Digital tool and method for planning knee replacement

The invention claimed is: 1. A computer-implemented method of determining a spatial relationship between a marker device and a resection plane associated with an anatomical structure of a patient's body, the marker device being video-detectable by an imaging unit, the imaging unit being fastened in a fixed and known spatial relationship to an adapter, the method comprising executing, by a processor of a computer, steps of: a) acquiring, at the processor, imaging unit position data describing a predetermined spatial relationship between the imaging unit and the resection plane, the predetermined spatial relationship between the imaging unit and the resection plane being a known spatial relationship between the imaging unit and the resection plane established by a mechanical contact between the adapter and the resection plane; b) acquiring, at the processor, marker device position data describing a spatial relationship between the marker device and the imaging unit based on imaging the marker device with the imaging unit in order to generate an orientation-dependent image appearance of the marker device; c) determining, by the processor and based on the imaging unit position data acquired in step a) and the marker device position data acquired in step b) and based on the orientation-dependent image appearance of the marker device, resection plane data describing the spatial relationship between the resection plane and the marker device, the spatial relationship between the resection plane and the marker device being defined as the orientation of the resection plane relative to the marker device. 2. The method according to claim 1 , wherein the predetermined spatial relationship is at least one of position and orientation of the imaging unit relative to the resection plane, wherein the spatial relationship between the marker device and the imaging unit is at least one of the position and orientation of the marker device relative to the imaging unit, and wherein the spatial relationship between the resection plane and the marker device is at least one of the position and orientation of the resection plane relative to the marker device. 3. The method according to claim 1 , further comprising a step of determining, based on the resection plane data, resection height data describing a resection height associated with the position of the resection plane. 4. The method according to claim 1 , wherein the imaging unit is a video camera which is combined with a display unit in a single device, which is disposed in a single housing also comprising a display unit. 5. The method according to claim 1 , wherein the marker device is a planar marker device comprising a plurality of graphical markers. 6. The method according to claim 1 , wherein the marker device has a fixed spatial relationship relative to the resection plane or wherein the marker device does not have a fixed spatial relationship relative to the resection plane. 7. The method according to claim 1 , wherein the resection plane data is determined as soon as the marker device is in the viewing area of the imaging unit. 8. The method according to claim 1 , wherein the anatomical structure is a tibia and wherein resection plane angular data is determined, by the processor, which describes at least one of a varus/valgus angle and a flexion angle of the resection plane, wherein the resection plane angular data is determined, by the processor, based on the resection plane data, and based on the following: data describing the position of the proximal end point of the proximodistal tibia axis; data describing the position of the distal end point of the proximodistal tibia axis; data describing the orientation of the anteroposterior axis of the distal end of the tibia on the body side with which the resection plane is associated. 9. The method according to claim 8 , wherein the data describing the position of the proximal end point of the mechanical, at least one of proximodistal and longitudinal, axis of the tibia is acquired, at the processor, by identifying the position of the proximal end point of the mechanical, at least one of proximodistal and longitudinal, axis of the tibia with a pointer tool having a predetermined, fixed, spatial relationship relative to the imaging unit while imaging the marker device with the imaging unit. 10. The method according to claim 1 , wherein the anatomical structure is a femur and wherein resection plane angular data is determined, by the processor, which describes at least one of a varus/valgus angle and a flexion angle of the resection plane, wherein the resection plane angular data is determined, by the processor based on the resection plane position data, and based on the following: data describing the position of the centre of rotation of the femoral head on the body side with which the resection plane is associated; data describing the position of the distal end point of the proximodistal femur axis; data describing the orientation of the anteroposterior axis of the femur on the body side with which the resection plane is associated. 11. The method according to claim 10 , wherein the data describing the position of the distal end point of the mechanical, at least one of proximodistal and longitudinal, femur axis is acquired, at the processor, by identifying the position of the distal end point of the mechanical, at least one of proximodistal and longitudinal, femur axis with a pointer tool having a predetermined, fixed, spatial relationship relative to the image unit while imaging the marker device with the imaging unit. 12. The method according to claim 1 , wherein the predetermined spatial relationship is defined such that the marker device is in the viewing area of the imaging unit. 13. The method according to claim 1 , wherein the predetermined spatial relationship according to step a) has been established by performing one of the following: placing a planar surface of the adapter flush on a resected portion of the anatomical structure of a patient's body; or inserting the adapter into a cutting block which is attached to the anatomical structure and defines the resection plane. 14. The method according to claim 1 , wherein the marker device has been placed on an ankle of the patient on the body side with which the resection plane is associated. 15. The method according to claim 1 , wherein the marker device has been placed in a fixed position which is not located on the patient's body. 16. The method according to claim 8 , wherein the resection plane angular data is determined based on the orientation of the resection plane relative to the marker device. 17. The method according to claim 10 , wherein the resection plane angular data is determined based on the orientation of the resection plane relative to the marker device. 18. A system for determining a spatial relationship between a medical marker device and a resection plane associated with an anatomical structure of a patient's body, the medical marker device being video-detectable by an imaging unit, the system comprising: an adapter; the imaging unit for imaging the medical marker device fastened in a fixed and known spatial relationship to the adapter; a display unit for displaying an image of the marker device; and a computer configured to execute a program which, when executed by the computer, causes a processor of the computer to perform a computer-implemented method of determining a spatial relationship between a marker device and a resection plane associated with an anatomical structure of a patien