Statement of purpose

To analyse the distribution of osteoarthritis of the knee, to determine what proportion of patients may be suitable for a partial knee replacement and finally to assess the risk of wear progression.

Reconstructive knee arthroplasty in patients with limb deformity can be a daunting and complex task. These patients are often younger and so post traumatic osteoarthritis poses a real challenge. In view of their relative youth, bone preservation would be favourable; however accurate implantation of components is essential. Formulation of a well calculated plan and accurate execution is essential for successful surgery.

We report on a novel method which combines 3D CT joint analysis and computer navigation to define the deformity present pre-operatively and determine whether the proposed reconstruction is feasible. If the reconstructive surgery is feasible, an accurate calculation the correction required is performed. The planned surgery is executed using computer aided navigation surgery.

Eight patients have benefited from the technique. Four patients presented with isolated medial compartment osteoarthritis and intact anterior cruciate ligament. These patients underwent 3D CT joint analysis and computer assisted navigation surgery to accurately implant unicondylar knee replacements.

Four Patients presented with two or three compartment disease. These patients underwent similar 3D CT analysis and navigated Total Knee Replacement.

The series demonstrates the merits of 3D CT joint analysis to accurately define deformity and therefore determine pre-operatively feasibility of corrective surgery proposed. The technique is then complimented by computer assisted navigation surgery to ensure the proposed surgical plan is accurately executed.

It is believed by some that knee radiographs may underestimate the extent of osteoarthritis. Often severe changes are noted at arthroscopic assessment despite the observation of preserved joint spaces on plain radiographs. This has important implications regarding the indications for different types of partial joint replacement if damage is underestimated.

Aims:

To determine the correlation if any between radiographic findings and arthroscopic findings.

Methods and patient selection: The pre-operative radiographs and intra-operative articular surface mappings were collected for 100 consecutive patients undergoing prospectively audited outcome of arthroscopic debridement. All the patients examined were aged 40 and above with knee pain. The intra-operative findings and any work done (debridement of meniscal tears or cartilage flap tears) were also recorded on zoned articular maps and meniscal diagrams. The pre-operative radiographs (AP standing, lateral, Rosenberg and skyline views) were examined and graded using the Kellgren and Lawrence grading system.

Results: Correlations made between arthroscopic findings and AP standing views yielded a sensitivity of 72% and specificity of 64%. The positive predictive value was 91% and negative predictive value was 32%. Rosenberg views were better at predicting the presence of osteoarthritis (sensitivity 76%, specificity 88%, positive predictive value 97%, negative predictive value 44%). Skyline views were found to particularly unreliable in assessment of patello-femoral damage. Analysis of the actual patterns of articular damage found at arthroscopy did show that it is possible to identify cohorts of patients who may in future be suitable for different types of partial replacement.

Conclusions: Radiographs and in particular skyline views are limited in terms of sensitivity and specificity in the prediction of osteoarthritis. Rosenberg views offer better prediction of osteoarthritis compared with weight bearing AP radiographs. Arthroscopy carried out in any event for clinical indications appears to offer useful additional information regarding indications for future surgery.