Implantable medical leads, systems, and related methods for creating a high impedance within a conduction path in the presence of a magnetic field of a given strength

What is claimed is: 1. A method of creating a high impedance within a conduction path of an implantable medical lead, comprising: providing a first actuator that when in the presence of a magnetic field attempts to move from a first start position to a first stop position and reaches the first stop position when a force acting on the first actuator due to the presence of the magnetic field is adequate to produce such movement, the first actuator being responsive to magnetic fields that are not oriented normal to a direction of movement of the first actuator; providing a second actuator that when in the presence of a magnetic field attempts to move from a second start position to a second stop position and reaches the second stop position when a force acting on the second actuator due to the presence of the magnetic field is adequate to produce such movement, the second actuator being responsive to magnetic fields that are not oriented parallel to a direction of movement of the second actuator; and providing at least one switch in series with the conduction path that resides in a closed state and achieves an open state to create the high impedance when the first actuator reaches the first stop position and/or when the second actuator reaches the second stop position. 2. The method of claim 1 , wherein providing at least one switch comprises providing one switch that achieves the open state to create the high impedance when the first actuator reaches the first stop position and/or when the second actuator reaches the second stop position. 3. The method of claim 1 , wherein providing at least one switch comprises providing a first switch that is coupled to the first actuator and that achieves the open state to create the open circuit when the first actuator reaches the first stop position and providing a second switch that is coupled to the second actuator and that achieves the open state to create the high impedance when the second actuator reaches the second stop position. 4. The method of claim 1 , wherein a force from the magnetic field acting on the first actuator is at a maximum when a force from the magnetic field acting on the second actuator is at a minimum. 5. The method of claim 1 , wherein providing the first actuator comprises positioning the first actuator coaxially with the second actuator and within a bore of the second actuator. 6. The method of claim 1 , wherein providing the first actuator comprises providing a pin attached to a first piece of ferromagnetic material and a cylinder that surrounds the pin and is attached to a second piece of ferromagnetic material, wherein the first piece and the second piece are separated by a distance when the first actuator is in the first start position and wherein the distance decreases as the first actuator moves toward the first stop position. 7. The method of claim 1 , wherein providing the second actuator comprises providing a cylinder that comprises alternating layers of ferromagnetic material and non-ferromagnetic material and providing an outer cylinder that surrounds the cylinder and comprises alternating layers of ferromagnetic material, such that the ferromagnetic material of the cylinder has a position in the direction of movement of the second actuator that is unaligned with a position in the direction of movement of the second actuator of the ferromagnetic material of the outer cylinder when the second actuator is in the second start position and wherein the position of the ferromagnetic material of the cylinder becomes more aligned in the direction of movement of the second actuator with the position of the ferromagnetic material of the outer cylinder as the second actuator moves toward the second stop position. 8. The method of claim 1 , wherein the direction of movement of the first actuator is parallel to the direction of movement of the second actuator. 9. A method of creating a high impedance within a conduction path of an implantable medical lead, comprising: providing a first magnetically responsive actuator that when in a presence of a magnetic field of an MRI scanner moves from a first start position toward a first stop position the magnetic field is not oriented normal to a direction of movement of the first actuator; providing a second magnetically responsive actuator that when in the presence of the magnetic field moves from a second start position toward a second stop position when the magnetic field is not oriented parallel to a direction of movement of the second actuator; and providing at least one switch in series with the conduction path, the at least one switch being coupled to both the first actuator and the second actuator, wherein the at least one switch resides in a closed state and achieves an open state to create the high impedance when the first actuator moves toward the first stop position and/or when the second actuator moves toward the second stop position. 10. The method of claim 9 , wherein providing at least one switch comprises providing one switch that achieves the open state to create the high impedance when the first actuator moves toward the first stop position and/or when the second actuator moves toward the second stop position. 11. The method of claim 9 , wherein providing at least one switch comprises providing a first switch that is coupled to the first actuator and that achieves the open state to create the open circuit when the first actuator reaches the first stop position and providing a second switch that is coupled to the second actuator and that achieves the open state to create the high impedance when the second actuator reaches the second stop position. 12. The method of claim 9 , wherein a force from the magnetic field acting on the first actuator is at a maximum when a force from the magnetic field acting on the second actuator is at a minimum. 13. The method of claim 9 , wherein providing the first actuator comprises positioning the first actuator coaxially with the second actuator and within a bore of the second actuator. 14. The method of claim 9 , wherein providing the first actuator comprises providing a pin attached to a first piece of ferromagnetic material and a cylinder that surrounds the pin and is attached to a second piece of ferromagnetic material, wherein the first piece and the second piece are separated by a distance when the first actuator is in the first start position and wherein the distance decreases as the first actuator moves toward the first stop position. 15. The method of claim 9 , wherein providing the second actuator comprises providing a cylinder that comprises alternating layers of ferromagnetic material and non-ferromagnetic material and providing an outer cylinder that surrounds the cylinder and comprises alternating layers of ferromagnetic material, such that the ferromagnetic material of the cylinder has a position in the direction of movement of the second actuator that is unaligned with a position in the direction of movement of the second actuator of the ferromagnetic material of the outer cylinder when the second actuator is in the second start position and wherein the position of the ferromagnetic material of the cylinder becomes more aligned in the direction of movement of the second actuator with the position of the ferromagnetic material of the outer cylinder as the second actuator moves toward the second stop position. 16. The method of claim 9 , wherein the direction of movement of the first actuator is parallel to the direction of movement of the second actuator. 17. An implantable medical lead, comprising: a lead body; at least