News
SEMS scientists discover teeth protein promises bone regeneration
8 July 2014
Patients suffering from osteoporosis or bone fractures might benefit from a new discovery of a protein that plays an important role in bone regeneration made by bioengineers at Queen Mary University of London.
Normally found in the formation of enamel, which is an important component of teeth, the scientists discovered that a partial segment of the protein statherin can be used to signal bone growth.
“What is surprising and encouraging about this research is that we can now use this particular molecule to signal cells and enhance bone growth within the body,” said co-author Dr Alvaro Mata from QMUL’s School of Engineering and Materials Science and the Institute of Bioengineering.
Publishing in the journal Biomaterials, the team created bioactive membranes made from segments of different proteins to show which protein in particular played the crucial role. They demonstrated the bone stimulating effect in a rat model, and used analytical techniques to visualise and measure the newly formed calcified tissue.
Co-author Dr Esther Tejeda-Montes also at QMUL’s School of Engineering and Materials Science said: “The benefit of creating a membrane of proteins using these molecules means it can be both bioactive and easily handled to apply over injured areas in the bone.”
Dr Mata added: “Our work enables the possibility to create robust synthetic bone grafts that can be tuned to stimulate the natural regenerative process, which is limited in most synthetic bone graft alternatives.”
The work was funded by the European Research Council and the Spanish Government.
Written by Neha Okhandiar, Public Relations Manager.
Normally found in the formation of enamel, which is an important component of teeth, the scientists discovered that a partial segment of the protein statherin can be used to signal bone growth.
“What is surprising and encouraging about this research is that we can now use this particular molecule to signal cells and enhance bone growth within the body,” said co-author Dr Alvaro Mata from QMUL’s School of Engineering and Materials Science and the Institute of Bioengineering.
Publishing in the journal Biomaterials, the team created bioactive membranes made from segments of different proteins to show which protein in particular played the crucial role. They demonstrated the bone stimulating effect in a rat model, and used analytical techniques to visualise and measure the newly formed calcified tissue.
Co-author Dr Esther Tejeda-Montes also at QMUL’s School of Engineering and Materials Science said: “The benefit of creating a membrane of proteins using these molecules means it can be both bioactive and easily handled to apply over injured areas in the bone.”
Dr Mata added: “Our work enables the possibility to create robust synthetic bone grafts that can be tuned to stimulate the natural regenerative process, which is limited in most synthetic bone graft alternatives.”
The work was funded by the European Research Council and the Spanish Government.
Written by Neha Okhandiar, Public Relations Manager.
Contact: | Dr Alvaro Mata |
Email: | a.mata@qmul.ac.uk |
Updated by: Corinne Hanlon