Key to this game-changing new approach is the addition of a layer of modified biomaterials known as biomimetic macromolecules to the surface of each dressing. This layer is designed to replicate the patient’s natural tissue structures, kick-starting the body’s healing processes and encouraging new skin and blood cells to form in the wound area.
Based at the Ïã¸ÛÁùºÏ²Ê×ÊÁÏ’s world-renowned Centre for Regenerative Medicine and Devices (CRMD), the project team brings together a dozen experts from a range of fields including immunology, podiatry, biochemistry and fluid dynamics.
Leading the team is , Professor of Tissue Regeneration at the Ïã¸ÛÁùºÏ²Ê×ÊÁÏ and director of the CRMD, who has spent more than thirty years carrying our research into the development of new types of biomaterials to aid healing and the monitoring of disease.
Professor Santin said: “Every year, millions of people around the world suffer pain, discomfort and reduced quality of life from chronic wounds which heal too slowly or not at all. The result is not just human suffering, but also a huge financial cost to health services worldwide, including our own NHS.
“Building on almost three decades of pioneering research in a range of fields, our team aims to transform the way severe wounds are treated. Using pioneering techniques developed here at Ïã¸ÛÁùºÏ²Ê×ÊÁÏ, we will create an entirely new generation of wound dressings that speed up the healing process and give doctors confidence that their patients are on track for a successful recovery.”
The project – ‘A biomimetic macromolecular platform for tissue healing and diagnostics at medical device interfaces: a personalised wound dressing model’ – is funded by the Engineering and Physical Sciences Research Council (part of ) through a £2.88m grant, which makes it the largest single research grant ever awarded to the Ïã¸ÛÁùºÏ²Ê×ÊÁÏ.
As well as creating new biomimetic macromolecules which improve on existing biomaterials, the project also promises to transform healthcare approaches in areas beyond wound treatment. These include better understanding of molecular interactions within organs, and creating synthetic antibodies or novel molecular probes which can be used for new diagnostics in the treatment and diagnosis of a range of diseases.