Method of calibrating a spinal cage

The invention claimed is: 1. A computer implemented medical method of calibrating a cage, comprising the steps: acquiring, by holding a pointer tip of a pointing device against a cage tip of the cage, a cage tip coordinate at the cage tip of the cage, wherein the cage tip is disposed at a first end of the cage in a length direction of the cage; acquiring, by holding the pointer tip of the pointing device against a cage end of the cage, a cage end coordinate at the cage end of the cage, wherein the cage end is disposed at a second end of the cage, opposing to the first end, in the length direction; acquiring, by holding a pointer shaft of the pointing device against a cage side of the cage, at least one axis along the side of the cage, wherein the pointer shaft relates to a part of the pointing device, extending away from the pointer tip; and determining a calibrated virtual model of the cage using the cage tip coordinate, the cage end coordinate and at least one cage axis. 2. The method of claim 1 , wherein acquiring the cage end coordinate, the cage tip coordinate and/or the at least one cage axis comprises: determining a cage-to-holder-coordinate-transformation (CageToHolder), which describes a transformation between a holder coordinate system (Holder) of a holding device and a cage coordinate system of the cage. 3. The method of claim 2 , wherein acquiring the cage end coordinate, the cage tip coordinate and/or the at least one axis comprises providing a pointer-to-holder-coordinate-transformation (PointerToHolder), which describes a transformation between the pointer coordinate system (Pointer) and the holder coordinate system (Holder); and determining a holder-to-cage-coordinate-transformation (HolderToCage), by using the pointer-to-holder-coordinate-transformation (PointerToHolder). 4. The method of claim 1 , wherein acquiring the cage end coordinate, the cage tip coordinate and/or the at least one axis comprises holding the pointing device onto the cage until the respective cage end coordinate, cage tip coordinate and/or at least one axis is acquired. 5. The method of claim 1 , wherein the virtual model indicates a shape, position and orientation of the cage. 6. The method of claim 1 , wherein the virtual model comprises a multi-dimensional representation of the cage, in particular a 3-dimensional representation of the cage. 7. The method of claim 1 , wherein acquiring the cage end coordinate comprises: acquiring a first holder point and a second holder point at opposing lateral sides of a cage holder, which holds the cage at the second end of the cage, by using the pointer tip of the pointing device; and determining the cage end coordinate as a centre of a connection line between the first holder point and the second holder point. 8. The method of claim 1 , comprising the step: acquiring, by using the pointer shaft of the pointing device, at least one axis along at least one lateral side of the cage in a height direction of the cage. 9. The method of claim 8 , comprising the step: acquiring, by using the pointer shaft of the pointing device, at least one axis along a top side and/or bottom side of the cage in a width direction of the cage. 10. The method of claim 8 , comprising the step: acquiring, by using the pointer shaft of the pointing device, at least one axis along a top side and/or bottom side of the cage in a length direction of the cage. 11. The method of claim 1 , comprising the steps: acquiring, by using the pointer shaft of the pointing device, a first axis along a first lateral side of the cage in a height direction of the cage; a second axis along a second lateral side of the cage opposite of the first lateral side, in the height direction of the cage; a third axis along a top side of the cage in a width direction of the cage; and a fourth axis along a bottom side of the cage in the width direction of the cage. 12. The method of claim 1 , comprising the steps: acquiring, by using the pointer shaft of the pointing device, a first axis along a first lateral side of the cage in a height direction of the cage; a second axis along a second lateral side of the cage opposite of the first lateral side, in the height direction of the cage; a fifth axis along a top side of the cage in a length direction of the cage; and a sixth axis along a bottom side of the cage in the length direction of the cage. 13. The method of claim 1 , wherein, for acquiring the at least one axis in a width direction and/or height direction, the pointer shaft is held in a width axis section distant to the cage end coordinate and the cage tip coordinate. 14. The method of claim 1 , wherein, for acquiring the at least one axis in the length direction, the pointer shaft is held in a length axis section distant to the lateral sides of the cage. 15. The method of claim 1 , wherein determining a calibrated virtual model comprises: determining a cage axis of the cage; determining at least one nearest point of the at least one axis, being the nearest point of the at least one axis to the cage axis; and determining the virtual model using the at least one nearest point. 16. The method of claim 15 , wherein determining the at least one nearest point comprises: determining a length cage axis connecting the cage tip coordinate and the cage end coordinate; determining a width cage axis, extending perpendicular to the length cage axis in a width direction through a centre of the length cage axis in the length direction; determining at least one nearest point of the at least one axis in the width direction and/or a height direction, being the nearest point of the at least one axis to the length cage axis; and determining at least one nearest point of the at least one axis in the length direction being the nearest point of the at least one axis to the width cage axis. 17. The method of claim 15 , comprising the steps: determining the cage coordinate system in the cage tip point coordinate, wherein the cage coordinate system comprises an x-axis, a y-axis and a z-axis, perpendicular to each other, wherein the z-axis is equal to the cage axis; determining at least one projection point, projecting the at least one nearest point into an x-y-plane, defined by the x-axis and the y-axis; determining a distance between the at least one projection point and an at least one planned projection point of a planned axis, wherein the at least one planned axis is a previously acquired axis for the cage; replacing the planned axis with the acquired at least one axis; if the determined distance is smaller than a predetermined threshold; and adding the acquired at least one axis to the previously acquired axis for the cage. 18. The method of claim 17 , wherein replacing the planned axis with the acquired at least one axis comprises: determining a replacement likelihood score for each planned axis; replacing the planned axis with the highest replacement likelihood score with the acquired at least one axis; and wherein the replacement likelihood score is determined using a weighted replacement likelihood function, using a distance of the planned axis to the cage axis and a distance of the planned axis to the acquired axis. 19. The method of claim 1 , wherein determining the at least one axis comprises: acquiring at least one shaft point relating to a shaft end distant to the pointer tip and at least one pointer tip point; and determining the at least one axis by connecting the at least one shaft po