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Clinical Orthopaedics and Related Research®
Published in: Clinical Orthopaedics and Related Research® 11/2012

01-11-2012 | Clinical Research

Is Femoral Component Rotation in a TKA Reliably Guided by the Functional Flexion Axis?

Authors: Sam Oussedik, FRCS, Corey Scholes, PhD, Duncan Ferguson, FRCS, Justin Roe, FRACS, David Parker, FRACS

Published in: Clinical Orthopaedics and Related Research® | Issue 11/2012

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Abstract

Background

The position of the femoral component in a TKA in the axial plane influences patellar tracking and flexion gap symmetry. Errors in femoral component rotation have been implicated in the need for early revision surgery. Methods of guiding femoral component rotation at the time of implantation typically are derived from the mean position of the flexion-extension axis across experimental subjects. The functional flexion axis (FFA) of the knee is kinematically derived and therefore a patient-specific reference axis that can be determined intraoperatively by a computer navigation system as an alternative method of guiding femoral component rotation. However, it is unclear whether the FFA is reliable and how it compares with traditional methods.

Question/purposes

We asked if the FFA could be measured reproducibly at different stages of the operative procedure; (2) where it lies in relation to a CT-derived gold standard; and (3) how it compares with more traditional methods of judging femoral component rotation.

Methods

Thirty-seven patients undergoing elective TKAs were recruited to the study. Preoperative CT scans were obtained and the transepicondylar axis (TEA) was identified. The TKA then was performed using computer navigation. The FFA was derived before incision and again after the surgical approach and osseous registration. The navigation system was used to register the surgical TEA. The FFA and surgical TEA then were compared with the CT-derived TEA.

Results

The mean preincision FFA was similar to the intraoperative FFA and therefore deemed reproducible. We observed no differences in variability between surgical TEA and preincision FFA. The FFA was different from the CT-TEA and judged similar in accuracy to the surgical TEA.

Conclusion

The reliability and accuracy of the FFA were similar to those of other intraoperative methods. Further evaluation is required to ascertain whether the FFA improves on currently available methods for determining the ideal rotation of the femoral component during TKA.
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Metadata
Title
Is Femoral Component Rotation in a TKA Reliably Guided by the Functional Flexion Axis?
Authors
Sam Oussedik, FRCS
Corey Scholes, PhD
Duncan Ferguson, FRCS
Justin Roe, FRACS
David Parker, FRACS
Publication date
01-11-2012
Publisher
Springer-Verlag
Published in
Clinical Orthopaedics and Related Research® / Issue 11/2012
Print ISSN: 0009-921X
Electronic ISSN: 1528-1132
DOI
https://doi.org/10.1007/s11999-012-2515-0

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