초록 ▼

Apparatus and method of communicating data employing current pulses transmitted by an implanted device through living biological tissue to an external device. The method also contemplates transmission of current pulses from the external device through living biological tissue to an implanted device.

Apparatus and method of communicating data employing current pulses transmitted by an implanted device through living biological tissue to an external device. The method also contemplates transmission of current pulses from the external device through living biological tissue to an implanted device. Uniquely configured antenna electrodes are preferably employed in the implanted device. Increase in signal-to-noise ratio is achieved through synchronization. The method may be employed in diagnostic, therapeutic and general monitoring activities in connection with human beings.

대표청구항 ▼

1. A method of data communication between an implanted device and an external device comprisingproviding an implanted device having a first antenna and first circuit components operatively associated therewith, providing an external device having a second antenna and an associated microprocessor, po

1. A method of data communication between an implanted device and an external device comprisingproviding an implanted device having a first antenna and first circuit components operatively associated therewith, providing an external device having a second antenna and an associated microprocessor, positioning said first antenna and said second antenna with living biological tissue therebetween, effecting communication between said implanted device and said external device to establish current pulses through ionic fluid in said biological tissue in at least one direction between said first antenna electrode and said second antenna electrode, and effecting said communication in a synchronous manner. 2. The method of claim 1, includingimplanting said implanted device in a living patient. 3. The method of claim 2, includingimplanting said implanted device in a human being. 4. The method of claim 3, includingeffecting said communication both from said first antenna to second antenna and from said second antenna to said first antenna. 5. The method of claim 4, includingimplanting said implantable device in the abdomen of said human being. 6. The method of claim 4, includingplacing the electrodes of said second antenna in contact with the skin of said human being. 7. The method of claim 4, includingproviding a microprocessor as one of said first circuit components. 8. The method of claim 7, includingproviding at least one sensor as one of said first circuit components. 9. The method of claim 8, includingsaid implanted device in the brain of said human being. 10. The method of claim 9, includingemploying said method to monitor brain functioning. 11. The method of claim 10, includingemploying said method to communicate subdural electroencepholographic signals to said external device. 12. The method of claim 1, includingemploying said method for diagnostic purposes. 13. The method of claim 1, includingemploying said method for therapeutic purposes. 14. The method of claim 1, includingproviding a power source as a said first circuit component in said implanted device. 15. The method of claim 1, includingdirecting the current pulses from said implanted first antenna through said biological material to said external second antenna. 16. The method of claim 1, includingemploying said first antenna and said second antenna for both transmission and reception of said current pulses. 17. A method of data communication between an implanted device and an external device comprisingproviding an implanted device having a first antenna and first circuit components operatively associated therewith, providing an external device having a second antenna and an associated microprocessor, positioning said first antenna and said second antenna with living biological tissue therebetween, effecting communication between said implanted device and said external device to establish current pulses in at least one direction between said first antenna and said second antenna, implanting said implanted device in a living patient, implanting said implanted device in a human being, effecting said communication both from said first antenna to second antenna and from said second antenna to said first antenna, effecting said communication in a synchronous manner, and employing heart pulses of said human being as a clock in synchronizing said communications. 18. A method of data communication between an implanted device and an external device comprisingproviding an implanted device having a first antenna and first circuit components operatively associated therewith, providing an external device having a second antenna and an associated microprocessor, positioning said first antenna and said second antenna with living biological tissue therebetween, effecting communication between said implanted device and said external device to establish current pulses in at least one direction between said first antenna electrode and said second antenna electrode, and establishing the distance between said first antenna and said second antenna at less than about 15 cm. 19. A method of data communication between an implanted device and an external device comprisingproviding an implanted device having a first antenna and first circuit components operatively associated therewith, providing an external device having a second antenna and an associated microprocessor, positioning said first antenna and said second antenna with living biological tissue therebetween, effecting communication between said implanted device and said external device to establish current pulses in at least one direction between said first antenna electrode and said second antenna electrode, and employing in said first antenna a pair of electrically conductive concave shells having their concave surfaces facing in generally opposed directions from each other. 20. The method of claim 19, includingsaid electrically conductive concave shells having generally concave surfaces facing each other, and electrically insulating the convex surfaces of said electrically conductive shells of said first antenna from each other. 