Abstract
Since its introduction in total hip replacements in the 1960's, Ultra High Molecular Weight Polyethylene (UHMWPE) has played a major role as a bearing component material for joint arthroplasty. Concerns were raised when issues of wear resistance became apparent, and therefore Highly Crosslinked Polyethylenes were introduced. Such materials undergo a thermal treatment to quench the free radicals and reduce progressive oxidation.
However, said thermal treatment weakens the material mechanical properties and hence the use of antioxidants has been proposed and implemented in clinical use, mainly Vitamin-E. This can be added to the material before or after irradiation. If it is done before, part of the anti-oxydant is consumed during irradiation and so will not be available for its main purpose, and part reacts before irradiation with the free radicals thus reducing the crosslinking effect. If it is added after irradiation, high temperatures are required in order to diffuse it in the bulk material, and anyway the surface will be mainly rich in antioxidant. However, Vitamin-E tends to neutralize the free radicals on the oxidized lipid chain present in our body fluids and so in direct contact with the prosthetic components: such mechanism reduces the Vitamin-E quantity available for anti-oxidation purposes in the long run.
A UHMWPE doped with Hindered Amine Light Stabilizer (HALS) has been developed and tested for applications in large joint replacements where highest resistance to wear and tough mechanical properties are simultaneously required, such as tibial inserts for knee joints or acetabular inserts for large diameter heads.
Mechanical and biocompatibility tests were run in accordance with ASTM F 2565-06 and ISO 10993-1 with successful results and good reproducibility.
In particular, electro spin resonance exhibited a very high level of free radicals in the three samples, which confirms the properties of this new material. Free radicals are the result of the activation of the HALS molecules during irradiation, creating nitroxide radicals that will destroy the residual alkyl radicals responsible for the oxidation before and after implantation.
Biocompatibility tests proved absence of cytotoxicity, sensitization, irritation, genotoxicity or pyrogenic reactions.
The possible future applications for this new material in the arthroplasty field will be discussed along with the expected advances and advantages.
