Instrument for endoscopic posterior nasal nerve ablation

We claim: 1. A surgical instrument assembly comprising: (a) an endoscope, the endoscope including an elongate shaft defining a longitudinal axis and having a distal end, the endoscope having a window with a field of view oriented transversely relative to the longitudinal axis such that the field of view includes a region proximal to the distal end; and (b) a surgical instrument comprising: (i) an elongate shaft having a proximal shaft portion and a malleable distal shaft portion, a proximal end of the malleable distal shaft portion being fixedly secured to a distal end of the proximal shaft portion, the elongate shaft being secured to the endoscope such that the proximal shaft portion is fixed against longitudinal movement relative to the endoscope; and (ii) an ablation head coupled to the malleable distal shaft portion, the ablation head including at least one electrode operable to deliver RF energy to tissue for ablating the tissue, the ablation head being sized to fit within a nasal cavity of a patient with the distal end of the endoscope, at least a portion of the ablation head being configured to be within the field of view, the proximal shaft portion being configured to operatively couple with an RF energy source operable to energize the at least one electrode with RF energy, the malleable distal shaft portion being configured to bend relative to a longitudinal shaft axis defined by the proximal shaft portion for selectively orienting the ablation head relative to the longitudinal shaft axis. 2. The surgical instrument of claim 1 , the at least one electrode comprising first and second electrodes operable to deliver bipolar RF energy to tissue. 3. The surgical instrument of claim 1 , the ablation head defining a distal end of an RF ablation instrument. 4. The surgical instrument of claim 1 , the ablation head extending distally from the malleable distal shaft portion along a head axis, the malleable distal shaft portion being configured to bend relative to the longitudinal shaft axis to orient the ablation head in a position in which the head axis is offset from and parallel to the longitudinal shaft axis. 5. The surgical instrument of claim 1 , the ablation head comprising a planar surface, the at least one electrode being disposed on the planar surface. 6. The surgical instrument of claim 1 , the ablation head being rectangular. 7. The surgical instrument of claim 1 , further comprising an electrical conductor housed within the elongate shaft, the electrical conductor being configured to electrically couple the at least one electrode of the ablation head with the RF energy source. 8. The surgical instrument of claim 1 , the elongate shaft comprising an electrically conductive material configured to electrically couple the at least one electrode of the ablation head with the RF energy source. 9. The surgical instrument of claim 1 , further comprising an electrical connector coupled with the proximal shaft portion, the electrical connector being configured to releasably couple with the RF energy source to place the at least one electrode in electric communication with the RF energy source. 10. The surgical instrument assembly of claim 1 , the ablation head being configured to be positioned within a field of view of the distal end of the endoscope. 11. The surgical instrument assembly of claim 1 , the proximal shaft portion of the surgical instrument extending parallel to the elongate shaft of the endoscope. 12. The surgical instrument assembly of claim 1 , the proximal shaft portion of the surgical instrument being in contact with the elongate shaft of the endoscope, the ablation head being configured to assume a position in which the ablation head is spaced apart from the elongate shaft of the endoscope. 13. The surgical instrument assembly of claim 1 , the ablation head including a first surface that faces toward the elongate shaft of the endoscope and an opposed second surface that faces away from the elongate shaft of the endoscope, the at least one electrode being disposed on the second surface. 14. The surgical instrument assembly of claim 1 , the endoscope further comprising a handle from which the elongate shaft of the endoscope extends distally, the elongate shaft of the endoscope and the surgical instrument being rotatable together relative to the handle about a longitudinal axis defined by the elongate shaft of the endoscope. 15. A surgical instrument assembly comprising: (a) an endoscope, the endoscope including an elongate shaft having a longitudinal axis and a distal shaft end through which the endoscope is configured with a field of view, the field of view being oriented transversely relative to the longitudinal axis and encompassing a region proximal to the distal shaft end; and (b) an RF ablation instrument fixedly secured relative to the elongate shaft of the endoscope, the RF ablation instrument comprising: (i) a malleable shaft portion, and (ii) an ablation head secured to a distal end of the malleable shaft portion, the ablation head including at least one electrode operable to ablate patient tissue with RF energy, the ablation head being sized to fit within a nasal cavity of a patient, the malleable shaft portion being configured to bend for selectively positioning the ablation head within the field of view. 16. The surgical instrument assembly of claim 15 , the at least one electrode comprising first and second electrodes operable to deliver bipolar RF energy to tissue. 17. The surgical instrument assembly of claim 15 , a proximal end of the RF ablation instrument including an electrical connector configured to releasably couple with an RF energy source operable to deliver RF energy to the at least one electrode. 18. A method of ablating a posterior nasal nerve of a patient with a surgical instrument assembly comprising an endoscope and an RF ablation instrument, the endoscope defining a longitudinal axis and includes a distal end configured to capture an image of patient anatomy within a field of view that includes a region that is lateral to the longitudinal axis and proximal to the distal end, the RF ablation instrument being—fixedly—secured to the endoscope and including a malleable shaft portion and an ablation head having an electrode, the method comprising: (a) bending the malleable shaft portion of the RF ablation instrument to position the ablation head within the field of view; (b) inserting the distal end of the endoscope and the ablation head into a nasal cavity of a patient while the ablation head is exposed to the nasal cavity of the patient; (c) under visualization provided by the endoscope via the field of view, positioning the electrode of the ablation head laterally relative to the longitudinal axis, with at least a portion of the ablation head being positioned proximally in relation to the distal end while still being within the field of view, and in electrical contact with tissue overlying a posterior nasal nerve of the patient; and (d) energizing the electrode with RF energy to thereby ablate a portion of the posterior nasal nerve with the RF energy. 19. The method of claim 18 , the ablation head including first and second electrodes, ablating the posterior nasal nerve with RF energy comprising positioning the first and second electrodes in electrical contact with the tissue overlying the posterior nasal nerve and delivering bipolar RF energy to the tissue. 20. The method of claim 18 , bending the malleable shaft portion comprising bending the malleable shaft po