21. The method of claim 19, includingsaid shells being asymmetrical. 22. A method of data communication between an implanted device and an external device comprisingproviding an implanted device having a first antenna and first circuit components operatively associated therewith, providing an external device having a second antenna and an associated microprocessor, positioning said first antenna and said second antenna with living biological tissue therebetween, effecting communication between said implanted device and said external device to establish current pulses in at least one direction between said first antenna electrode and said second antenna electrode, and providing said first circuit components on an electronic chip. 23. The method of claim 22, includingproviding said implanted first antenna on said electronic chip. 24. The method of claim 23, includingpositioning said first antenna up to about 15 cm from said second antenna. 25. The method of claim 22, includingproviding an electrically nonconductive flexible sheet to reflect brain current flux and resist said fluid contacting said first antenna. 26. A method of data communication between an implanted device and an external device comprisingproviding an implanted device having a first antenna and first circuit components operatively associated therewith, providing an external device having a second antenna and an associated microprocessor, positioning said first antenna and said second antenna with living biological tissue therebetween, effecting communication between said implanted device and said external device to establish current pulses in at least one direction between said first antenna electrode and said second antenna electrode, and protectively encapsulating said implanted device with a resinous material. 27. A method of data communication between an implanted device and an external device comprisingproviding an implanted device having a first antenna and first circuit components operatively associated therewith, providing an external device having a second antenna and an associated microprocessor, positioning said first antenna and said second antenna with living biological tissue therebetween, effecting communication between said implanted device and said external device to establish current pulses in at least one direction between said first antenna electrode and said second antenna electrode, and said implantable device having a width of less than about 12 mm, a length of less than about 12 mm and a thickness of less than about 4 mm. 28. A method of data communication between an implanted device and an external device comprisingproviding an implanted device having a first antenna and first circuit components operatively associated therewith, providing an external device having a second antenna and an associated microprocessor, positioning said first antenna and said second antenna with living biological tissue therebetween, effecting communication between said implanted device and said external device to establish current pulses in at least one direction between said first antenna electrode and said second antenna electrode, implanting said implanted device in a living patient, implanting said implanted device in a human being, effecting said communication both from said first antenna to second antenna and from said second antenna to said first antenna, providing a microprocessor as one of said first circuit components, providing at least one sensor as one of said first circuit components, and employing said external device to transmit a current pulse to cause said internal device to transmit data, said internal device responsively transmitting said data to said external device, and said transmissions being effected at times other than the period of R-waves of an electrocardiogram. 29. The method of claim 28 includingsaid external device emitting a current pulse or pulses of the different sign or configuration from the pulses it emits when it requests data from said implanted device when it wishes to transmit data to said implanted device, and said external device following said pulses with the desired transmitted data to said implanted device with said pulses being transmitted at a time other than the time period when R-waves of the electrocardiogram are present. 30. Apparatus for volume conduction between an implantable device and an external device, comprisingan implantable device having a first antenna and first circuit components for transmitting current pulses through living biological tissue and receiving current pulses therethrough, a second antenna for transmitting current pulses through living biological tissue and receiving current therethrough, said first circuit components including a first microprocessor, said external device having a second microprocessor, said first antenna being a directional antenna, and said apparatus being structured for directional data communication. 31. The apparatus of claim 30, includingemploying in said first antenna electrodes having a pair of electrically conductive concave shells facing in generally opposed directions from each other, and said second antenna for contacting the skin generally adjacent said biological tissue. 32. The apparatus of claim 31, includingsaid antenna electrodes being asymmetrical. 33. The apparatus of claim 31, includingsaid first circuit components including at least one sensor. 34. The apparatus of claim 33, includingsaid implantable device structured to deliver EEG data to said external device. 35. The apparatus of claim 34, includingsaid antenna electrode shells having convex surfaces generally facing each other, and electrical insulation disposed on said convex surfaces. 36. The apparatus of claim 34, includingsaid first circuit components including at least one power source. 37. The apparatus of claim 30, includingsaid implantable device being configured and dimensioned to be implantable in a human abdomen. 38. The apparatus of claim 37, includingsaid implantable device having a width less than about 12 mm, a length less than about 12, and a thickness less than about 4 mm. 39. The apparatus of claim 36, includingan electrically nonconductive flexible sheet for reflecting brain current flux away from said first antenna disposed on the opposite side of said first antenna electrode from said second antenna.