Transcutaneous power transmission and communication for implanted heart assist and other devices
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
A61M-001/10
A61M-001/12
H04B-005/00
H02J-005/00
H01F-038/14
출원번호
US-0319038
(2014-06-30)
등록번호
US-9308303
(2016-04-12)
발명자
/ 주소
Badstibner, Kurt D.
Speicher, Jonathan R.
Heilman, Marlin S.
Bates, Richard A.
Greene, Charles E.
출원인 / 주소
VASCOR, INC.
대리인 / 주소
Bartony & Associates, LLC.
인용정보
피인용 횟수 :
0인용 특허 :
50
초록▼
A system includes an implantable pump system for assisting blood flow in a patient including at least one movable valve. The movable valve is in a normally open state when the moveable valve is not being powered and a drive system in operative connection with the moveable valve to move the moveable
A system includes an implantable pump system for assisting blood flow in a patient including at least one movable valve. The movable valve is in a normally open state when the moveable valve is not being powered and a drive system in operative connection with the moveable valve to move the moveable valve under power. The system further includes an energy transfer system to provide energy to the drive system. The energy transfer system includes an external system including a power source and an external coil and an internal system including an internal coil adapted to receive transcutaneous energy transmitted from the external coil. The internal system has at least a first state wherein energy transmission from the external coil is required to provide operational power to the drive system.
대표청구항▼
1. A system, comprising: an implantable pump system adapted to assist blood flow in a patient comprising: a drive system and an energy transfer system to provide energy to the drive system, the energy transfer system comprising:an external system comprising a power source and an external coil, the e
1. A system, comprising: an implantable pump system adapted to assist blood flow in a patient comprising: a drive system and an energy transfer system to provide energy to the drive system, the energy transfer system comprising:an external system comprising a power source and an external coil, the external coil being adapted to be placed in the vicinity of a patient's skin, andan internal system comprising an internal coil adapted to be implanted and to receive transcutaneous energy transmitted from the external coil, a capacitor system in operative connection with the internal coil to be charged therefrom, the capacitor system being adapted to store energy to provide operational power to the drive system, the internal system having at least a first state wherein energy transmission from the external coil to the capacitor system is required to provide operational power to the drive system,wherein when the external coil is energized, energy is transmitted from the external coil to the internal coil over a range of frequencies between 50 and 500 kHz and the external system and the internal system are adapted such that a change of frequency of energy transmitted from the external coil to the internal coil of +/−10% results in a change in transfer efficiency of no greater than 10%. 2. The system of claim 1 wherein the capacitor system is unable to power a reciprocating pressurizing mechanism of the drive system through one stroke without energy transmission from the external coil when the internal system is in the first state. 3. The system of claim 1 wherein the implantable pump is adapted to be placed in series connection with the aorta. 4. The system of claim 1 wherein the internal system comprises no battery. 5. The system of claim 3 wherein the capacitor system comprises a single capacitor adapted to store energy to provide operational power to the drive system. 6. The system of claim 1 wherein the capacitor system is capable of storing no more than 260 Joules of energy. 7. The system of claim 1 wherein the external system comprises an external communication system and the internal system comprises and internal communication system, wherein the external communication is adapted to transmit to or receive informational signals from the internal communication system via at least one of an external radio or the external coil, and the internal communication system is adapted to transmit information signals to or receive signals from the external communication system via at least one of an internal radio or the internal coil. 8. The system of claim 1 wherein the external coil is energized at a voltage of sufficient amplitude to provide an efficiency of at least 75%. 9. A system, comprising: an implantable pump system adapted to assist blood flow in a patient comprising: a drive system and an energy transfer system to provide energy to the drive system, the energy transfer system comprising:an external system comprising a power source and an external coil adapted to be placed in the vicinity of a patient's skin, an external control system in operative connection with the power source and the external coil, an external communication system in operative connection with the external control systeman internal system comprising an internal coil adapted to be implanted and to receive transcutaneous energy transmitted from the external coil, a capacitor system in operative connection with the internal coil to be charged therefrom, the capacitor system being adapted to store energy to provide operational power to the drive system, an internal control system in operative connection with the capacitor system and the internal coil and an internal communication system in operative connection with the internal control system, the internal system having at least a first state wherein energy transmission from the external coil to the capacitor system is required to provide operational