The discussion will focus on new approaches to reduce bacterial adhesion on the surface of polymethylmethacrylate (PMMA) in contact with bone, comparing the clinical and engineering point of view. One possibility is to encourage and speed up direct interaction with the bone, for example by adding a bioactive phase in the cement (hydroxyapatite, glass and bioactive glass ceramic). A widespread strategy is also the addition of different types of antibiotics (gentamicin, tobramycin vancomycin, etc.), although they are known to have some drawbacks: not complete release, resistant strain development. Another strategy could be represented by the PMMA-based composite cements loaded with a completely inorganic filler consisting of a bioactive glass doped with ions whose bioactivity mechanism is well-known and encompasses a chemical and biological interaction with tissues promoting osteoinduction. Bioactive glasses can be doped with antibacterial ions (silver, copper, etc.) preserving their biocompatibility and bioactivity and, at the same time, acquiring antibacterial properties. Thus, it is possible to produce composite cements that combine the properties of the polymer matrix with those of the inorganic filler, overcoming the main problems associated with the use of antibiotics. An additional possibility is the addition of essential oils, vegetable oils with remarkable antibacterial properties.

Summary

Prosthetic UHMWPE added with vitamin E and crosslinked UHMWPE are able to decrease significantly the adhesion of various bacterial and fungal strains limiting biomaterial associated infection and consequent implant failure.