Rotating electrical connector for RF energy enabled tissue debridement device

What is claimed is: 1. A bipolar electrosurgical device comprising: an inner shaft forming a cutting tip; an outer shaft defining a lumen and a cutting window; wherein the inner shaft is rotatably disposed about a rotational axis A defined within the lumen such that the cutting tip is selectively exposed through the cutting window; first and second electrodes associated with the outer shaft such that the first and second electrodes rotate with rotation of the outer shaft relative to the inner shaft; wherein the first electrode is electrically isolated from the second electrode and is electrically connected to a proximal contact surface; a rotary electrical connection assembly maintained by a hub member, the rotary electrical connection assembly including an outer stationary connector and an inner rotating connector at least partially nested within a pair of opposing, arcuate arms of the outer stationary connector, the outer stationary connector held stationary upon rotation of the hub member about the rotational axis A and the inner rotating connector configured to rotate in connection with the hub member about the rotational axis A, the inner rotating connector in electrical contact with the proximal contact surface, the rotary electrical connection assembly including an extension electrically coupled to the outer stationary connector between the pair of opposing, arcuate arms, wherein both the outer stationary connector and the inner rotating connector are electrically conductive, partial ring-like structures extending at least 180 degrees about the rotational axis A; wiring electrically connected to and extending from the extension for delivering electrical power to the outer stationary connector which is conducted to the inner rotating connector along the pair of opposing, arcuate arms to common, nested surfaces of the partial ring-like structure of the inner rotating connector; and an actuator linked to the proximal contact surface, wherein the bipolar electrosurgical device is configured such that the outer shaft rotates relative to the inner shaft and the wiring in response to operation of the actuator while the proximal contact surface remains electrically connected to the inner rotating connector. 2. The bipolar electrosurgical device of claim 1 , wherein the bipolar electrosurgical device is configured such that the inner rotating connector is rotatable relative to the extension. 3. The bipolar electrosurgical device of claim 2 , wherein the bipolar electrosurgical device is configured such that the inner rotating connector rotates relative to the extension with rotation of the outer shaft relative to the inner shaft. 4. The bipolar electrosurgical device of claim 1 , wherein the extension is formed as part of the outer stationary connector, and further wherein the inner rotating connector and the outer stationary connector remain electrically connected with rotation of the inner rotating connector relative to the extension. 5. The bipolar electrosurgical device of claim 4 , wherein the bipolar electrosurgical device is configured such that the inner rotating connector rotates relative to the outer stationary connector with rotation of the inner rotating connector relative to the extension. 6. The bipolar electrosurgical device of claim 4 , wherein the bipolar electrosurgical device is configured such that the inner rotating connector rotates relative to the outer stationary connector with rotation of the outer shaft relative to the inner shaft. 7. The bipolar electrosurgical device of claim 4 , wherein the bipolar electrosurgical device is configured such that physical contact between the inner rotating connector and the outer stationary connector is maintained throughout 360 degrees of rotation of the outer shaft relative to the inner shaft. 8. The bipolar electrosurgical device of claim 4 , wherein a shape of the inner rotating connector is similar to the rotational axis A, and further wherein the inner rotating connector and the outer stationary connector remain electrically connected with 360 degrees of rotation of the inner rotating connector about the rotational axis. 9. The bipolar electrosurgical device of claim 4 , wherein the outer stationary connector further includes a bridge interconnecting the extension and the opposing, arcuate arms. 10. The bipolar electrosurgical device of claim 1 , further comprising an irrigation path extending along the outer shaft. 11. The bipolar electrosurgical device of claim 10 , wherein the irrigation path is defined by tubing carried external the outer shaft. 12. The bipolar electrosurgical device of claim 10 , wherein the bipolar electrosurgical device is configured such that the irrigation path rotates with rotation of the outer shaft relative to the inner shaft. 13. The bipolar electrosurgical device of claim 1 , wherein the proximal contact surface rotates with rotation of the outer shaft relative to the inner shaft. 14. The bipolar electrosurgical device of claim 1 , wherein the second electrode is electrically connected to a proximal contact surface, and further wherein the proximal contact surface associated with the second electrode is electrically isolated from the proximal contact surface associated with the first electrode. 15. The bipolar electrosurgical device of claim 1 , further comprising a handpiece carrying the actuator. 16. The bipolar electrosurgical device of claim 15 , wherein the outer shaft defines a proximal side opposite the cutting window, and further wherein the proximal side is mounted to the handpiece. 17. The bipolar electrosurgical device of claim 1 , wherein the outer stationary connector and the inner rotating connector are formed from electrically conductive materials. 18. The bipolar electrosurgical device of claim 1 , wherein the first electrode is disposed on an edge of the outer shaft defining the cutting window. 19. The bipolar electrosurgical device of claim 18 , wherein the second electrode is disposed on an outer surface of the outer shaft.