System and catheter for image guidance and methods thereof

What is claimed: 1. A catheter-based imaging system comprising: a catheter having a telescoping proximal end, a distal end having a distal sheath and a distal lumen, a working lumen, and an ultrasonic imaging core, the ultrasonic imaging core being arranged for rotation and linear translation, the working lumen extending from the telescoping proximal end toward the distal end adjacent to the ultrasonic imaging core; a patient interface module (PIM) including a linkage arm mount, a rotational motor, a gear and arm system comprising a first gear coupled to a linkage arm, and an ultrasonic energy generator and receiver coupled to the ultrasonic imaging core, the rotational motor being directly coupled to the first gear, and the linkage arm being directly coupled to the linkage arm mount, wherein the rotational motor imparts controlled rotation to the ultrasonic imaging core and the rotational motor is adapted to drive the gear and arm system to impart controlled, linear, and bidirectional translation to the ultrasonic imaging core, wherein the PIM includes a translation stage, the translation stage being rigidly fixed to both the first gear and the rotational motor, and the linkage arm being adapted to couple the first gear to the linkage arm mount, and wherein the rotational motor imparts controlled linear, and bidirectional translation by rotating the first gear such that the translation stage is linearly translated relative to the linkage arm mount via the linage arm; and an imaging engine configured to electrically interface with the PIM, the imaging engine coupled to the ultrasonic energy receiver, the imaging engine adapted to generate an image. 2. The catheter-based imaging system of claim 1 , wherein the catheter is adapted for intracardiac use. 3. The catheter-based imaging system of claim 1 , wherein the catheter is adapted for transesophageal use. 4. The catheter-based imaging system of claim 1 , further comprising a compliant balloon at the catheter distal end. 5. The catheter-based imaging system of claim 4 , wherein the catheter comprises an inflation lumen in fluid communication with the balloon. 6. The catheter-based imaging system of claim 4 , wherein the catheter comprises an inflation lumen and a deflation lumen in fluid communication with the balloon. 7. The catheter-based imaging system of claim 4 , wherein the catheter distal end is in fluid communication with the balloon. 8. The catheter-based imaging system of claim 1 , wherein the catheter is dimensioned for transnasal delivery. 9. The catheter-based imaging system of claim 1 , wherein the ultrasonic imaging core comprises at least one transducer. 10. The catheter-based imaging system of claim 1 , wherein the ultrasonic imaging core comprises at least one transducer array. 11. The catheter-based imaging system of claim 1 , wherein the rotational motor comprises an ultrasonic piezoelectric motor. 12. The catheter-based imaging system of claim 1 , wherein the PIM comprises a linear translation position sensor including a sensor array and a magnet disposed within the PIM, wherein linear translation of the ultrasonic imaging core causes a corresponding linear translation of the magnet relative to the sensor array, and wherein sensors of the sensor array are configured to sense the magnet and are aligned along a travel range of the magnet. 13. The catheter-based imaging system of claim 1 , wherein the imaging engine is further adapted to identify susceptible substrates responsive to ultrasound tissue classifiers. 14. The catheter-based imaging system of claim 1 , further comprising a temperature monitor that monitors luminal esophageal temperature responsive to ultrasound tissue classifiers. 15. The catheter-based imaging system of claim 9 , wherein the imaging engine is further adapted to stitch scanned image sub-volumes into a large scanned image volume. 16. The catheter-based imaging system of claim 9 , wherein the imaging engine is further adapted to be responsive to the ultrasonic imaging core to provide synthetic aperture imaging. 17. The catheter-based imaging system of claim 10 , wherein the imaging engine is further adapted to be responsive to the at least one transducer array to provide synthetic aperture imaging. 18. The catheter-based imaging system of claim 9 , wherein the imaging engine is further adapted to be responsive to the ultrasonic imaging core to provide synthetic aperture beam steering. 19. The catheter-based imaging system of claim 10 , wherein the imaging engine is further adapted to be responsive to the at least one transducer array to provide synthetic aperture beam steering. 20. The catheter-based imaging system of claim 1 , wherein the catheter distal end comprises a self-sealing septum, an atraumatic tip, and a septum puncture port. 21. The catheter-based imaging system of claim 1 , wherein the catheter distal tip comprises a short monorail rapid exchange guidewire receiver. 22. The catheter-based imaging system of claim 1 , wherein the catheter comprises an over-the-wire guidewire receiver. 23. The catheter-based imaging system of claim 1 , wherein the catheter comprises a steerable section. 24. The catheter-based imaging system of claim 1 , wherein the catheter comprises a second working lumen. 25. The catheter-based imaging system of claim 1 , wherein the ultrasonic imaging core comprises a magnetic tracking sensor. 26. The catheter-based imaging system of claim 1 , wherein the catheter distal sheath comprises a radio-opaque marker band. 27. A catheter-based imaging system, comprising: a catheter having a telescoping proximal end, a distal end having a distal sheath and a distal lumen, a working lumen, and an ultrasonic imaging core, the ultrasonic imaging core being arranged for rotation and linear translation, the working lumen extending from the telescoping proximal end toward the distal end adjacent to the ultrasonic imaging core; a patient interface module (PIM) including a linkage arm mount, a gear and arm system comprising a first gear coupled to a linkage arm, a rotational motor, a translation stage, and an ultrasonic energy generator and receiver coupled to the ultrasonic imaging core, linear rotational motor being directly coupled to the first gear, and the linkage arm being directly coupled to the linkage arm mount, wherein the rotational motor is adapted to impart controlled rotation to the ultrasonic imaging core and to drive the gear and arm system to impart controlled, linear, and bidirectional translation to the ultrasonic imaging core, and an ultrasonic energy generator and receiver coupled to the ultrasonic imaging core; wherein the translation stage is rigidly fixed to the rotational motor, and wherein the rotational motor is configured to move along with and linearly translate the translation stage; and an imaging engine configured to electrically interface with the PIM, the imaging engine coupled to the ultrasonic energy receiver, the imaging adapted to generate an image.