power to the drive system,wherein the internal communication system is adapted to wirelessly transmit a signal to the external communication system to provide information related to a voltage of the capacitor system, and the external system is adapted to cause the power source to energize the external coil upon receiving information transmitted from the internal communication system indicating that the voltage is at least as low as a lower threshold value to charge the capacitor system and to de-energize the external coil upon receiving information transmitted from the internal communication system indicating that the voltage is at least as high as a higher threshold value, and wherein the external control system is adapted to cause the power source to energize the external coil after a determined maximum time period that the external coil has not been energized regardless of whether or not the voltage is at least as low the lower threshold value. 10. The system of claim 9 wherein, when the external coil is energized, energy is transmitted from the external coil to the internal coil over a range of frequencies. 11. The system of claim 10 wherein, when the external coil is energized, energy is transmitted from the external coil to the internal coil in a range of frequencies under control of a spread spectrum algorithm. 12. The system of claim 11 wherein the nominal transmission frequency is between 50 and 500 kHz. 13. A system, comprising: an implantable pump system adapted to assist blood flow in a patient comprising: a drive system and an energy transfer system to provide energy to the drive system, the energy transfer system comprising:an external system comprising a power source and an external coil adapted to be placed in the vicinity of a patient's skin, an external control system in operative connection with the power source and the external coil, an external communication system in operative connection with the external control systeman internal system comprising an internal coil adapted to be implanted and to receive transcutaneous energy transmitted from the external coil, a capacitor system in operative connection with the internal coil to be charged therefrom, the capacitor system being adapted to store energy to provide operational power to the drive system, an internal control system in operative connection with the capacitor system and the internal coil and an internal communication system in operative connection with the internal control system, the internal system having at least a first state wherein energy transmission from the external coil to the capacitor system is required to provide operational power to the drive system,wherein the internal communication system is adapted to wirelessly transmit a signal to the external communication system to provide information related to a voltage of the capacitor system, and the external system is adapted to cause the power source to energize the external coil upon receiving information transmitted from the internal communication system indicating that the voltage is at least as low as a lower threshold value to charge the capacitor system and to de-energize the external coil upon receiving information transmitted from the internal communication system indicating that the voltage is at least as high as a higher threshold value, and wherein the external control system is further adapted to cause the power source to energize the external coil in a manner to result in the voltage being greater than the higher threshold value in anticipation of a required high energy load. 14. A system, comprising: an implantable pump system adapted to assist blood flow in a patient comprising a drive system and an energy transfer system to provide energy to the drive system, the energy transfer system comprising:an external system comprising a power source and an external coil adapted to be placed in the vicinity of a patient's skin, an external control system in operative connection with the power source and the external coil, an external communication system in operative connection with the external control systeman internal system comprising an internal coil adapted to be implanted and to receive transcutaneous energy transmitted from the external coil, a capacitor system in operative connection with the internal coil to be charged therefrom, the capacitor system being adapted to store energy to provide operational power to the drive system, an internal control system in operative connection with the capacitor system and the internal coil and an internal communication system in operative connection with the internal control system, the internal system having at least a first state wherein energy transmission from the external coil to the capacitor system is required to provide operational power to the drive system, the internal communication system being adapted to wirelessly transmit a signal to the external communication system to provide information related to a voltage of the capacitor system and the external system being adapted to cause the power source to energize the external coil upon receiving information transmitted from the internal communication system indicating that the voltage is at least as low as a lower threshold value to charge the capacitor system and to de-energize the external coil upon receiving information transmitted from the internal communication system indicating that the voltage is at least as high as a higher threshold value, wherein information signals are transmitted between the external coil and the internal coil within a frequency range different from a frequency range at which energy is transmitted from the external coil to the internal coil. 15. The system of claim 14 wherein the external communication system