System and method for altering rotational alignment of bone sections

What is claimed is: 1. A method for altering rotational alignment of two sections of a patient's bone, comprising: providing an intramedullary rotational correction device comprising: a first portion configured to be secured to a first section of bone; a second portion configured to be secured to a second section of bone; an actuator disposed in the first portion; and a rotary nut, the rotary nut having one or more non-linear spline configured to communicate with a non-linear groove of the first portion, wherein upon a rotation of the rotary nut by the actuator the non-linear spline of the rotary nut is configured to communicate with the non-linear groove of the first portion and rotate the first portion relative to the second portion; securing the first portion of a intramedullary rotational correction device to a first section of a patient's bone; securing the second portion of the intramedullary rotational correction device to a second section of the patient's bone; positioning an external adjustment device in external proximity to the patient's bone, the external adjustment device configured to activate the actuator disposed within the intramedullary rotational correction device; and operating the external adjustment device to activate the actuator of the intramedullary rotational correction device, the actuator thereby causing a rotation of the second portion of the intramedullary rotational correction device with respect to the first portion of the intramedullary rotational correction device. 2. The method of claim 1 , wherein the actuator comprises a rotatable permanent magnet. 3. The method of claim 2 , wherein the external adjustment device comprises one or more rotatable magnets configured to generate a rotating magnetic field. 4. The method of claim 3 , wherein the rotating magnetic field causes the rotatable permanent magnet of the intramedullary rotational correction device to rotate and thereby effectuate a change in the rotational orientation of the second portion relative to the first portion. 5. The method of claim 2 , wherein the rotary nut is in mechanical communication with a lead screw, the lead screw operatively connected to the rotatable permanent magnet and configured to be rotated by the operating of the external adjustment device. 6. The method of claim 5 , wherein a slip clutch is located between the magnet and the lead screw and configured to prevent binding of the rotatable permanent magnet and the lead screw. 7. The method of claim 1 , wherein the one or more non-linear splines are located on at least a portion of a surface of the rotary nut, the one or more non-linear splines are configured to interface with corresponding non-linear grooves disposed along an inner surface of the first portion of the intramedullary rotational correction device. 8. The method of claim 7 , wherein one or more of the non-linear splines disposed on the rotary nut, and the non-linear grooves on the inner surface of the first portion, form a helical arrangement. 9. The method of claim 8 , wherein one or more ball bearings are disposed between the non-linear grooves of the rotary nut and the first portion. 10. A intramedullary rotational correction device, comprising: a first portion comprising a housing and configured to be secured to a first section of a patient's bone; a second portion comprising a shaft and configured to be secured to a second section of the patient's bone; an actuator disposed within the housing of the first portion; and a rotary nut, the rotary nut having one or more non-linear spline configured to communicate with a non-linear groove of the first portion, wherein upon a rotation of the rotary nut by the actuator the non-linear spline of the rotary nut is configured to communicate with the non-linear groove of the first portion and rotate the first portion relative to the second portion. 11. The intramedullary rotational correction device of claim 10 , wherein the actuator comprises a rotatable permanent magnet. 12. The intramedullary rotational correction device of claim 11 , further comprising: an external adjustment device comprising at least one rotatable magnet configured to rotate the rotatable permanent magnet, and rotate the second portion in relation to the first portion. 13. The intramedullary rotational correction device of claim 12 , comprising a lead screw operatively coupled to the rotatable permanent magnet. 14. The intramedullary rotational correction device of claim 13 , the rotary nut in communication with the lead screw, wherein rotation of the rotatable permanent magnet rotates the lead screw which rotates the rotary nut, the rotary nut thereby rotating the second portion in relation to the first portion. 15. The intramedullary rotational correction device of claim 10 , comprising one or more planetary gear set. 16. The intramedullary rotational correction device of claim 10 , comprising one or more extension portion. 17. The intramedullary rotational correction device of claim 10 , the one or more non-linear splines located on at least a portion of a surface of the rotary nut, the one or more non-linear splines configured to interface with corresponding non-linear grooves disposed along an inner surface of the first portion of the intramedullary rotational correction device. 18. The intramedullary rotational correction device of claim 17 , wherein one or more of: the non-linear splines disposed on the rotary nut and the non-linear grooves on the inner surface of the first portion, form a helical arrangement. 19. The intramedullary rotational correction device of claim 18 , further comprising one or more ball bearing disposed between the non-linear grooves of the rotary nut and the first portion.