Less invasive methods for ablation of fat pads

The invention claimed is: 1. A method for ablating epicardial tissue within a body of a subject, comprising the steps of: percutaneously inserting a catheter comprising a position sensor at a distal tip into a pericardial cavity of said body; locating epicardial target tissue in said pericardial cavity for ablation thereof, wherein said epicardial target tissue is only one epicardial fat pad; determining position coordinates of said catheter relative to an epicardial surface of a heart using a control unit and the position sensor, said position coordinates comprising location and orientation information of the distal tip of the catheter; displaying said location and orientation information of the distal tip of the catheter relative to the epicardial surface of the heart on a display; disposing said catheter in proximity to said only one epicardial fat pad; orienting said distal tip of said catheter with respect to said only one epicardial fat pad using a deflection wire coupled to a distal end of said catheter and manipulating a specified surface of an electrode of said distal tip of said catheter against said only one epicardial fat pad using said deflection wire so as to maximize energy transfer from said catheter to said only one epicardial fat pad; and directing sufficient energy from said distal tip of said catheter preferentially toward said only one epicardial fat pad to ablate neural structures therein. 2. The method according to claim 1 , wherein orienting said catheter comprises sensing location and orientation information thereof and moving said catheter responsively to said information. 3. The method according to claim 1 , wherein said energy comprises ultrasound energy. 4. The method according to claim 3 , further comprising the step of focusing said ultrasound energy onto said only one epicardial fat pad. 5. The method according to claim 1 , wherein said energy comprises laser energy. 6. The method according to claim 1 , wherein said energy comprises microwave energy. 7. The method according to claim 1 , wherein said catheter comprises a resonant circuit having a resonant frequency; further comprising the steps of: generating radiofrequency energy at a site remote from said resonant circuit, at said resonant frequency; and re-radiating energy toward said only one epicardial fat pad using said resonant circuit. 8. The method of claim 1 , wherein said epicardial target tissue further comprises an epicardial ganglion that is within said only one epicardial fat pad. 9. The method of claim 1 , wherein said locating epicardial target tissue in said pericardial cavity comprises using a noninvasive imaging method. 10. A minimally invasive method for ablating epicardial tissue within a body of a subject, comprising steps of: percutaneously inserting a catheter comprising a position sensor at a distal tip into a pericardial cavity of said body; locating epicardial target tissue in said pericardial cavity for ablation thereof, wherein said epicardial target tissue is only one epicardial fat pad; determining position coordinates of said catheter relative to an epicardial surface of a heart using a control unit and the position sensor, said position coordinates comprising location and orientation information of the distal tip of the catheter; displaying said location and orientation information of the distal tip of the catheter relative to the epicardial surface of the heart on a display; disposing said catheter in proximity to said only one epicardial fat pad; orienting said distal tip of said catheter with respect to said only one epicardial fat pad using a deflection wire coupled to a distal end of said catheter so as to maximize energy transfer from said catheter to said only one epicardial fat pad; directing sufficient energy from said distal tip of said catheter preferentially toward said only one epicardial fat pad to ablate neural structures therein; and manipulating a specified surface of said catheter against said only one epicardial fat pad using said deflection wire for maximizing said energy transfer from said catheter to said only one epicardial fat pad when performing said step of directing sufficient energy from said catheter, wherein said specified surface includes an exposed surface of a transducer being at said distal tip of said catheter and substantially planar, and wherein said step of orienting said catheter includes manipulating said substantially planar exposed surface of said transducer against said only one epicardial fat pad, wherein said energy transfer is generally perpendicular to said exposed surface of said transducer. 11. The method of claim 10 , wherein said epicardial target tissue further comprises an epicardial ganglion that is within said only one epicardial fat pad. 12. The method according to claim 10 , wherein said energy comprises ultrasound energy. 13. The method of claim 9 , wherein said noninvasive imaging method is selected from the group consisting of cardiac CT, MR imaging, and cardiac neurotransmission imaging. 14. The method of claim 10 , wherein said locating epicardial target tissue in said pericardial cavity comprises using a noninvasive imaging method. 15. The method of claim 14 , wherein said noninvasive imaging method is selected from the group consisting of cardiac CT, MR imaging, and cardiac neurotransmission imaging.