Abstract
Recent findings about UHMWPE oxidation from in vivo stresses lead to the need of a better understanding of which anti-oxidant additivation method is the best option for the use in orthopaedic field. A GUR 1050 crosslinked Vitamin E - blended UHMWPE has been investigated, to provide an accurate outline of its properties.
DSC and FTIR measurements, together with ageing and tensile tests were performed on compression moulded blocks, as well as biocompatibility tests, including implantation on rabbits. Moreover, wear simulations on finished components (Delta acetabular liners) have been completed.
All the test procedures have been repeated for a reference material, a GUR 1050 crosslinked and remelted standard UHMWPE (commercial name UHMWPE X-Lima), and the outcomes have been compared to the crosslinked Vitamin E - blended UHMWPE ones.
On the additivated UHMWPE, we found a ultimate tensile strength of 43 MPa, a yield strength value of 25 MPa, and an elongation to breakage equal to 320%. The degree of cristallinity was 45 ± 2%, and no signal of creation of oxidation products was detected up to 2000 h of permanence in oxidant ambient after the ageing test. The reference material showed comparable mechanical resistance values (∗ = 40 MPa, y = 20 MPa, 350% elongation), a cristallinity of 46 ± 2%, and the creation of oxidation products starting from 700 h in oxidant ambient. The biocompatibility tests indicate that the additivated material is biocompatible, as the reference X-Lima UHMWPE.
Wear tests gave a wear rate of 5,09 mg/million cycles against 6,13 mg/million cycles of the reference material, and no sign of run in wear rate.
Our results indicate that there is no change in mechanical properties in respect to the reference material. This is confirmed by DSC measurements, that show no change in cristallinity. The blend between polymer and additive assures an uniform concentration of Vitamin E across the whole thickness of the moulded block, and ageing test results on additivated UHMWPE have shown that the material possess a superior resistance to degradation phenomena.
Biocompatibility assess that the presence of Vitamin E is not detrimental for the in vivo use of the material, and wear results indicate a better wear resistance of the material, especially in the first stages of the wear process.
From these considerations, it can be concluded that the material, in respect to the standard UHMWPE, is highly resistant to oxidation phenomena, therefore it is expected to have superior in vivo endurance performance.
