Magnitude of Cement-Device Interfacial Stresses with and without Tibial Stemming: Impact of BMI

 

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ABSTRACT

Patients expect their total knee arthroplasty to relieve pain and to be long lasting. With patients becoming more active, weighing more, and living longer, this expectation becomes increasingly more difficult to fulfill. Patients who are obese and active put greater loads on their implants and may have a greater risk of failure. Although much attention has been paid to decreasing polyethylene wear, a major cause of implant failure, very little research focus has been directed to elucidate other measures to reduce failure, such as the efficacy of prophylactic stemming of the tibial tray. This study explored whether additional mechanical support for tibial base plates would help reduce bone cement stresses in heavy patients, who, like patients with a high activity level, put added stress on their implants. A tibial base plate with a 12-mm-diameter × 50-mm-long stem was compared with the same tibial base plate with a 15-mm-diameter × 20-mm-long end cap using finite element analysis. The results indicate that the tibial base plate with a prophylactic stem significantly reduced compressive and shear stresses on the cement-device interface and therefore may help to reduce the possibility of tibial loosening in these at-risk patients. Further, such studies will aid the surgeon in educating patients and in selecting the appropriate implant strategy.

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Ananthkrishnan GopalakrishnanM.S. 

Stryker Orthopaedics, 325 Corporate Drive

Mahwah, NJ 07073

Email: Ananthkrishnan.Gopalakrishnan@stryker.com