Qualification Type: | PhD |
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Location: | Birmingham |
Funding for: | UK Students, EU Students, International Students |
Funding amount: | This project is funded by the MIBTP |
Hours: | Full Time |
Placed On: | 22nd November 2024 |
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Closes: | 16th January 2025 |
Background:
Bacterial biofilms pose a significant challenge in healthcare and industrial settings, where they colonize surfaces such as implants, urinary catheters, food processing equipment, and pipelines. These biofilms are responsible for infections, contamination, clogging, and reduced operational efficiency. As biofilms adversely impact numerous human activities, their prevention and eradication have been the focus of intensive research for decades. Despite advancements, current strategies face limitations in their long-term efficacy against bacterial adhesion. For instance, the use of chemical antimicrobials can lead to the development of multidrug-resistant bacteria, posing severe risks to both human and animal health.
Recent studies indicate that bacteria are sensitive to mechanical stimuli, revealing that vibrations can disrupt their adhesion and biofilm formation. However, existing methods rely on large, external equipment to generate vibrations, which limits their practical application. The project aims to develop a self-sustaining solution by creating novel polymer materials that can harvest ambient acoustic energy—such as noise from hospital or industrial environments—and convert it into localised vibrations. These vibrations will inhibit bacterial attachment without the need for bulky external devices, offering a dynamic and non-chemical strategy to combat biofilm formation.
Objectives:
The goal is to prevent biofilm-related infections in hospitals and contamination in food and industrial processing. Employing a multidisciplinary approach that combines polymerchemistry, materials science, microbiology, and bioengineering, the project seeks to innovate acoustic energy-harvesting materials capable of preventing long-term bacterial adhesion. The materials will be created using polymerisation and self-assembly techniques, engineered to respond to ambient noise frequencies common in relevant settings. Mechanical testing will assess their effectiveness in converting acoustic energy into surface vibrations that disrupt bacterial adhesion. The project will further integrate these polymers with nanostructured surfaces designed to mimic natural antibacterial topographies, enhancing their efficacy against biofilm formation. Key structural and vibrational properties will be evaluated, ensuring efficient energy conversion that influences bacterial behaviour.
This project will open new avenues i) to combat biofouling of medical implants/devices, including urinary catheters that are resistant to colonisation, therefore reducing infections in hospitals; ii) to create antimicrobial surfaces for food processing to prevent spoilage or contamination of food and industrial equipment that resists bacterial attachment, which would increase process efficiency.
The project will be supervised by Professor Paula Mendes (p.m.mendes@bham.ac.uk) and Dr Tim Overton.
Funding:
This project is funded by the MIBTP. For more information, please visit the Birmingham MIBTP page: https://www.birmingham.ac.uk/research/activity/mibtp
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