leadwire is electrically connected to an RF source disposed on the device side of the housing of the AIMD. While in the SECOND THROW position, a reflective return signal from the RF source is measured and analyzed to determine if the implanted AIMD lead exhibits any life-threatening performance issues, such as lead body anomalies, lead insulation defects or changes, or even defective, fractured or dislodged lead conductors. In another embodiment, a SINGLE POLE RF switch is configured to disconnect filter capacitors during the delivery of a high-voltage cardioversion shock from an implantable cardioverter defibrillator. Dis-connection of the filter capacitor either reduces or eliminates filter capacitor pulse inrush currents, which allows for the use of standard low-voltage filter capacitors instead of larger and more expensive high-voltage pulse rated filter capacitors. Dis-connection of the filter capacitor also allows for an RF interrogation pulse to be applied to the implanted lead in real-time (for example, pre-set intervals throughout the day).

公开(公告)号：US20200246625A1

公开(公告)日：2020-08-06

申请号：US16854138

申请日：2020-04-21

Applicant: Greatbatch Ltd.

Inventor： Robert A. Stevenson ,  Keith W. Seitz ,  Jason Woods ,  Christine A. Frysz

IPC: A61N1/375 ,  A61N1/39

Abstract: An enhanced RF switchable filtered feedthrough for real-time identification of the electrical and physical integrity of an implanted AIMD lead includes a DOUBLE POLE RF switch disposed on the device side. Additionally, the RF switchable filtered feedthrough can optionally include transient voltage suppressors (TVS) and an MRI mode. In an embodiment, a DOUBLE POLE RF switch selectively disconnects EMI filter capacitors so that an RF test/interrogation signal is sent from the AIMD down into an implanted lead(s). The reflected RF signal is then analyzed to assess implanted lead integrity including lead body anomalies, lead insulation defects, and/or lead conductor defects. The Double Pole switch is configured to be controlled by an AIMD control signal to switch between FIRST and SECOND THROW positions. In the FIRST THROW position a conductive leadwire hermetically sealed to and disposed through an insulator is electrically connected to a filter capacitor, which is then electrically connected to the ferrule of a hermetic feedthrough of an AIMD. In the FIRST THROW position, EMI energy imparted to a body fluid side implanted lead can be diverted to the housing of the AIMD. In the SECOND THROW position the conductive leadwire is electrically connected to an RF source disposed on the device side of the housing of the AIMD. While in the SECOND THROW position, a reflective return signal from the RF source is measured and analyzed to determine if the implanted AIMD lead exhibits any life-threatening performance issues, such as lead body anomalies, lead insulation defects or changes, or even defective, fractured or dislodged lead conductors. In another embodiment, a SINGLE POLE RF switch is configured to disconnect filter capacitors during the delivery of a high-voltage cardioversion shock from an implantable cardioverter defibrillator. Dis-connection of the filter capacitor either reduces or eliminates filter capacitor pulse inrush currents, which allows for the use of standard low-voltage filter capacitors instead of larger and more expensive high-voltage pulse rated filter capacitors. Dis-connection of the filter capacitor also allows for an RF interrogation pulse to be applied to the implanted lead in real-time (for example, pre-set intervals throughout the day).

公开(公告)号：US10596369B2

公开(公告)日：2020-03-24

申请号：US16121716

申请日：2018-09-05

Applicant: Greatbatch Ltd.

Inventor： Robert A. Stevenson ,  Christine A. Frysz ,  Thomas Marzano ,  Keith W. Seitz ,  Marc Gregory Martino

IPC: A61N1/08 ,  H01G4/005 ,  H01G4/30 ,  H01G4/35 ,  A61N1/375 ,  H01G4/236 ,  H01G4/12 ,  H03H1/00 ,  A61N1/37

Abstract: A hermetically sealed filtered feedthrough assembly includes an electrically conductive ferrule sealed by a first gold braze to an insulator disposed at least partially within a ferrule opening. A conductive wire is disposed within a via hole disposed through the insulator extending from a body fluid side to a device side. A second gold braze hermetically seals the conductive leadwire to the via hole. A capacitor is disposed on the device side having a capacitor dielectric body with a dielectric constant k that is greater than 0 and less than 1000. The capacitor is the first filter capacitor electrically connected to the conductive leadwire coming from the body fluid side into the device side. An active electrical connection electrically connects the conductive leadwire to the capacitor active metallization. A ground electrical connection electrically connects the capacitor ground metallization to the ferrule and housing of the active implantable medical device.

公开(公告)号：US10559409B2

公开(公告)日：2020-02-11

申请号：US16362862

申请日：2019-03-25

Applicant: Greatbatch Ltd.

Inventor： Keith W. Seitz ,  Dallas J. Rensel ,  Brian P. Hohl ,  Jonathan Calamel ,  Xiaohong Tang ,  Robert A. Stevenson ,  Christine A. Frysz ,  Thomas Marzano ,  Jason Woods ,  Richard L. Brendel

IPC: A61N1/375 ,  B23K1/19 ,  C04B41/51 ,  H01B17/30 ,  C04B41/45 ,  C04B41/88 ,  H01B19/02 ,  B23K1/00 ,  C04B41/00 ,  B23K1/008 ,  B23K26/32 ,  B23K26/21 ,  B22F7/04 ,  B23K101/36 ,  B23K103/14 ,  B22F7/08

Abstract: A method for manufacturing a feedthrough dielectric body for an active implantable medical device includes the steps of first forming a ceramic reinforced metal composite (CRMC) paste by mixing platinum with a ceramic material to form a CRMC material, subjecting the CRMC material to a first sintering step to thereby form a sintered CRMC material, ball-milling or grinding the sintered CRMC material to form a powdered CRMC material; and then mixing the powdered CRMC material with a solvent to form the CRMC paste. The method further includes forming an alumina ceramic body in a green state, forming at least one via hole through the alumina ceramic body, filling the via hole with the CRMC paste, drying the ceramic body including the CRMC paste to form a first CRMC material filling the via hole, forming a second via hole through the first CRMC material, providing a metal core in the second via hole, and subjecting the ceramic body including the first CRMC material and the metal core to a second sintering step to thereby form the dielectric body. The dielectric body is then sealed in a ferrule opening to form a feedthrough.