Safety feature to disable an electronic device when a wireless implantable medical device (IMD) is proximate
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H04M-011/04
A61N-001/08
A61N-001/37
A61M-005/142
A61N-001/372
출원번호
US-0277893
(2014-05-15)
등록번호
US-8954030
(2015-02-10)
발명자
/ 주소
Buchheit, Brian K.
출원인 / 주소
Buchheit, Brian K.
대리인 / 주소
Patents on Demand P.A.
인용정보
피인용 횟수 :
4인용 특허 :
137
초록▼
A communication pathway is established between an implanted medical device (IMD) and a proximate electronic device. Performance of one or more functions by the electronic device is known to have a potential to cause at least one adverse effect on the implanted medical device. The implanted medical d
A communication pathway is established between an implanted medical device (IMD) and a proximate electronic device. Performance of one or more functions by the electronic device is known to have a potential to cause at least one adverse effect on the implanted medical device. The implanted medical device can wirelessly conveying a message over the communication pathway to the electronic device detailing an existence of the implanted medical device (IMD) within wireless communication range of the electronic device and detailing a safety requirement or operational data specific to the implanted medical device. The conveyance of the message from the implanted medical device can place the proximate electronic device on notice to minimize the adverse effects on the implanted medical device resulting from executing the one or more functions.
대표청구항▼
1. A method for protecting an implanted medical device (IMD) from proximate device harmful interference comprising: establishing a communication pathway between an implanted medical device (IMD) and a proximate electronic device, wherein the implanted medical device is an active implanted medical de
1. A method for protecting an implanted medical device (IMD) from proximate device harmful interference comprising: establishing a communication pathway between an implanted medical device (IMD) and a proximate electronic device, wherein the implanted medical device is an active implanted medical device having wireless communication capabilities, wherein performance of one or more functions by the proximate electronic device is known to have a potential to cause at least one adverse effect to a treatment provided by the implanted medical device or to an operation of the implanted medical device when the implanted medical device is within an effective proximity of the electronic device at a time the electronic device performs the one or more functions, wherein the communication pathway for wireless communication refers to any communication medium not requiring a dedicated physical wire between communication endpoints over which an information bearing signal is conveyed;the implanted medical device wirelessly conveying a message over the communication pathway to the electronic device indicating an existence of the implanted medical device (IMD) within wireless communication range of the electronic device and indicating a safety requirement or operational data specific to the implanted medical device, wherein the wireless communication range corresponds to at least a high likelihood of the implanted medical device being within the effective proximity of the proximate electric device; andthe conveyance of the message from the implanted medical device placing the proximate electronic device, which receives the message, on notice, such that the electronic device responsive to being on notice is able to minimize potential harmful effects of performing the one or more functions while the implanted medical device is within the effective proximity, is able to alert a user of the electronic device of potential harmful effects of performing the one or more functions while the implanted medical device is within the effective proximity, or automatically disable the one or more functions while the implanted medical device is in the effective proximity, wherein the implanted medical device is a man-made device that is partially or totally inserted into a human body or a natural orifice of the human body, where the implanted medical device is operationally designed to remain in place after being inserted for over thirty days. 2. The method of claim 1, further comprising: the implanted medical device conveying a notification or an alert to a wearer of the implanted medical device or to other humans within the effective proximity of a presence of the electronic device having the one or more functions able to cause the at least one adverse effect on the implanted medical device. 3. The method of claim 1, further comprising: the implanted medical device changing operational state from a default while near the effective proximity to minimize harm resulting from the one or more electronic device executing the one or more functions; andthe implanted medical device changing operational state back to the default when the implanted medical device is no longer near the effective proximity. 4. The method of claim 1, further comprising: exchanging communications between the implanted medical device and the electronic device as the electronic device performs the one or more functions; anddynamically altering optional state of the implanted medical device responsive to the exchanged communications to minimize or eliminate the adverse effect. 5. The method of claim 1, further comprising: the implanted medical device detecting one of more adverse effects from the one or more functions; andresponsive to the detecting, the implanted medical device establishing the communication pathway and wirelessly conveying the message over the communication pathway. 6. The method of claim 1, wherein the implanted medical device utilizes at least one of a near field communication (NFC) transmission, a BLUETOOTH transmission having a range of less than twenty meters, and a radio transmission having a range of less than twenty meters to wirelessly convey the message. 7. The method of claim 1, wherein the implanted medical device utilizes at least one of a near field communication (NFC) transmission, a BLUETOOTH transmission, and a radio transmission to wirelessly conveying the message, wherein the NFC transmission, the BLUETOOTH transmission, or the radio transmission has a range of less than one meter. 8. The method of claim 1, wherein the electronic device is one of a mobile telephony device, a touch-screen computing device, a personal computer, a microwave device, and a medical device. 