Biomaterials and Tissue Engineering
Understanding how materials interact with the human body and what we can do to develop new materials to improve quality of life is what drives our research into biomaterials and tissue engineering.
Our biomaterials research is divided into four sub-themes:
Biomaterials
Biomaterials are being developed in response to clinical need. Research includes work on new biomaterials for cell culture and tissue engineering, drug release, transfection, prosthetics and enhanced implant biocompatibility.
Key contacts for biomaterials:
- Professor John Haycock
- Professor Sheila MacNeil
- Professor John Harding
- Professor Ipsita Roy
- Dr Frederik Claeyssens
- Dr Gwen Reilly
- Dr Chris Holland
- Dr Vanessa Hearnden
- Dr Alice Pyne
- Dr Nicola Green
Tissue engineering
Tissue engineering research at Sheffield is working towards a number of targets including skin, nerve, cartilage, bone, cornea, urethra and oral mucosa. These are important for clinical applications, as well as providing proof-of-concept for engineering more complex tissues.
Key contacts for tissue engineering:
- Professor John Haycock
- Professor Sheila MacNeil
- Professor John Harding
- Professor Ipsita Roy
- Dr Frederik Claeyssens
- Dr Gwen Reilly
- Dr Chris Holland
- Dr Vanessa Hearnden
- Dr Nicola Green
Stem cell research
Stem cell research at Sheffield includes directing adult-derived cell properties towards bone, nerve, tendon and cartilage cells and includes bioreactor scale-up approaches for therapeutic applications. Considerable excitement and potential surrounds stem cells as they can be grown and transformed into specialised cells such as muscle, bone or nerve by routine cell culture. It is therefore thought that stem cell therapy might be able to dramatically change how we treat human disease.
Key contacts for stem cell research:
- Professor John Haycock
- Professor Sheila MacNeil
- Professor John Harding
- Dr Frederik Claeyssens
- Dr Gwen Reilly
- Dr Chris Holland
- Dr Vanessa Hearnden
- Dr Nicola Green
Biominerals
Nature produces amazing mineral composites such as bones, teeth and shells and is generally far more specific, efficient, environmental-friendly and cheaper than modern industrial processes. We are using computer simulations to understand the mechanisms used by nature to grow mineral structures and how they modify the properties of materials via molecular additives. Our work also explores molecular-mineral interfaces in organisms, sensors and biofilms.
Key contacts for biominerals: