RF and/or microwave energy conveying structure, and an invasive electrosurgical scoping device incorporating the same

The invention claimed is: 1. An energy conveying structure for invasive electrosurgery, the energy conveying structure comprising a coaxial layered structure having: an innermost insulating layer; an inner conductive layer formed on the innermost insulating layer; an outer conductive layer formed coaxially with the inner conductive layer; and a dielectric layer separating the inner conductive layer and the outer conductive layer, wherein the inner conductive layer, the outer conductive layer and the dielectric layer form a transmission line for conveying radiofrequency (RF) and/or microwave energy, characterized in that: the coaxial layered structure is insertable in a flexible insertion tube of an invasive surgical scoping device, wherein the innermost insulating layer is hollow to form an instrument channel for the invasive surgical scoping device, and wherein the energy conveying structure includes: a first terminal that is electrically connected to the inner conductive layer and which extends through the innermost insulating layer into the instrument channel; and a second terminal that is electrically connected to the outer conductive layer and which extends through the dielectric layer and innermost insulating layer into the instrument channel. 2. An energy conveying structure according to claim 1 , wherein the instrument channel has a diameter between 1 mm and 5 mm. 3. An energy conveying structure according to claim 1 , wherein the first terminal is located proximally from the second terminal. 4. An electrosurgical device comprising: an energy conveying structure according to claim 1 ; and an electrosurgical instrument mounted in the instrument channel of the energy conveying structure, wherein the electrosurgical instrument comprises: a first contact that is electrically connectable to the first terminal; a second contact that is electrically connected to the second terminal; a distal bipolar transmission structure electrically connected to the first contact and the second contact for delivering the RF and/or microwave energy into biological tissue. 5. An electrosurgical device according to claim 4 , wherein the distal bipolar transmission structure comprises a first conductive element that is electrically connected to the first contact and a second conductive element that is electrically connected to the first contact. 6. An electrosurgical device according to claim 5 , wherein the first contact and the second contact are formed on a connection collar located proximally to the bipolar transmission structure. 7. An electrosurgical device according to claim 4 including a catheter for conveying a control wire or a fluid feed to the electrosurgical instrument, the catheter being slidably mounted in the instrument channel. 8. An electrosurgical device according to claim 6 including a catheter for conveying a control wire or a fluid feed to the electrosurgical instrument, the catheter being slidably mounted in the instrument channel, and wherein the connection collar is mounted on an outer surface of the catheter. 9. An electrosurgical device according to claim 6 , wherein the connection collar includes a shoulder for abutting a projection at the distal end of the instrument channel. 10. An electrosurgical device according to claim 6 including an extension sleeve that extends axially away from the connection collar towards the bipolar transmission structure at the distal end of the electrosurgical instrument. 11. An electrosurgical device according to claim 10 , wherein the extension sleeve comprises a tube of dielectric material, and carries a conductive structure which provides electrical connection between the first contact and first conductive element and between the second contact and second conductive element respectively. 12. An electrosurgical device according to claim 4 , wherein a geometry of an interconnection between the electrosurgical instrument and the energy conveying structure is configured to create an impedance match between the electrosurgical instrument and the energy conveying structure at a frequency of microwave energy conveyed by the energy conveying structure. 13. An electrosurgical device according to claim 4 , wherein the dielectric material is formed from polyimide. 14. An electrosurgical device according to claim 4 , wherein the energy conveying structure comprises an additional conductor which forms a first pole of an RF-carrying bipolar transmission line, and wherein the inner conductive layer and the outer conductive layer form a second pole of the RF-carrying bipolar transmission line. 15. An electrosurgical device according to claim 14 , wherein the additional conductor is a conductive wire carried within the instrument channel. 16. An invasive electrosurgical scoping device comprising: a flexible insertion tube having a longitudinal bore formed therethrough; an electrosurgical device according to claim 4 inserted in the longitudinal bore. 17. An invasive electrosurgical scoping device according to claim 16 , wherein the flexible insertion tube includes a stop flange at its distal end, the stop flange having a projection that overhangs an entrance to the instrument channel. 18. An invasive electrosurgical scoping device according to claim 16 , wherein the flexible insertion tube includes a resilient seal mounted over an entrance to the instrument channel. 19. An energy conveying structure according to claim 1 , wherein the coaxial layered structure forms a liner that can be detachably mounted in a longitudinal bore of the flexible insertion tube of the invasive surgical scoping device. 20. An invasive electrosurgical scoping device comprising a body having a flexible insertion tube extending therefrom, wherein the flexible insertion tube comprises: an observation channel formed therethrough, a longitudinal bore formed therethrough, and an energy conveying structure according to claim 1 integrally mounted in the longitudinal bore. 21. An invasive surgical scoping device comprising a body having a flexible insertion tube extending therefrom, wherein the flexible insertion tube comprises: an observation channel formed therethrough, a longitudinal bore formed therethrough, and an energy conveying structure in the longitudinal bore, the energy conveying structure comprising a coaxial layered structure having: an innermost insulating layer; an inner conductive layer formed on the innermost insulating layer; an outer conductive layer formed coaxially with the inner conductive layer; and a dielectric layer separating the inner conductive layer and the outer conductive layer, wherein the inner conductive layer, the outer conductive layer and the dielectric layer form a transmission line for conveying radiofrequency (RF) or microwave energy, and wherein the innermost insulating layer is hollow to form an instrument channel of the invasive surgical scoping device, and wherein at least the innermost insulating layer, the inner conductive layer and at least a portion of the dielectric layer form a liner that can be detachably mounted in the longitudinal bore. 22. An invasive surgical scoping device according to claim 21 , wherein the outer conductive layer and a remaining portion of the dielectric layer are integrally formed in the wall of the longitudinal bore. 23. An invasive surgical scoping device according to claim 21 , wherein the coaxial layered structure forms a liner t