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Next generation antibacterial Ti implants

Completed

The development of next generation antibacterial Ti implants with integrated chemical and topographical modifications

Bone implant failure is mainly caused by infection due to bacterial infiltration and biofilm formation, in addition to aseptic loosening. The current practice to treat implant infection is revision surgeries plus antibiotics. The process is long, painful and costly. More seriously, most bacteria causing such infections have become antibiotics resistant. There is an urgent need to develop new implants with antibacterial functions that are independent of antibiotics to treat possible implant infection while securing long-term implant fixation.

There are two major approaches in developing new antibacterial biomaterials. One is to functionalise existing materials with chemical antibacterial agents. The other is to generate surface nanotopographies by mimicking the naturally functional surfaces of insects and other organs. The related studies constitute one of the hottest topics of the current biomaterials research. Both approaches have shown effective antibacterial capabilities but limitations at the same time.

This proposed collaboration between Ã÷ÐÇ°ËØÔ, UK (Ã÷ÐÇ°ËØÔ) and the Institute of Metal Research, the Chinese Sciences Academy, China (IMR) sees opportunities to explore the benefits of integrating chemical and topographical modifications in the development of new generation orthopaedic and dental implants. The project will focus on the combined chemical and topographical antibacterial behaviour, aiming to develop novel titanium implants with maximized antibacterial functions. The research will include material fabrication, surface modification, biophysical characterization and bactericidal mechanism observations, etc.

The research addresses the most urgent and core problems of orthopaedic and dental implants and will have a strong impact on the development of new generation biomaterials.

The project demonstrates the effect of integrated chemical and topographical modification on the antibacterial performance for titanium implants. The UK research will benefit directly from the scientific deliverables from the project, which include the principles of antibacterial biomaterial design, fabrication technology, and the detailed knowledge of surface nanotopography control, antibacterial performance and bactericidal mechanisms for the targeted Ti-Cu implants. These deliverables represent critical advances in the development of new generation titanium implants and will inspire other UK researchers for further scientific and technical progress in this and a wider field of biomaterials research. Ultimately, the research will lead to effective solutions to solve the problems of orthopaedic and dental implant infection, improving the quality of UK health care.

The research will particularly strengthen UK’s leading position in the research of solidification processing for light alloys, by applying the advanced high shear melt treatment technology to the casting of high quality biomedical Ti-Cu alloys.

Working with Chinese scientists, the UK research not only gains from cutting edge innovation but also remains engaged in the rising R&D power of China, which will facilitate the commercial exploitation of UK research outcomes and benefit future UK research.

This collaboration will strengthen the current research in biomaterials and also broadens the research area for both Ã÷ÐÇ°ËØÔ and IMR. The project promotes a set of skills across boundaries of conventional disciplines by the application of novel solidification and surface modification processesand various advanced techniques for microstructural, topographical and biophysical characterization. All participants will benefit from sharing general expertise and special know-hows between the two sides.


Meet the Principal Investigator(s) for the project

Dr Yan Huang
Dr Yan Huang - Dr Huang leads metallic biomaterials research at Ã÷ÐÇ°ËØÔ, working on both traditional permanent titanium implants and novel biodegradable magnesium medical devices for orthopaedic cardiovascular applications. He recently won three research grants in biomaterials research from the Royal society, EPSRC and European Commission (EC). Dr Huang is a founding member and co-investigator of the EPSRC Future Liquid Metal Engineering (LiME) HUB where he leads the activities on process development and light alloy processing involving both solidification and plastic deformation. He has extensive experience in process innovation for combined solidification and thermomechanical processing (semisolid forming, twin roll casting, and integrated cast-forming), solid state joining, severe plastic deformation for light alloys and light metal matrix composites. He has long term interests in the characterization of microstructure and texture evolution during thermomechanical processing and fundamental issues of strengthening, plastic deformation and grain boundary migration. Teaching: 1)ME3608 Propulsion Systems, Aircraft Structures and Materials, Airworthiness and Stability and Control; 2) ME5537/ME5307 Advanced racing vehicle dynamics IC engines, materials and manufacturing; 3) MACE research method workshops for post graduate students; 4) BCAST training courses.

Related Research Group(s)

metallurgical process of melting metals

Ã÷ÐÇ°ËØÔ Centre for Advanced Solidification Technology (BCAST) - BCAST is an academic research centre focusing on both fundamental and applied research on solidification of metallic materials.


Partnering with confidence

Organisations interested in our research can partner with us with confidence backed by an external and independent benchmark: The Knowledge Exchange Framework. Read more.


Project last modified 14/11/2023