Multi-direction steerable handles

The invention claimed is: 1. A control handle for a steerable transluminal device, the control handle comprising: a housing defining a longitudinal axis extending in distal and proximal directions; pull wires that extend from a distal end of the housing and into the steerable transluminal device and that extend along an axial length of the steerable transluminal device and that are operable to effect flexion of the steerable transluminal device; a flex control member operable to control tension on the pull wires to adjust a magnitude of radial flexion of the steerable transluminal device; a position control member operable to control tension on the pull wires to adjust a circumferential angle in which the radial flexion of the steerable transluminal device is directed; a cam member that is movable axially relative to the housing and also movable rotationally about the longitudinal axis relative to the housing; at least one follower engaged with the cam member such that the at least one follower moves relative to the control handle in response to movement of the cam member relative to the housing; wherein the pull wires are coupled to the at least one follower; wherein rotation of the flex control member causes axial adjustment of the cam member; and wherein the position control member is fixed relative to the cam member and rotation of the position control member causes rotational adjustment of the cam member. 2. The control handle of claim 1 , wherein the flex control member is operable to increase or decrease tension of all the pull wires to adjust the magnitude of radial flexion of the steerable transluminal device, and wherein the position control member is operable to increase tension in one or more pull wires and simultaneously reduce tension in one or more other pull wires to adjust the circumferential angle in which the radial flexion of the steerable transluminal device is directed. 3. The control handle of claim 1 , further comprising a clutch mechanism having an engaged position operable to lock the position control member such that the circumferential angle of the steerable transluminal device is fixed while allowing operation of the flex control member to adjust the magnitude of radial flexion of the steerable transluminal device. 4. The control handle of claim 1 , wherein the flex control member is fixed axially relative to a central shaft that extends axially through the cam member and is rotationally engaged with the housing to allow rotation of the flex control member relative to the housing and restrict axial motion of the flex control member and the central shaft relative to the housing. 5. The control handle of claim 1 , wherein the cam member comprises a contact surface at one axial end that interfaces with the at least one follower, the contact surface having a slope that varies in axial position as a function of circumferential position around the longitudinal axis of the control handle, and wherein the slope of the cam member contact surface varies gradually in axial position moving circumferentially around the contact surface, such that the at least one follower moves gradually axially as the cam member is rotated about the longitudinal axis of the control handle. 6. The control handle of claim 1 , wherein the at least one follower comprises a gimbal mechanism including a gimbal ring and a gimbal plate, wherein the gimbal ring is pivotably coupled within the housing and the gimbal plate is pivotably coupled within the gimbal ring. 7. The control handle of claim 1 , wherein the flex control member and the position control member are independently operable to allow independent adjustment of the magnitude of radial flexion of the of the steerable transluminal device and independent adjustment of the circumferential angle in which the radial flexion of the steerable transluminal device is directed. 8. The control handle of claim 4 , wherein the central shaft is engaged with the cam member such that rotation of the flex control member relative to the housing causes axial motion of the cam member relative to the housing. 9. The control handle of claim 5 , wherein the cam member contact surface is a planar surface that defines an oblique plane that is not parallel or perpendicular to the longitudinal axis of the control handle. 10. The control handle of claim 6 , wherein the pull wires are coupled to the gimbal plate, the cam member is in contact with the gimbal plate, and the position of the cam member determines an orientation of the gimbal mechanism, and the orientation of the gimbal mechanism determines axial positions of the pull wires. 11. The control handle of claim 6 , wherein the pull wires are looped around wire guides in the gimbal mechanism, or the pull wires are looped around wire guides fixed relative to the housing proximal to the gimbal mechanism, or both. 12. The control handle of claim 10 , wherein the gimbal plate comprises one or more bumps or valleys where the cam member contacts the gimbal plate, such that the cam member's axial position relative to the gimbal plate is slightly adjusted when the cam member contacts the one or more bumps or valleys. 13. The control handle of claim 7 , wherein the magnitude of radial flexion of the steerable transluminal device and the circumferential angle in which the radial flexion of the steerable transluminal device is directed can be adjusted without rotating the steerable transluminal device about its longitudinal axis.