Electrosurgical systems and methods

What is claimed is: 1. An electrosurgical wand, comprising: a handle on a proximal end of the electrosurgical wand and an elongate shaft coupled to the handle and extending distally from the handle along a longitudinal axis; a combination active electrode having a blade portion and a screen portion disposed on a distal end of the electrosurgical wand, wherein the blade portion extends along and laterally from the electrosurgical wand longitudinal axis defining the distal-most portion of the electrosurgical wand, and wherein the screen portion forms an obtuse angle to the blade portion, the obtuse angle opening toward the distal end of the electrosurgical wand and has at least one aperture therein fluidly coupled to an aspiration channel within the electrosurgical wand; and second and third electrodes, proximally spaced from the combination active electrode, the second electrode spanning a portion of an outside surface of the electrosurgical wand adjacent and proximally spaced from the blade portion of the combination active electrode, the third electrode spanning a portion of the outside surface of the electrosurgical wand opposite the second electrode. 2. The electrosurgical wand of claim 1 , wherein the second electrode defines a thermal electrode. 3. The electrosurgical wand of claim 1 wherein the second and third electrodes are two discrete portions of a single electrode element separated by an insulating portion. 4. The electrosurgical wand of claim 1 , wherein the second electrode spans a single side of the electrosurgical wand, and the third electrode spans at least three sides of the electrosurgical wand. 5. The electrosurgical wand of claim 1 , wherein an insulative spacer is disposed between the combination active electrode, the second electrode and the third electrode and has a distal planar surface oriented at an obtuse angle to the longitudinal axis and parallel with the obtuse angle of the screen portion. 6. The electrosurgical wand of claim 1 , wherein the screen portion further comprises a surface asperity configured to more readily form plasma adjacent the surface asperity. 7. The electrosurgical wand of claim 1 , wherein the second and third electrodes are axially offset from each other, so that a distal edge of the second electrode extends further axially than a distal edge of the third electrode. 8. The electrosurgical wand of claim 7 wherein the distal edges of the second and third electrodes lie along a plane that is parallel to the screen portion. 9. The electrosurgical wand of claim 1 , wherein the second electrode has a smaller surface area than the third electrode. 10. The electrosurgical wand of claim 1 wherein the second electrode has a plurality of axially spaced apertures therethrough, and the third electrode has a plurality of radially spaced apertures therethrough, both pluralities of apertures in fluid communication with a fluid delivery channel within the electrosurgical wand. 11. The electrosurgical wand of claim 1 , wherein the second electrode has a polished surface finish configured to reduce tissue sticking, and the third electrode has an unpolished surface finish, configured to improve surface fluid retention. 12. A system comprising: an electrosurgical controller comprising a processor; a memory coupled to the processor; a voltage generator operatively coupled to the processor, the voltage generator comprising an active terminal and a return terminal; a wand connector configured to couple to a connector of an electrosurgical wand, and the wand connector comprising a plurality of electrical pins, and at least one electrical pin coupled to the active terminal of the voltage generator; and a peristaltic pump comprising a rotor coupled to an electric motor, the electric motor operatively coupled to the processor; and an electrosurgical wand comprising: a handle and an elongate shaft extending distally from the handle along a longitudinal central axis; a combination active electrode disposed at a distal end of the electrosurgical wand defining a blade portion at the distal-most end of the electrosurgical wand extending along and laterally offset from the longitudinal central axis and a screen portion having at least one aperture in operational relationship to a fluid channel within the electrosurgical wand therethrough; a return electrode abutting the elongate shaft and extending along and annularly about the longitudinal central axis, having first and second exposed portions that are distinct from each other, the first exposed portion extending along a first side of the elongate shaft adjacent the blade portion of the combination active electrode and the second exposed extending along an opposing side of the elongate shaft; and wherein the memory stores a program that, when executed by the processor, causes the processor to implement at least two modes of ablation during an electrosurgical procedure; wherein in a first mode of the at least two modes of ablation, the program causes the processor to: control flow of fluid though an aperture that is proximate to the return electrode on the distal end of the electrosurgical wand at a first flow rate; and control energy delivered to the combination active electrode by the electrosurgical controller so as to molecularly dissociate tissue with minimal hemostasis; and wherein in a second mode of the at least two modes of ablation, the program causes the processor to: control flow of fluid through the aperture that is proximate to the return electrode on the distal end of the electrosurgical wand at a second flow rate different than the first flow rate; and control energy delivered to the combination active electrode by the electrosurgical controller so as to molecularly dissociate tissue with more hemostasis. 13. The system of claim 12 wherein the processor is further configured to control the energy so as to molecularly dissociate tissue by pulsing a voltage output between a voltage sufficient to form an ionized vapor layer adjacent the combination active electrode and a voltage sufficient to extinguish the ionized vapor layer. 14. The system of claim 13 wherein the processor is further configured to control the energy so as to molecularly dissociate tissue by pulsing the voltage output at a first pulsing rate in the first mode and at a second pulsing rate, different from the first pulsing rate, in the second mode.