Bacteria such as Staphylococcus aureus, the ‘superbug’ behind MRSA, can be a major problem for patients who have surgically implanted devices, such as a replacement heart valve, pacemaker or prosthetic  hip implant.

Implanted Devices are Susceptible to Bacterial Biofilm Formation

Bacteria are able to form protective colonies, called biofilm, on surgically implanted pacemakers, which can lead to wider infections such as endocarditis, an aggressive, bacterial infection of the heart.

Research performed by scientists at the Department of Biology, at the University of York, has shed new light on how these biofilm colonies are formed. Biofilm helps the bacteria within to avoid attack from the immune system and antibiotics.

Often the only way to tackle the resulting infection is to remove the affected device, which can be a difficult and invasive process.

The team from the University of York, led by Professor Jennifer Potts, included British Heart Foundation-funded Ph.D. student Dominika Gruszka. They found that the bacteria release long, thin protein chains to connect with other bacteria or mesh with other bacterial products. The chains have a highly unusual repetitive structure which could not have been predicted and provides important clues to how they might work.

A similar protein is found on the surface of Staphylococcus epidermidis, another bacterium commonly found in device infections.

Professor Jennifer Potts, a BHF Senior Research Fellow, said: “This discovery provides an important step forward in understanding how biofilms form. It should help in the development of new ways of preventing infection of cardiac devices by these bacteria.”

Dr. Hélène Wilson, Research Advisor at the British Heart Foundation, which co-funded the study, said: “These clusters of bacteria on implanted devices can be a problem for heart patients because they are very difficult to treat with antibiotics. Often the only way to tackle the infection is to remove the affected device, which can be a difficult and invasive process and lead to further complications.”

“This discovery is an important step towards improving our understanding of how these biofilms are structured, which could help lead to new treatments or new ways to prevent them forming.”

Source: University of York