9. The method of claim 1, wherein the implanted medical device is one of a neurostimulator, a cardioverter-defibrillator, a cardiac resynchronization device, a pacemaker, and a medical pump. 10. An implanted medical device (IMD) comprising: one or more processors;a wireless transmitter;a non-transitory storage medium storing programmatic instructions, wherein execution of the programmatic instructions by the one or more processors causes the implanted medical device to: (a) establish a communication pathway between the implanted medical device (IMD) and a proximate electronic device, wherein the implanted medical device is an active implanted medical device having wireless communication capabilities via the wireless transmitter, wherein performance of one or more functions by the proximate electronic device is known to have a potential to cause at least one adverse effect to a treatment provided by the implanted medical device or to an operation of the implanted medical device when the implanted medical device is within an effective proximity of the proximate electronic device at a time the proximate electronic device performs the one or more functions, wherein the communication pathway for wireless communication refers to any communication medium not requiring a dedicated physical wire between communication endpoints over which an information bearing signal is conveyed, wherein the wireless transmitter refers to any transmitter for conveying the information bearing signal over the communication pathway; and(b) wirelessly convey a message over the communication pathway to the electronic device indicating an existence of the implanted medical device (IMD) within wireless communication range of the proximate electronic device and indicating a safety requirement or operational data specific to the implanted medical device, wherein the wireless communication range corresponds to at least a high likelihood of the implanted medical device being within the effective proximity of the proximate electric device,wherein the conveyance of the message from the implanted medical device places the proximate electronic device, which receives the message, on notice, such that the proximate electronic device responsive to being on notice is able to minimize potential harmful effects of performing the one or more functions while the implanted medical device is within the effective proximity, is able to alert a user of the proximate electronic device of potential harmful effects of performing the one or more functions while the implanted medical device is within the effective proximity, or automatically disable the one or more functions while the implanted medical device is in the effective proximity, wherein the implanted medical device is a man-made device that is partially or totally inserted into a human body or a natural orifice of the human body, where the implanted medical device is operationally designed to remain in place after being inserted for over thirty days. 11. The system of claim 10, wherein execution of the programmatic instructions by the one or more processors causes the implanted medical device to: convey a notification or an alert to a wearer of the implanted medical device or to other humans within the effective proximity of a presence of the proximate electronic device having the one or more functions able to have cause the at least one adverse effect on the implanted medical device. 12. The system of claim 10, wherein execution of the programmatic instructions by the one or more processors causes the implanted medical device to: change operational state from a default while near the effective proximity to minimize harm resulting from the proximate electronic device executing the one or more functions; andchange operational state back to the default when the implanted medical device is no longer near the effective proximity. 13. The system of claim 10, wherein execution of the programmatic instructions by the one or more processors causes the implanted medical device to: exchange communications between the implanted medical device and the proximate electronic device as the proximate electronic device performs the one or more functions; anddynamically alter optional state of the implanted medical device responsive to the exchanged communications to minimize or eliminate the adverse effect. 14. The system of claim 10, wherein execution of the programmatic instructions by the one or more processors causes the implanted medical device to: detect one of more adverse effects from the one or more functions; andresponsive to the detecting, establish the communication pathway and wirelessly conveying the message over the communication pathway. 15. The system of claim 10, wherein the proximate electronic device is one of a mobile telephony device, a touch-screen computing device, a personal computer, a microwave device, and a medical device. 16. The system of claim 10, wherein the implanted medical device is one of a neurostimulator, a cardioverter-defibrillator, a cardiac resynchronization device, a pacemaker, and a medical pump. 17. The system of claim 10, wherein the implanted medical device is a neurostimulator, wherein execution of the programmatic instructions by the one or more processors causes the neurostimulator to: change operational state from a default while near the effective proximity to minimize harm resulting from the proximate electronic device executing the one or more functions; andchange operational state back to the default when the implanted medical device is no longer near the effective proximity. 18. The system of claim 10, wherein the implanted medical device is a cardioverter-defibrillator, wherein execution of the programmatic instructions by the one or more processors causes the cardioverter-defibrillator to: change operational state from a default while near the effective proximity to minimize harm resulting from the proximate electronic device executing the one or more functions; andchange operational state back to the default when the implanted medical device is no longer near the effective proximity. 19. The system of claim 10, wherein the implanted medical device is a cardiac resynchronization device, wherein execution of the programmatic instructions by the one or more processors causes the cardiac resynchronization device to: change operational state from a default while near the effective proximity to minimize harm resulting from the proximate electronic device executing the one or more functions; andchange operational state back to the default when the implanted medical device is no longer near the effective proximity. 