Multipolar, virtual-electrode catheter with at least one surface electrode and method for ablation
First Claim
1. A virtual-electrode catheter for treatment of tissue, the catheter comprising:
- a catheter body comprising a sidewall and an outer surface;
a first internal lumen extending within said catheter body and adapted to flowingly receive a conductive fluid;
an exit feature comprising a flow path from said first internal lumen through said catheter body sidewall and said outer surface, said exit feature being adapted to permit the conductive fluid to exit from said first internal lumen toward the tissue;
an internal flexible conductor mounted within said first internal lumen adjacent to said exit feature and an inner surface of said catheter body sidewall, wherein said internal flexible conductor is adapted to deliver treatment energy to the tissue via the conductive fluid in said first internal lumen, wherein said internal flexible conductor is configured to be connected to an energy source to supply the treatment energy; and
at least one surface electrode mounted on said outer surface of said catheter body adjacent to said exit feature, wherein the at least one surface electrode is configured to be connected to a return end of the energy source, wherein the internal flexible conductor operates as an active electrode when connected to the energy source, wherein the at least one surface electrode operates as an inactive return electrode to capture and return at least a portion of the treatment energy to the energy source when the at least one surface electrode is connected to the return end of the energy source, thereby creating an electric field between the internal flexible conductor and the at least one surface electrode, and wherein said at least one surface electrode comprises;
a first surface electrode comprising a first conductive coil along a first side of a longitudinal centerline of said exit feature; and
a second surface electrode comprising a second conductive coil along a second side of said longitudinal centerline of said exit feature;
wherein said first conductive coil and said second conductive coil straddle said exit feature longitudinal centerline.
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Accused Products
Abstract
Virtual-electrode catheters and methods for using such virtual-electrode catheters are disclosed. For example, bipolar and multipolar, virtual-electrode catheters having at least one internal electrode and at least one surface electrode, and methods of using these catheters for treatment of cardiac arrhythmias via, for example, radiofrequency (RF) ablation are disclosed. The catheters may comprise a catheter body with an internal lumen extending within it and adapted to flowingly receive a conductive fluid. An exit feature defining a flow path from the internal lumen to the catheter'"'"'s outer surface may exist through a sidewall of the catheter body. A conductor is mounted within the internal lumen adjacent to the exit feature and is adapted to deliver treatment energy to the tissue via the conductive fluid in the internal lumen. At least one surface electrode is mounted on the outer surface of the catheter body adjacent to the exit feature.
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Citations
39 Claims
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1. A virtual-electrode catheter for treatment of tissue, the catheter comprising:
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a catheter body comprising a sidewall and an outer surface; a first internal lumen extending within said catheter body and adapted to flowingly receive a conductive fluid; an exit feature comprising a flow path from said first internal lumen through said catheter body sidewall and said outer surface, said exit feature being adapted to permit the conductive fluid to exit from said first internal lumen toward the tissue; an internal flexible conductor mounted within said first internal lumen adjacent to said exit feature and an inner surface of said catheter body sidewall, wherein said internal flexible conductor is adapted to deliver treatment energy to the tissue via the conductive fluid in said first internal lumen, wherein said internal flexible conductor is configured to be connected to an energy source to supply the treatment energy; and at least one surface electrode mounted on said outer surface of said catheter body adjacent to said exit feature, wherein the at least one surface electrode is configured to be connected to a return end of the energy source, wherein the internal flexible conductor operates as an active electrode when connected to the energy source, wherein the at least one surface electrode operates as an inactive return electrode to capture and return at least a portion of the treatment energy to the energy source when the at least one surface electrode is connected to the return end of the energy source, thereby creating an electric field between the internal flexible conductor and the at least one surface electrode, and wherein said at least one surface electrode comprises; a first surface electrode comprising a first conductive coil along a first side of a longitudinal centerline of said exit feature; and a second surface electrode comprising a second conductive coil along a second side of said longitudinal centerline of said exit feature; wherein said first conductive coil and said second conductive coil straddle said exit feature longitudinal centerline. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36)
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37. A virtual-electrode catheter for tissue ablation, the catheter comprising:
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a catheter body having an outer surface, an internal lumen, and a fluid exit feature extending between said internal lumen and said outer surface, wherein said fluid exit feature is arranged along a longitudinally-extending exit feature centerline, wherein said exit feature is adapted to be placed against tissue, and wherein said internal lumen is adapted to deliver conductive fluid to said fluid exit feature; an active internal electrode mounted within said internal lumen of said catheter body and adapted to contact said conductive fluid, wherein said active internal electrode is configured to be electrically connected to a source of ablative energy and is adapted to impart said ablative energy to the tissue via said conductive fluid; and at least one passive external electrode mounted on said outer surface of said catheter body adjacent to said fluid exit feature, wherein said at least one passive external electrode is configured to be electrically connected to said source of ablative energy to return at least a portion of said ablative energy to said source of ablative energy, whereby, upon activation of said source of ablative energy, an electric field is created between said active internal electrode and said at least one passive external electrode, and in the tissue adjacent to said fluid exit feature;
wherein said at least one passive external electrode further comprises;a first surface electrode mounted on said outer surface of said catheter body adjacent to a first side of said longitudinally-extending exit feature centerline; and a second surface electrode mounted on said outer surface of said catheter body adjacent to a second side of said longitudinally-extending exit feature centerline.
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38. A multipolar, virtual-electrode catheter for performing radiofrequency ablation of cardiac tissue, the catheter comprising:
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a catheter body defining an outer surface and an internal lumen, wherein said internal lumen is adapted to carry conductive fluid; at least two metal electrodes positioned on said outer surface of said catheter body, wherein said at least two metal electrodes are adapted for placement against the cardiac tissue, wherein at least one of said at least two metal electrodes is configured to be connected to a return end of an RF source; a metal conductor positioned within said internal lumen and adapted to impart radiofrequency energy to the conductive fluid, wherein said internal flexible conductor is configured to be connected to the RF source to supply the radiofrequency energy; at least one opening on said outer surface of said catheter, said at least one opening adapted to create a flow path for the conductive fluid in said internal lumen to flow out of the catheter and impinge upon the cardiac tissue as a virtual-electrode, wherein said at least one opening is arranged along a longitudinally-extending opening centerline, and wherein said at least two metal electrodes further comprise; a first surface electrode mounted on said outer surface of said catheter body adjacent to a first side of said longitudinally-extending opening centerline; and a second surface electrode mounted on said outer surface of said catheter body adjacent to a second side of said longitudinally-extending opening centerline; and at least one temperature sensor on said outer surface of said catheter body in close juxtaposition to said at least two metal electrodes, wherein the internal flexible conductor operates as an active electrode when connected to the RF source, wherein at least one of the at least two metal electrodes operates as an inactive return electrode to capture and return at least a portion of the RF energy to the RF source when the at least one of the at least two metal electrodes is connected to the return end of the RF source, thereby creating an electric field between the metal conductor and at least one of the first surface electrode and the second surface electrode. - View Dependent Claims (39)
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Specification