Apparatus and method for sensing force on a robotically controlled medical instrument

What is claimed is: 1. A medical instrument system, comprising: an elongated probe body having a bendable section, a distal tip section, and an axially variable-length section disposed between the bendable and distal tip sections, the probe body having a lumen axially extending therethrough; a push-pull member slidably disposed in the lumen of the probe body, the push-pull member having a distal end affixed to the distal tip section of the probe body and a proximal end portion extending out a proximal end of the probe body; a dithering mechanism configured to mechanically couple to the proximal end portion of the push-pull member, the dithering mechanism further configured for cyclically displacing the push-pull member axially back and forth within the lumen of the probe body, such that the distal tip section is axially displaced relative to bendable section via the axially variable-length section; at least one force sensor positioned adjacent to the proximal end portion of the push-pull member, the at least one force sensor being configured for measuring a load applied to the push-pull member; and a processor operatively coupled to the at least one force sensor and configured for determining an external force axially applied to the distal tip section of the probe body based on signals received from the at least one force sensor. 2. The medical instrument system of claim 1 , wherein the probe body comprises a flexible intravascular catheter body having an operative element mounted on the distal tip section. 3. The medical instrument system of claim 1 , wherein the axially variable-length section of the probe body comprises an axially compressible polymer sleeve. 4. The medical instrument system of claim 1 , wherein the axially variable-length section of the probe body comprises a bellows. 5. The medical instrument system of claim 1 , wherein the axially variable-length section of the probe body comprises a spring, the spring having a distal end coupled to the distal tip section and a proximal end coupled to the bendable section. 6. The medical instrument system of claim 1 , wherein the at least one force sensor is mounted on the dithering mechanism. 7. The medical instrument system of claim 1 , wherein the push-pull member comprises a fluid delivery tube having an open distal end coupled to the distal tip section. 8. The medical instrument system of claim 1 , wherein the medical probe further includes at least one control element extending within the probe body, and wherein the system is a robotically controlled instrument system, including an instrument driver having an adapter configured to be operatively coupled to the at least one control element for bending the bendable section of the probe body in at least one direction, and wherein the dithering mechanism is mounted on the instrument driver. 9. The medical instrument system of claim 1 , wherein the probe body is manually controlled using a handle attached to a proximal end of the probe body, and wherein the dithering mechanism is located on or in the handle. 10. The medical instrument system of claim 1 , wherein the processor determines the external force axially applied to the distal tip section of the probe by: obtaining a baseline force measurement from the at least one force sensor when the push-pull member is dithered back and forth without any external axial force being applied to the distal tip section of the probe body, obtaining a total force measurement from the at least one force sensor when the push-pull member is dithered back and forth with an external axial force applied to the distal tip section of the probe body, and computing the external axial force applied to the distal tip section of the probe body by subtracting the baseline force measurement from the total force measurement. 11. A medical instrument system, comprising: an elongated probe body having a bendable section, a distal tip section, and an axially variable-length section disposed between the bendable and distal tip sections; a push-pull member slidably disposed in an axially extending lumen of the probe body, the push-pull member having a distal end affixed to the distal tip section of the probe body and a proximal end portion extending out a proximal end of the probe body; a dithering mechanism configured for attaching to the proximal end portion of the push-pull member, the dithering mechanism further configured for cyclically displacing the push-pull member axially back and forth within the lumen of the probe body, such that the distal tip section of the probe body is axially displaced relative to bendable section of the probe body via the axially variable-length section of the probe body; and a force sensor positioned adjacent to the proximal end portion of the push-pull member, the force sensor being fixed relative to the push-pull member and configured for measuring a load applied to the push-pull member. 12. The medical instrument system of claim 11 , wherein the axially variable-length section of the probe body comprises an axially compressible polymer sleeve and a spring carried in a lumen of the sleeve, the spring having a distal end coupled to the distal tip section of the probe body, and a proximal end coupled to the bendable section of the probe body, such that the spring is cyclically compressed and decompressed as the distal tip section is axially dithered back and forth relative to the bendable section, the push-pull member extending through a lumen of the spring. 13. The medical instrument system of claim 11 , further comprising a stiffening coil extending axially through the lumen of the probe body, the push-pull member extending through a central lumen of the stiffening coil, the bendable section of the probe body terminating distally at a steering wire anchor, the stiffening coil extending distally past the steering wire anchor and through the axially variable-length section to the distal tip section of the probe body, wherein a pitch of a portion of the stiffening coil passing through the axially variable-length section is significantly opened up compared with a pitch of the more proximal portion of the stiffening coil, so that the portion of the stiffening coil passing through the axially variable-length section of the probe body acts as a spring to maintain the push-pull member in tension as the push-pull member is dithered back and forth through the probe body lumen. 14. The medical instrument system of claim 11 , wherein the force sensor is mounted on the dithering mechanism. 15. The medical instrument system of claim 11 , wherein the push-pull member comprises a fluid delivery tube. 16. The medical instrument system of claim 11 , wherein the system is a robotically controlled instrument system, including an instrument driver having an adapter configured to be operatively coupled to one or more steering wires extending through the bendable section of the probe body, and wherein the dithering mechanism is mounted on the instrument driver. 17. The medical instrument system of claim 11 , wherein the probe body is manually controlled using a handle attached to a proximal end of the probe body, and wherein the dithering mechanism is located on or in the handle. 18. The medical instrument system of claim 11 , further comprising a processor operatively coupled to the force sensor and configured for determining an external force axially applied to the distal tip section of the probe body by: obtaining a baseline force measurement from the at least one force sensor when the push-pull member is dithered ba