is adapted to transmit to or receive informational signals from the internal communication system via at least one of an external radio or the external coil, and the internal communication system is adapted to transmit information signals to or receive signals from the external communication system via at least one of an internal radio or the internal coil. 16. A system, comprising: an implantable pump system adapted to assist blood flow in a patient comprising a drive system and an energy transfer system to provide energy to the drive system, the energy transfer system comprising:an external system comprising a power source, an external coil adapted to be placed in the vicinity of a patient's skin and an external communication system, andan internal system comprising an internal coil adapted to be implanted and to receive transcutaneous energy transmitted from the external coil, a capacitor system in operative connection with the internal coil to be charged therefrom, the capacitor system being adapted to store energy to provide operational power to the drive system, and an internal communication system, the internal system having at least a first state wherein energy transmission from the external coil to the capacitor system is required to provide operational power to the drive system,wherein the external communication is adapted to transmit to or receive informational signals from the internal communication system via at least one of an external radio or the external coil, and the internal communication system is adapted to transmit information signals to or receive signals from the external communication system via at least one of an internal radio or the internal coil, and the internal communication system is adapted to transmit a periodic status signal to confirm operability of at least a portion of the internal system. 17. A system, comprising: an implantable pump system adapted to assist blood flow in a patient comprising: a drive system and an energy transfer system to provide energy to the drive system, the energy transfer system comprising:an external system comprising a power source, an external coil adapted to be placed in the vicinity of a patient's skin, an external control system in operative connection with the power source and the external coil, and an external communication system in operative connection with the external control system,an internal system comprising an internal coil adapted to be implanted and to receive transcutaneous energy transmitted from the external coil, a capacitor system in operative connection with the internal coil to be charged therefrom, the capacitor system being adapted to store energy to provide operational power to the drive system, an internal control system in operative connection with the first energy storage system and the internal coil, and an internal communication system in operative connection with the internal control system, the internal system having at least a first state wherein energy transmission from the external coil to the capacitor system is required to provide operational power to the drive system, anda monitoring system to measure a variable related to current draw by the external coil to provide information to the patient regarding position of the external coil relative to the internal coil based at least in part on the measured variable related to current draw on the external coil. 18. The system of claim 17 wherein the monitoring system to measure a variable related to current draw on the external coil comprises a current sensor in electrical connection with the external coil and in communicative connection with the external control system. 19. A system, comprising: an implantable pump system adapted to assist blood flow in a patient comprising: a drive system and an energy transfer system to provide energy to the drive system, the energy transfer system comprising:an external system comprising a power source and an external coil, the external coil being adapted to be placed in the vicinity of a patient's skin, andan internal system comprising an internal coil adapted to be implanted and to receive transcutaneous energy transmitted from the external coil, a capacitor system in operative connection with the internal coil to be charged therefrom, the capacitor system being adapted to store energy to provide operational power to the drive system, and a second energy storage system comprising an internal rechargeable battery which stores sufficient energy to provide operation power to the drive system without transfer of energy from the external coil, the internal system having at least a first state wherein energy transmission from the external coil to the capacitor system is required to provide operational power to the drive system and a second state wherein energy is drawn from the second energy storage system to provide energy to the drive system,wherein the internal system is placed in the second state upon instructional information being transmitted from the external control system via the external communication system to the internal control system via the internal communication system. 20. The system of claim 19 wherein the external system is adapted to allow the patient to manually cause the internal system to be in the second state. 21. The system of claim 19 wherein no energy is drawn from the internal rechargeable battery to provide energy to the drive system in the first state. 22. The system of claim 21 wherein the internal rechargeable battery is adapted to power the drive system for a period of time in the range of 5 minutes to 2 hours. 23. The system of claim 22 wherein the internal rechargeable battery comprises a plurality of lithium ion battery cells.
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