20. The system of claim 10, wherein the implanted medical device is a pacemaker, wherein execution of the programmatic instructions by the one or more processors causes the pacemaker to: change operational state from a default while near the effective proximity to minimize harm resulting from the proximate electronic device executing the one or more functions; andchange operational state back to the default when the implanted medical device is no longer near the effective proximity. 21. The system of claim 10, wherein the implanted medical device is a medical pump, wherein execution of the programmatic instructions by the one or more processors causes the medical pump to: change operational state from a default while near the effective proximity to minimize harm resulting from the proximate electronic device executing the one or more functions; andchange operational state back to the default when the implanted medical device is no longer near the effective proximity. 22. The system of claim 10, wherein the implanted medical device is a bone fusion stimulator, wherein execution of the programmatic instructions by the one or more processors causes the bone fusion stimulator to: change operational state from a default while near the effective proximity to minimize harm resulting from the proximate electronic device executing the one or more functions; andchange operational state back to the default when the implanted medical device is no longer near the effective proximity. 23. The system of claim 10, wherein the implanted medical device is a cochlear implant, wherein execution of the programmatic instructions by the one or more processors causes the cochlear implant to: change operational state from a default while near the effective proximity to minimize harm resulting from the proximate electronic device executing the one or more functions; andchange operational state back to the default when the implanted medical device is no longer near the effective proximity. 24. The system of claim 10, wherein the implanted medical device is a gastric stimulator, wherein execution of the programmatic instructions by the one or more processors causes the gastric stimulator to: change operational state from a default while near the effective proximity to minimize harm resulting from the proximate electronic device executing the one or more functions; andchange operational state back to the default when the implanted medical device is no longer near the effective proximity. 25. A computer program product comprising a non-transitory computer readable storage medium having computer usable program code embodied therewith, the computer usable program code comprising: computer usable program code configured to establishing a communication pathway between an implanted medical device (IMD) and a proximate electronic device, wherein the implanted medical device is an active implanted medical device having wireless communication capabilities, wherein performance of one or more functions by the proximate electronic device is known to have a potential to cause at least one adverse effect to a treatment provided by the implanted medical device or to an operation of the implanted medical device when the implanted medical device is within an effective proximity of the proximate electronic device at a time the proximate electronic device performs the one or more functions, wherein the communication pathway for wireless communication refers to any communication medium not requiring a dedicated physical wire between communication endpoints over which an information bearing signal is conveyed; andcomputer usable program code configured to wirelessly conveying a message over the communication pathway from the implanted medical device to the electronic device indicating an existence of the implanted medical device (IMD) within wireless communication range of the proximate electronic device and indicating a safety requirement or operational data specific to the implanted medical device, wherein the wireless communication range corresponds to at least a high likelihood of the implanted medical device being within the effective proximity of the proximate electric device, wherein the conveyance of the message from the implanted medical device places the proximate electronic device, which receives the message, on notice, such that the proximate electronic device responsive to being on notice is able to minimize potential harmful effects of performing the one or more functions while the implanted medical device is within the effective proximity, is able to alert a user of the proximate electronic device of potential harmful effects of performing the one or more functions while the implanted medical device is within the effective proximity, or automatically disable the one or more functions while the implanted medical device is in the effective proximity, wherein the implanted medical device is a man-made device that is partially or totally inserted into a human body or a natural orifice of the human body, where the implanted medical device is operationally designed to remain in place after being inserted for over thirty days. 26. The computer program product of claim 25, further comprising: computer usable program code configured to conveying a notification or present an alert to a wearer of the implanted medical device or to other humans within the effective proximity of a presence of the proximate electronic device having the one or more functions able to have cause the at least one adverse effect on the implanted medical device. 27. The computer program product of claim 25, further comprising: computer usable program code configured to change an operational state of the implanted medical device from a default while near the effective proximity to minimize harm resulting from the proximate electronic device executing the one or more functions; andcomputer usable program code configured to change an operational state of the implanted medical device back to the default when the implanted medical device is no longer near the effective proximity. 28. The computer program product of claim 25, further comprising: computer usable program code configured to detect at the implanted medical device one of more adverse effects from the one or more functions; andcomputer usable program code configured to, responsive to the detecting, establish the communication pathway and wirelessly conveying the message over the communication pathway.
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