초록 ▼

The present invention relates to an epidural stimulation lead having at least one electrode that substantially encircles another electrode. Operatively, the encircling electrode can be set as an, anode and the encircled electrode can be set as a cathode to generate an electrical field therebetween.

The present invention relates to an epidural stimulation lead having at least one electrode that substantially encircles another electrode. Operatively, the encircling electrode can be set as an, anode and the encircled electrode can be set as a cathode to generate an electrical field therebetween. The encircling electrode functions in this capacity as an anode guard, which among other things, concentrates the electrical field about the designated cathode and limits the lateral range of a generated electrical field.

대표청구항 ▼

1. A method of providing pain managing electrical energy with an epidural stimulation lead comprising the steps of:implanting the epidural stimulation lead relative to a targeted nerve bundle, wherein the epidural stimulation lead further comprises:a first electrode array comprising a plurality of e

1. A method of providing pain managing electrical energy with an epidural stimulation lead comprising the steps of:implanting the epidural stimulation lead relative to a targeted nerve bundle, wherein the epidural stimulation lead further comprises:a first electrode array comprising a plurality of electrodes;a second electrode array comprising a plurality of electrodes, wherein the first electrode array encircles the second electrode array; anda plurality of conductors, wherein the conductors independently couple the first electrode array and the second electrode array to a programmable energy source;delivering pain-managing electrical energy from the programmable energy source to the first electrode array and the second electrode array through the plurality of conductors;laterally limiting an applied electric field associated with the delivered pain-managing electrical energy by positively biasing the first electrode array relative to the second electrode array. 2. The method of claim 1, further comprising the step of focusing the applied electric field associated with the delivered pain-managing electrical energy to the second electrode array. 3. The method of claim 1, wherein the step of laterally limiting an applied electric field associated with the delivered pain-managing electrical energy minimizes stimulating tissues which surround the targeted nerve bundle. 4. The method of claim 1, further comprising a step of depolarizing the neural tissue within the targeted nerve bundle adjacent to the second electrode array. 5. The method of claim 4, further comprising a step of hyperpolarizing the neural tissue within the targeted nerve bundle and adjacent to the first electrode array. 6. The method of claim 1, further comprising a step of implanting the lead percutaneously. 7. The method of claim 1, further comprising a step of varying, with the programmable energy source, the pain-managing electrical energy delivered to individual electrodes within the first electrode array and the second electrode array to achieve differing levels of pain reduction. 8. The method of claim 1, wherein the first electrode array and the second electrode array comprise separate arrays. 9. The method of claim 1, further comprising a step of always positively biasing the first electrode array relative to the second electrode array. 10. A method of providing pain managing electrical energy with an epidural stimulation lead comprising the steps of:implanting the epidural stimulation lead relative to a targeted nerve bundle, wherein the epidural stimulation lead further comprises:a plurality of electrode arrays that consist of:a first electrode array; anda second electrode array, wherein the first electrode array substantially encircles the second electrode array; anda plurality of conductors, wherein the conductors independently couple the first electrode array and the second electrode array to a programmable energy source;delivering pain-managing electrical energy from the programmable energy source to the first electrode array and the second electrode array through the plurality of conductors;laterally limiting an applied electric field associated with the delivered pain-managing electrical energy by positively biasing the first electrode array relative to the second electrode array. 11. The method of claim 10, further comprising the step of focusing the applied electric field associated with the delivered pain-managing electrical energy to the second electrode array. 12. The method of claim 10, wherein the step of laterally limiting an applied electric field associated with the delivered pain-managing electrical energy minimizes stimulating tissues which surround the targeted nerve bundle. 13. The method of claim 10, wherein the epidural stimulation lead comprises an inert body to contain the first electrode array and the second electrode array. 14. The method of claim 10, wherein neural tissue within the targeted nerve bundle and adjacent to the first electrode array becomes hyperpolarized. 15. The method of claim 10, wherein the epidural stimulation lead is implanted percutaneously. 16. The method of claim 10, wherein the programmable energy source varies the pain-managing electrical energy delivered to individual electrodes within the first electrode array and the second electrode array to achieve differing levels of pain reduction. 17. The method of claim 10, wherein the first electrode array and the second electrode array comprise separate arrays. 18. The method of claim 10, wherein the first electrode array is always positively biased relative to the second electrode array. 19. A pain-managing system comprising:an epidural stimulation lead implanted relative to targeted nerve bundle further comprising:a plurality of electrode arrays that consist of:a first electrode array having two or more electrodes; anda second electrode array having two or more electrodes substantially encircled by the first electrode array;a plurality of conductors, wherein the conductors independently couple the first electrode array and the second electrode array to a programmable energy source;an inert body to contain the first electrode array and the second electrode array; andan inert sheath to contain the plurality of conductors;a programmable energy source electrically coupled to the plurality of conductors and operable to supply pain-managing electrical energy to the first electrode array and the second electrode array through the plurality of conductors;an applied electric field associated with the delivered pain-managing electrical energy by positively biasing the first electrode array relative to the second electrode array, and wherein the applied electric field is laterally limited by the biasing. 20. The pain-managing system of claim 19, wherein the applied electric field associated with the delivered pain-managing electrical energy focuses the pain managing electrical energy to the second electrode array. 21. The pain-managing system of claim 19, wherein laterally limiting the applied electric field associated with the delivered pain-managing electrical energy minimizes stimulating tissues which surround the targeted nerve bundle. 22. The pain-managing system of claim 19, wherein the targeted nerve bundle comprises the spinal tissue. 23. The pain-managing system of claim 19, wherein the epidural stimulation lead is implanted percutaneously. 24. The pain-managing system of claim 19, wherein the programmable energy source varies the pain-managing electrical energy delivered to individual electrodes within the first electrode array and the second electrode array to achieve differing levels of pain reduction. 25. The pain-managing system of claim 19, wherein the second electrode array has a greater number of electrodes than the first electrode array. 26. A pain-managing system comprising:an epidural stimulation lead implanted relative to targeted nerve bundle further comprising:a plurality of electrode arrays that consist of:a first electrode array; anda second electrode array substantially encircled by the first electrode array, wherein the second electrode array has a greater than or equal number of electrodes as the first electrode array;a plurality of conductors, wherein the conductors independently couple the first electrode array and the second electrode array to a programmable energy source;an inert body to contain the plurality of electrodes; andan inert sheath to contain the plurality of conductors; anda programmable energy source electrically coupled to the plurality of conductors and operable to supply pain-managing electrical energy to the first electrode array and the second electrode array through the plurality of conductors.