Vinay Medhekar scite author profile

ABSTRACT:Understanding the sequence of reactions that occur in ultra-high-molecular-weight polyethylene (UHMWPE) following 60 Co ␥ irradiation has been the focus of numerous experimental studies. In the study reported here, we have incorporated recent experimental findings into a mathematical model for UHMWPE oxidation. Simulation results for shelf aging and accelerated aging are presented. It is shown that very reasonable simulations of shelfaging and accelerated-aging data can be obtained. It is also shown that simulations of shelf aging in reduced oxygen environments predict that the subsurface peaks of ketones will be shifted to the exterior surface. In vivo aging can be simulated if we assume that the oxygen level in the synovial fluid is about one-eighth that of atmospheric levels. Some reduced irradiation doses are predicted to significantly reduce the ketone formation for shelf-aging periods of up to 10 years.

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Modeling shelf and accelerated aging of ultra-high molecular weight polyethylene in air

Medhekar¹,

Thompson²,

Wang³

et al.

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Vinay Medhekar

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Modeling shelf and accelerated aging of ultra-high molecular weight polyethylene in air

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