External fixator deformity correction systems and methods

What is claimed is: 1. A computer-implemented method comprising employing at least one processor to execute instructions to: generate a display of a graphical representation of a first ring of a synthetic external fixator superimposed on a display of a medical x-ray image, the medical x-ray image displaying a view of a patient's bone, the graphical representation of the first ring representing a first physical ring of a physical external fixator attached to the patient's bone, the physical external fixator also including a second physical ring and a plurality of physical struts connecting the first physical ring to the second physical ring; generate a display of a first line segment extending along a first segment of the bone shown in the display of the medical x-ray image by detecting locations of corresponding graphical user input on the first segment of the bone shown in the display; for each physical strut shown in the display of the medical x-ray image, receive strut user input entered graphically onto the display of the medical x-ray image, the strut user input representing locations of the physical strut relative to the first physical ring and the second physical ring; generate a strut line segment for each physical strut and displaying the strut line segment on the display such that the strut line segment overlies a corresponding one of the plurality of physical struts shown in the medical x-ray image; and generate a bone deformity correction plan specifying for each physical strut a sequence of strut lengths to be used in a bone deformity correction treatment. 2. The method of claim 1 , wherein the graphical user input on the first segment of the bone shown in the display includes mouse clicks at opposite end portions of the first segment of the bone shown in the display of the medical x-ray image. 3. The method of claim 1 , wherein the strut user input includes a first point of attachment of the physical strut to the first physical ring and a second point of attachment of the physical strut to the second physical ring. 4. The method of claim 3 , wherein the first point of attachment of the physical strut to the first physical ring is (i) a hole in the first physical ring or (ii) an intermediary piece of hardware coupled to the first physical ring. 5. The method of claim 4 , wherein the first point of attachment of the physical strut to the first physical ring is the intermediary piece of hardware, the intermediary piece of hardware being a ring drop device adapted to position a corresponding one of the physical struts a predefined distance from the first physical ring. 6. The method of claim 1 , wherein the graphical representation of the first ring of the synthetic external fixator is displayed as an ellipse superimposed on the medical x-ray image. 7. The method of claim 6 , wherein the displayed ellipse is displayed simultaneously with the strut line segments. 8. A computer system comprising at least one microprocessor configured to execute instructions to: generate a display of a graphical representation of a first ring of a synthetic external fixator superimposed on a display of a medical x-ray image, the medical x-ray image displaying a view of a patient's bone, the graphical representation of the first ring representing a first physical ring of a physical external fixator attached to the patient's bone, the physical external fixator also including a second physical ring and a plurality of physical struts connecting the first physical ring to the second physical ring; generate a display of a first line segment extending along a first segment of the bone shown in the display of the medical x-ray image by detecting locations of corresponding graphical user input on the first segment of the bone shown in the display; for each physical strut shown in the display of the medical x-ray image, receive strut user input entered graphically onto the display of the medical x-ray image, the strut user input representing locations of the physical strut relative to the first physical ring and the second physical ring; generate a strut line segment for each physical strut and displaying the strut line segment on the display such that the strut line segment overlies a corresponding one of the plurality of physical struts shown in the medical x-ray image; and generate a bone deformity correction plan specifying for each physical strut a sequence of strut lengths to be used in a bone deformity correction treatment. 9. The computer system of claim 8 , wherein the graphical user input on the first segment of the bone shown in the display includes mouse clicks at opposite end portions of the first segment of the bone shown in the display of the medical x-ray image. 10. The computer system of claim 8 , wherein the strut user input includes a first point of attachment of the physical strut to the first physical ring and a second point of attachment of the physical strut to the second physical ring. 11. The computer system of claim 10 , wherein the first point of attachment of the physical strut to the first physical ring is (i) a hole in the first physical ring or (ii) an intermediary piece of hardware coupled to the first physical ring. 12. The computer system of claim 11 , wherein the first point of attachment of the physical strut to the first physical ring is the intermediary piece of hardware, the intermediary piece of hardware being a ring drop device adapted to position a corresponding one of the physical struts a predefined distance from the first physical ring. 13. The computer system of claim 8 , wherein the graphical representation of the first ring of the synthetic external fixator is displayed as an ellipse superimposed on the medical x-ray image. 14. The computer system of claim 13 , wherein the displayed ellipse is displayed simultaneously with the strut line segments. 15. A non-transitory computer-readable medium encoding instructions which, when executed by a microprocessor of a computer system, cause the computer system to: generate a display of a graphical representation of a first ring of a synthetic external fixator superimposed on a display of a medical x-ray image, the medical x-ray image displaying a view of a patient's bone, the graphical representation of the first ring representing a first physical ring of a physical external fixator attached to the patient's bone, the physical external fixator also including a second physical ring and a plurality of physical struts connecting the first physical ring to the second physical ring; generate a display of a first line segment extending along a first segment of the bone shown in the display of the medical x-ray image by detecting locations of corresponding graphical user input on the first segment of the bone shown in the display; for each physical strut shown in the display of the medical x-ray image, receive strut user input entered graphically onto the display of the medical x-ray image, the strut user input representing locations of the physical strut relative to the first physical ring and the second physical ring; generate a strut line segment for each physical strut and displaying the strut line segment on the display such that the strut line segment overlies a corresponding one of the plurality of physical struts shown in the medical x-ray image; and generate a bone deformity correction plan specifying for each physical strut a sequence of strut lengths to be used in a bone deformity correction treatment. 16. The non-transitory computer-readable medium of claim 15 , wherein the graphical user input on the first segment of the