Needle instrument for posterior nasal neurectomy ablation

We claim: 1. A method of using a surgical instrument, the surgical instrument comprising: (a) an outer tube configured to be gripped by a user; and (b) a needle slidably disposed within the outer tube, wherein the needle comprises: (i) a needle lumen, (ii) a distal needle tip configured to pierce tissue, wherein the needle lumen opens to the distal needle tip such that the distal needle tip is configured to deliver fluid from the needle lumen to tissue, and (iii) an electrode disposed at the distal needle tip, wherein the electrode is operable to deliver RF energy to tissue for ablating the tissue, wherein the needle is translatable relative to the outer tube between a proximal retracted position in which the distal needle tip is housed coaxially within the outer tube, and a distal extended position in which the distal needle tip is exposed from the outer tube and configured to pierce tissue, wherein the needle further comprises a needle shaft that extends longitudinally along a shaft axis, wherein the distal needle tip extends distally from the needle shaft and is resiliently biased toward an offset configuration in which the distal needle tip is non-coaxial with the shaft axis, wherein the distal needle tip is configured to remain straight when in the proximal retracted position, the method comprising: advancing the needle distally from the proximal retracted position to a distal position, the needle tip being positioned in a posterior nasal nerve in the distal position, the needle tip transitioning from the straight configuration to the offset configuration as the needle is advanced distally from the proximal retracted position to the distal position. 2. The method of claim 1 , wherein the electrode is configured to deliver monopolar RF energy to tissue when the needle is in the distal extended position. 3. The method of claim 1 , wherein the distal needle tip comprises an electrically conductive material that defines the electrode. 4. The method of claim 1 , further comprising an electrically insulative layer positioned between an outer surface of the needle and an inner surface of the outer tube. 5. The method of claim 4 , wherein the electrically insulative layer is secured to the needle such that a distal end of the electrically insulative layer terminates proximally of the distal needle tip. 6. The method of claim 1 , wherein a proximal end of the needle is configured to couple with a fluid source, wherein the needle lumen is configured to communicate fluid from the fluid source to tissue through the distal needle tip. 7. The method of claim 1 , wherein an opening of the distal needle tip is oriented away from the shaft axis in the offset configuration. 8. The method of claim 1 , wherein the offset configuration comprises at least one of a curved configuration or an angled configuration. 9. The method of claim 1 , wherein the needle further comprises an electrical connector, wherein the electrical connector is configured to electrically couple with an RF energy source. 10. The method of claim 1 , wherein the needle further comprises a lateral projection, wherein the outer tube includes a longitudinal slot that slidably receives the lateral projection, wherein the lateral projection is exposed through the longitudinal slot such that the lateral projection is configured to be engaged by a user to actuate the needle relative to the outer tube. 11. The method of claim 1 , wherein the needle further comprises: (i) a first projection extending laterally from a first portion of the needle, and (ii) a second projection extending laterally from a second portion of the needle, wherein the outer tube comprises: (i) a first longitudinal slot configured to slidably receive the first projection therethrough, and (ii) a second longitudinal slot configured to slidably receive the second projection therethrough. 12. The method of claim 11 , wherein the first projection comprises an actuator tab, wherein the second projection comprises an electrical connector. 13. The method of claim 11 , wherein the first projection and the second projection are both coupled to the needle shaft and wherein the second projection is slidable dependent on a position of the first projection. 14. The method of claim 1 , wherein the outer tube and the needle are configured to extend coaxially along a central axis of the surgical instrument when the needle is in the proximal retracted position. 15. A method of using a surgical system the perform the method of claim 1 , the surgical system comprising: (a) an RF energy source operatively coupled with the electrode of the needle; (b) a fluid source operatively coupled with the needle lumen; and (c) a ground pad operatively coupled with the RF energy source, wherein the surgical instrument is operable to energize the electrode with RF energy from the RF energy source while dispensing fluid from the fluid source through the distal needle tip, wherein the electrode is configured to cooperate with the ground pad to deliver monopolar RF energy to tissue for ablating the tissue, the method further comprising: activating the RF energy source and dispensing fluid from the fluid source through the distal needle tip while the needle is in the distal position. 16. A method of using a surgical instrument, the surgical instrument comprising: (a) an outer tube; and (b) a needle slidably disposed within the outer tube, wherein the needle comprises: (i) a shaft defining a longitudinal shaft axis, (ii) a distal tip configured to pierce tissue, wherein the distal tip is resiliently biased toward an offset configuration relative to the longitudinal shaft axis, and (iii) an electrode disposed at the distal tip, wherein the electrode is operable to deliver RF energy to tissue for ablating the tissue, wherein the needle is translatable relative to the outer tube between a proximal retracted position in which the distal tip is housed within the outer tube, and a distal extended position in which the distal tip is exposed from the outer tube, wherein the distal tip is configured to resiliently transition from a straight configuration to the offset configuration in response to distal extension of the distal tip from the outer tube, the method comprising: advancing the needle distally from the proximal retracted position to the distal extended position, the needle tip being positioned in a posterior nasal nerve in the distal extended position, the needle tip transitioning from the straight configuration to the offset configuration as the needle is advanced distally from the proximal retracted position to the distal extended position. 17. The method of claim 16 , wherein the distal tip is configured to extend coaxially with the longitudinal shaft axis when in the straight configuration. 18. The method of claim 16 , wherein the offset configuration comprises at least one of a curved configuration or an angled configuration relative to the longitudinal shaft axis. 19. A method of ablating a posterior nasal nerve of a patient with an RF ablation instrument, wherein the RF ablation instrument includes an outer tube and a needle slidably disposed within the outer tube and having a distal needle tip with an electrode, wherein the needle defines a longitudinal shaft axis and has a resilient bias urging the distal needle tip toward an offset configuration relative to the longitudinal shaft axis, the method comprising: (a) inserting a distal end of the RF ablation instrument into a nasal cavity of the patient while the