Endobronchial catheter

The invention claimed is: 1. A method of endoscopy comprising the steps of: (a) inserting into a bronchus of a lung an elongated assembly having a lumen, a long axis, a separate channel extending alongside with the lumen, a distal segment, and a deflector disposed in the distal segment, the lumen extending generally along the long axis, the deflector having a proximal end defining a first entrance pore in communication with the lumen, a second entrance pore located distally from the first entrance pore, and an exit pore, wherein the second entrance pore is in communication with the separate channel, the deflector defining a bore in communication with the first entrance pore, the second entrance pore, and the exit pore, the bore extending therethrough at an angle to the long axis, wherein the exit pore is laterally oriented relative to the lumen; (b) introducing a tool into the deflector via either the first entrance pore or the second entrance pore; (c) transmitting signals from a location sensor disposed in the distal segment to a position processor that is operative for computing a location of the distal segment responsively to the signals from the location sensor; (d) imaging a target in the lung using an ultrasound imager disposed in the distal segment and transmitting data provided by the ultrasound imager to electronic circuitry for processing thereof; (e) urging the exit pore of the deflector laterally against a wall of the bronchus by inflating an inflatable balloon disposed on the distal segment, wherein the inflatable balloon is positioned contralateral to the exit pore, wherein the inflatable balloon defines a longitudinally extending groove, wherein the elongated assembly further comprises a tubular segment laterally received in the longitudinally extending groove; (f) thereafter penetrating the wall of the bronchus with the tool via the exit pore, as the exit pore is urged against the wall of the bronchus by the inflated inflatable balloon, to reach the target in the lung with the tool; (g) anchoring the assembly to provide counter-traction thereon while penetrating the wall of the bronchus using a push-pull anchoring system comprising a plurality of guides and respective wires threaded therethrough by moving the wires between a first position wherein the wires are retracted within the guides and a second position wherein the wires extend beyond the guides and diverge from the long axis sufficiently to engage the wall of the bronchus; and (h) performing an operation on the target using the tool. 2. The method according to claim 1 , wherein introducing the tool comprises passing the tool through the lumen such that the deflector deflects a distal portion of the tool laterally relative to the lumen and out through the exit pore. 3. The method according to claim 1 , wherein the assembly further comprises a proximal segment and a handle having a wire control disposed on the proximal segment, wherein anchoring the assembly comprises moving the wires by activating the wire control. 4. The method according to claim 1 , wherein the location sensor is a tri-axial magnetic field sensor. 5. The method according to claim 1 , wherein the location sensor is an electrode that reports impedance measurement signals to the position processor cooperatively with a plurality of body surface electrodes. 6. The method according to claim 1 , wherein the inflatable balloon is positioned distally in relation to the exit pore. 7. The method according to claim 1 , wherein the longitudinally extending groove is angularly positioned to correspond with an angular position of the exit pore in relation to the long axis, thereby positioning the inflatable balloon contralaterally relative to the exit pore. 8. The method according to claim 1 , wherein each wire exits through a respective pair of ports, wherein each pair of ports comprises a first port and a corresponding second port. 9. The method according to claim 8 , wherein each first port is positioned distally in relation to the corresponding second port.