• Title of article

    Tradeoffs amongst fatigue, wear, and oxidation resistance of cross-linked ultra-high molecular weight polyethylene

  • Author/Authors

    Atwood، نويسنده , , Sara A. and Van Citters، نويسنده , , Douglas W. and Patten، نويسنده , , Eli W. and Furmanski، نويسنده , , Jevan and Ries، نويسنده , , Michael D. and Pruitt، نويسنده , , Lisa A.، نويسنده ,

  • Issue Information
    ماهنامه با شماره پیاپی سال 2011
  • Pages
    13
  • From page
    1033
  • To page
    1045
  • Abstract
    This study evaluated the tradeoffs amongst fatigue crack propagation resistance, wear resistance, and oxidative stability in a wide variety of clinically-relevant cross-linked ultra-high molecular weight polyethylene. Highly cross-linked re-melted materials showed good oxidation and wear performance, but diminished fatigue crack propagation resistance. Highly cross-linked annealed materials showed good wear and fatigue performance, but poor oxidation resistance. Moderately cross-linked re-melted materials showed good oxidation resistance, but moderate wear and fatigue resistance. Increasing radiation dose increased wear resistance but decreased fatigue crack propagation resistance. Annealing reduced fatigue resistance less than re-melting, but left materials susceptible to oxidation. This appears to occur because annealing below the melting temperature after cross-linking increased the volume fraction and size of lamellae, but failed to neutralize all free radicals. Alternately, re-melting after cross-linking appeared to eliminate free radicals, but, restricted by the network of cross-links, the re-formed lamellae were fewer and smaller in size which resulted in poor fatigue crack propagation resistance. This is the first study to simultaneously evaluate fatigue crack propagation, wear, oxidation, and microstructure in a wide variety of clinically-relevant ultra-high. The tradeoff we have shown in fatigue, wear, and oxidation performance is critical to the material’s long-term success in total joint replacements.
  • Keywords
    WEAR , Oxidation , Polyethylene (UHMWPE) , microstructure , Fatigue
  • Journal title
    Journal of the Mechanical Behavior of Biomedical Materials
  • Serial Year
    2011
  • Journal title
    Journal of the Mechanical Behavior of Biomedical Materials
  • Record number

    1404845