Phase Stability of Zirconia and Alumina/Zirconia Composite Heads against UHMWPE Liners in a Temperature-Controlled Hip Simulation Study

Yen Shuo Liao; Mark Hanes; J.Craig Fryman; Mark DiSilvestro

doi:10.4028/www.scientific.net/KEM.284-286.991

Paper Titles

Safety Issues in the Use of THR Ceramic Heads and Cups
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Alumina Matrix Composites in Arthroplasty
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ATZ – A New Material with a High Potential in Joint Replacement
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Bone-Bonding Ability of Ce-TZP/Al₂O₃ Nanocomposite with a Microporous Surface and Calcium Phosphate Coating
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Phase Stability of Zirconia and Alumina/Zirconia Composite Heads against UHMWPE Liners in a Temperature-Controlled Hip Simulation Study
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Third-Body-Wear as a Risk Factor in Joint Endoprosthetics
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Investigation of Monoclinic Content on Clinically Retrieved Zirconia Heads
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Ceramic-On-Ceramic Implants in Total Hip Arthroplasty
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Subcritical Crack Growth Resistance of Low Temperature Degradation-Free Zirconia/Alumina Composites for Medical Applications
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HomeKey Engineering MaterialsKey Engineering Materials Vols. 284-286Phase Stability of Zirconia and Alumina/Zirconia...

Phase Stability of Zirconia and Alumina/Zirconia Composite Heads against UHMWPE Liners in a Temperature-Controlled Hip Simulation Study

Abstract:

This study evaluated the wear performance of cobalt-chromium, zirconia and alumina/zirconia composite heads against moderately crosslinked ultra-high-molecular-weight polyethylene liners under different temperature conditions. A temperature control unit was utilized to allow direct cooling/heating the head components at 4, 20, 37 and 45 °C in addition to the conventional no temperature control method. Results showed that the polyethylene wear was affected by the coolant temperature. The CoCrMo and the alumina/zirconia groups had similar wear rate without temperature control, however, the CoCrMo group generated 50% more wear than the alumina/zirconia group did when the coolant temperatures were above 20 °C. The zirconia group had the lowest wear rate of the three groups in all temperature conditions. The monoclinic phase content of the zirconia heads were about 0.2 M% before the test and 6.0 M% after the test, while the X-ray diffraction remained similar before and after the test in alumina/zirconia composite heads. The current study was able to reproduce the phase transformation of zirconia ceramics as reported in some clinical retrieval reports. A temperature control feature is recommended in a wear study in order to better simulate implant wear performance under the physiological condition in human body.