Arthroscopic devices and methods

What is claimed is: 1. An electrosurgical probe comprising: an elongated shaft assembly having a proximal end, a distal end, and a longitudinal axis; a housing carried on the distal end of the shaft; an interior channel extending axially through the interior of the shaft and housing to an opening in the housing, said opening having a proximal edge; and an electrode with an elongate edge extending laterally across the opening, said electrode configured to reciprocate longitudinally relative to the opening between a distally extended position and a proximally retracted position, wherein the elongate edge of the electrode extends over the proximal edge of the opening when the electrode is in the retracted position to shear tissue interfacing with the opening. 2. The electrosurgical probe of claim 1 wherein the shaft comprises an outer sleeve and an inner sleeve, wherein the housing is mounted on a distal end of the outer sleeve, the electrode is mounted on a distal end of the inner sleeve, and wherein the inner sleeve is reciprocatably mounted in the outer sleeve. 3. The electrosurgical probe of claim 2 further comprising a proximal hub attached to a proximal end of the outer sleeve and a sliding collar attached to a proximal end of the inner sleeve, said sliding collar being mounted to axially reciprocate within the proximal hub while being restrained from rotation relative to the proximal hub. 4. The electrosurgical probe of claim 3 further comprising a rotating coupling mounted to rotate in the proximal hub while being restrained from axially translating relative to the proximal hub, wherein the rotating coupling has a distal surface which engages a proximal surface on the sliding collar and wherein said distal and proximal surfaces are shaped so that rotation and/or rotational oscillation of the rotating coupling causes the sliding collar to axially reciprocate within the proximal hub to cause the electrode to axially reciprocate relative to the opening in the housing. 5. The electrosurgical probe of claim 1 wherein the electrode reciprocates with a stroke in a range from 0.01 mm and 10 mm. 6. The electrosurgical probe of claim 5 wherein the stroke is in a range between 0.1 mm and 5 mm. 7. The electrosurgical probe of claim 1 wherein the electrode has an outer surface that is outward of a plane of the opening. 8. The electrosurgical probe of claim 7 wherein the said outer surface extends outward of the plane of the opening by distance in a range from 0.50 mm to 2.5 mm. 9. The electrosurgical probe of claim 5 wherein the electrode has a proximally-facing edge that extends over an edge of the opening at an end of said stroke. 10. The electrosurgical probe of claim 5 wherein the electrode has lateral edges that extend over edges of the opening. 11. The electrosurgical probe of claim 4 further comprising a motor drive operatively coupled to the inner sleeve and configured to axially reciprocate the electrode. 12. The electrosurgical probe of claim 11 wherein the motor drive couples to the rotating coupling. 13. The electrosurgical probe of claim 11 wherein the motor drive is carried in a handpiece that is detachably coupled to the proximal hub. 14. The electrosurgical probe of claim 11 wherein the motor drive is configured to reciprocate the electrode at a rate in a range from 1 Hz and 1,000 Hz. 15. The electrosurgical probe of claim 13 further comprising a flow pathway that extends from a window section of the opening in the distal end of the inner sleeve to a side-facing opening in the rotating coupling. 16. An electrosurgical probe, comprising: an elongated shaft carrying a distal dielectric housing, said elongated shaft having an interior channel extending to a window in the distal dielectric housing; a dielectric member configured to move within the interior channel and window; an electrode carried by the dielectric member, wherein said electrode has an edge which extends laterally across the window and over a proximal edge of the window to resect tissue interfacing with the window; and a motor operatively coupled to the dielectric member to axially reciprocate the dielectric member to move the electrode in the window. 17. The electrosurgical probe of claim 16 wherein the dielectric housing is a ceramic material. 18. The electrosurgical probe of claim 16 wherein the moveable dielectric member is a ceramic material. 19. The electrosurgical probe of claim 16 further comprising a negative pressure source communicating with said interior channel. 20. The electrosurgical probe of claim 16 wherein the shaft comprises an outer sleeve and an inner sleeve, wherein the dielectric housing is carried by a distal end of the outer sleeve, the moveable dielectric member is mounted on a distal end of the inner sleeve, and wherein the inner sleeve is reciprocatably mounted in the outer sleeve. 21. The electrosurgical probe of claim 16 wherein the electrode has an outer surface that is outward of a plane of the window. 22. The electrosurgical probe of claim 16 wherein the said outer surface extends outward of the plane of the window by distance in a range from 0.50 mm to 2.5 mm. 23. The electrosurgical probe of claim 16 wherein the electrode has edges that extend over an edge of the window. 24. A method for ablating tissue, said method comprising: engaging a window having a planar opening with a proximal edge in a housing against a surface of the tissue; axially reciprocating a lateral elongate edge of a member across the window in a plane parallel to the plane of the window; applying a radiofrequency current to the lateral elongate edge; and applying a vacuum to the housing; wherein the lateral elongate edge extends over an edge of the opening at a proximal end of its reciprocation to shear tissue interfacing with the window. 25. The method of claim 24 wherein the elongate edge protrudes beyond the plane of the window in the housing. 26. The method of claim 25 wherein the elongate edge protrudes beyond the plane of the window in the housing by a distance in the range from 0.50 mm to 2.5 mm. 27. The method of claim 24 wherein the elongate edge is reciprocated at a rate in a range from 1 Hz and 1,000 Hz. 28. The method of claim 24 , wherein the applying the radiofrequency current to the lateral elongate edge ablates tissue and generates tissue debris. 29. The method of claim 28 , wherein applying the vacuum to the housing aspirates the tissue debris.