Fig 1.
3D Slicer view of the programmed plug-in.
Fig 2.
One reference point along the capital bearing area of the femoral head of the left femur of a dog to calculate the center of the femoral head.
Fig 3.
The femoral neck base center of the left femur of a dog manually placed in the center of the proximal femoral metaphysis, at the level of the highest medial protrusion of the lesser trochanter.
Fig 4.
The most caudodistal midpoint on the convex surface of the lateral condyle of the right femur of a dog.
Fig 5.
The most caudal point of the lateral condyle of the left tibia of a dog.
Fig 6.
The most cranial point on the lateral part of the cochlea tibiae of the left tibia of a dog.
Fig 7.
The lateral lowest midpoint of the cochlear-tibial groove of the left tibia of a dog.
Fig 8.
The lateral lowest midpoint of the condylar-tibial groove of the right tibia of a dog.
Fig 9.
The most cranial point on the lateral part of the articular surface of the trochlea of the talus of the left tibia of a dog.
Fig 10.
Comparison of the VoXim® method with the 3D Slicer method using a modified Bland-Altmann-Diagram for the antetorsion angle measurement.
Fig 11.
Comparison of the VoXim® method with the 3D Slicer method using a modified Bland-Altmann-Diagram for the femorotiabal rotation angle.
Fig 12.
Comparison of the VoXim® method with the 3D Slicer method using a modified Bland-Altmann-Diagram for the femoral varus/vagus angle.
Fig 13.
Comparison of the VoXim® method with the 3D Slicer method using a modified Bland-Altmann-Diagram for the tibial torsion angle.
Fig 14.
Comparison of the VoXim® method with the 3D Slicer method using a modified Bland-Altmann-Diagram for the varus/valgus angle of the tibia.
Fig 15.
Comparison of the VoXim® method with the 3D Slicer method using a modified Bland-Altmann-Diagram for the tibiotalar rotation angle.
Table 1.
Circular mean and circular standard deviation of the difference between the VoXim® method with the 3D Slicer method for each angle in degrees.