Abstract
Rationale and Objectives. To reduce tibio-femoral misalignment, the polyethylene bearing-component of a new knee prosthesis was allowed limited motion on the underlying metallic component. The object of the work presented here was to develop a suitable radiographic technique for quantifying the in-vivo position of the bearing. By collecting these data at discrete flexion angles, the functional operation of the prosthesis could be determined
Methods. The known geometries between landmarks on the two components were used to produce algorithms for reconstructing their spatial positions from a single radiograph. A custom-designed computer program utilized these algorithms to determine the relative translation and rotation of the polyethylene component
Results. This technique produced typical errors of 0.54 mm translation and 0.56° rotation between the polyethylene component and the underlying metallic component
Conclusions. A practical method has been developed for assessing mobile-bearing motion, in vivo. This method can be applied to other prosthetic devices, or combinations of components, once the requirement for identifiable landmarks has been addressedClinical Relevance. Skeletal and soft-tissue changes in the pathological knee may produce abnormal rotations and translations in the transverse tibial plane. This technique is intended both to validate the design philosophy of a mobile-bearing prosthesis and to provide additional data on any pathological motions, which will have implications for future prosthetic designs.