Biphasic calcium phosphates (BCP) are the most frequently used materials because of their mineral analogy with bio-mineral part of bones. Their chemical synthesis can be modulated by doping, in order to respond to the biological needs. We present here the biological responses induced by copper ions in solution, to characterize its cytotoxicity and antibacterial activity. We also investigate the antibacterial property of Cu-doped BCP (Ca10 Cu0.1 (PO4)6 (OH)1.8 O0.2) on a strain of clinical interest: S. aureus, compared to undoped BCP. The sol-gel route has been used to prepare the BCP ceramics. Human BMC (Bone Marrow Cells) were obtained from metaphysal cancellous bone collected during hip arthroplasty and used for cytotoxicity evaluations. A strain of Staphylococcus aureus isolated from an osteoarticular infection after total knee arthroplasty was used to evaluate antibacterial activities. Results indicate that 3 ppm of copper ions leads to the death of all cultured bacteria in 24 hours and 25 ppm caused the death of all cells in 15 days. Regarding BCP, the undoped bioceramics increased the bacterial growth compared to a control without bioceramic. After 16 hours of contact, the copper ions released by the Cu-doped BCP induced a significant decrease of the bacterial concentration, indeed no viable bacteria were found. These materials seem to be a promising alternative for the preparation of multifunctional bone substitutes.

Background

Medical applications of nanotechnology are promising because it allows the surface of biomaterial to be tailored to optimise the interfacial interaction between the biomaterial and its biological environment. Such interfaces are of interest in the domain of orthopaedic surgery as they could have anti-bacterial functions or could be used as drug delivery systems. The development of orthopaedics is moving towards better integration of biology in implants and surgical techniques, but the mechanical properties of implanted materials are still important for orthopaedic applications. During clinical implantation, implants are subjected to large mechanical stresses. In order to obtain the best performance during clinical use, mechanical properties of implants need to be investigated and understood.

Background

External fixation is a method of osteosynthesis currently required in traumatology and orthopaedic surgery. Pin tract infection is a common problem in clinical practice. Infection occurs after a bacterial colonisation of the pin due to its contact with skin and local environment. To prevent such local contamination, one way to handle this issue is to create a specific coating using method which could be applied in the medical field. In this work we develop a surface coating for external fixator pins based on photocatalytic TiOα properties, producing a bactericidal effect with sufficient mechanical strength to be compatible with surgical use.