The performance of total knee arthroplasty in deeply flexed postures is of increasing concern as the procedure is performed on younger, more physically active and more culturally diverse populations. Several implant design factors, including tibiofemoral conformity, tibial slope and posterior condylar geometry have been shown directly to affect deep flexion performance.

The goal of this study was to evaluate the performance of a fixed-bearing, asymmetric, medial rotation arthroplasty design during kneeling activities.

Thirteen study participants (15 knees) with primary total knee arthroplasty (Medial Rotation Knee, Finsbury, Surrey, UK) were observed while doing a step activity and kneeling on a padded bench from 90° to maximum comfortable flexion using lateral fluoroscopy. Subjects averaged 74 years of age and nine were female. Subjects were an average of 17 months post-operative, and scored 94 points on the International Knee Score and 99 on the Functional Score. Digitised fluoroscopic images were corrected for geometric distortion and 3D models of the implant components were registered to determine the 3D position and orientation of the implants in each image.

During the step activity, the medial and the lateral femoral contact point stayed fairly constant with no axial rotation from 0 to 100° of flexion. At maximum kneeling flexion, the knees exhibited 119° of implant flexion (101°-139°), 7° (-7° to 17°) tibial internal rotation, and the lateral condyle translated backwards by 11 mm.

Patients with medial rotation knee arthroplasty exhibited medial pivot action with no paradoxical translation. The knees exhibited excellent kneeling flexion and posterior translation of the femur with respect to the tibia. The axial rotation in MRK was within the range of normal knee kinematics from -10 to 120 (perhaps 140).

Kinematics of human joints have been studied using various methods of observation for millennia, including cadaver dissection, mechanical tests, and more recently photogrammetric gait analysis. For just over sixteen years, dynamic single-plane radiographic observations have been used to quantitatively characterize the motions of anatomic and prosthetically replaced joints. These observations have improved the understanding, in particular, of knee function and the influence of prosthetic design and surgical technique on knee kinematics and patient function. Other studies have reported the kinematics of the hip, shoulder, spine and foot/ankle. It is clear that advances in the technologies to acquire and quantify radiographic images of the skeleton in motion can have a major impact on joint mechanics research and, ultimately, clinical diagnosis. This lecture will highlight two avenues of development in our laboratory: open-source software for determining skeletal kinematics from radiographic images, and a novel robotic imaging platform for observing the skeleton in motion.

Our group is working on an open-source shape-matching software application that will be freely available to anyone who wishes to use it (sourceforge.net/projects/jointtrack). This flexible platform will allow the modular addition of new capabilities as plug-in components written in a wide range of languages (C++, Python, Java, etc.), and makes heavy use of other open-source and public libraries (I.C.E., OpenGL, VTK, ITK). All of our future developments will use this platform so that the latest results will be available to all, and hopefully other users will share their advances collaboratively. We currently have created a graphical user interface for performing single-plane model-image registration, and are currently working to expand this to handle bi-plane imaging.

We also are developing a robotic platform to permit radiographic imaging of human joints during normal, unrestricted, dynamic activities. This platform will move the x-ray source and sensor in response to the patient’s unconstrained motion, providing views with greater diagnostic potential than are acquired with fixed or c-arm imaging systems. This same imaging platform will also provide an extremely flexible platform for cone-beam tomography, so that a single system will be able to perform all imaging functions required for skeletal model-image registration based kinematic measurements.

The goal of these endeavors is to advance the possibility that dynamic radiographic analysis of joint motion will soon be a useful, accurate, and routine diagnostic and measurement tool available to enhance the efforts of orthopaedic surgeons in the treatment of their patients.