Skip to Content
 
University of Limerick, Ireland

 

Students & Staff   Study at UL  |  Research  |  Faculties  |  A - Z Directory  |  Finding Staff

You are here:  Home
 

University of Limerick Led Team Develops Hospital Textiles to kill MRSA Superbug


Bioelectricsurface

A European Research Team co-ordinated by leading Irish Research Institute, MSSI at the University of Limerick have recently (18th March) announced the development of textiles which will kill the MRSA (Methicillin Resistant Staphylococcus Aureus) superbug. The BioElectricSurface Research Team has used nanomaterials on textiles used in hospital drapes, bed linens and upholstery. Nanomaterials, which are a thousand times smaller than a human hair, are known to possess extra-ordinary properties that the team has harnessed to develop this technology to fight MRSA.

The MRSA bug is one of the major causes of hospital-acquired infections. In June 2007, the European Centre for Disease Prevention (ECDC) identified anti-biotic resistant micro-organisms as the most important infectious disease threat in Europe. One in 10 patients entering a European hospital can expect to catch an infection caused by drug-resistant microbes. Every year, around 3 million people in the EU catch a healthcare-associated infection, resulting in approximately 50,000 deaths.

Within the BioElectricSurface project, scientists and engineers from the University of Limerick, Ireland, Wroclaw University of Technology, Poland, Wroclaw Medical University, Poland and Comenius University, Slovakia have been working on developing this technology since 2008. They have embedded both commercial and custom-made nanoparticles into textiles through a patent-pending process that is effective against MRSA and other superbugs. The patent pending process ensures the nanoparticles adhere tightly to the textile which is an essential feature in commercialisation as it minimises "free" or "loose" nanoparticles.

Coordinator of this research, Dr. Syed Tofail of the Materials and Surface Science Institute, University of Limerick, expressed his excitement in the development of this new method as the social impact and commercial potential for such technology are very high. The US and European market size for medical textiles was estimated to be over billion and current sales only meet one third of the market potential. 'Our technology will be used to produce practical, economical and effective products for this huge potential market,' he adds.

According to Professor Noel O'Dowd, Director of the Materials and Surface Science Institute, "This is an excellent example of translational research where fundamental studies have been successfully transformed into a practical application. The use of MSSI's state-of-the-art facilities and equipment has been pivotal to such successes".

Dr. Ewa Dworniczek, a microbiologist from the Wroclaw Medical University, Poland and a member of the BioElectricSurface team, notes 'most textiles used in non-surgical environments are conventional, which partly gives rise to the spread of infectious diseases even among patients who go to hospital for non-surgical care'. These garments can pose a public health risk due to the inability of current hospital laundries to annihilate bacteria that have grown antibiotic resistant in the hospital environment.

Team member, Professor Halina Podbielska, Director of the Institute of Biomedical Engineering and Instrumentation, at Wroclaw University of Technology, Poland considers that the use of nanotechnology for such conventional, reusable textiles with superior anti-microbial performance will also provide significant cost savings due to reusability. 'Such textiles' she expects 'will find ready use in the manufacture of reusable hospital garments for non-surgical applications such as bedding, pillow covers, nurse's uniforms etc.'

World Health Statistics 2007 show that there are 7.94 million nurses registered in Europe and USA. Assuming the average cost of a standard reusable uniform to be around $40, the team estimates a total annual value of $634 million for this segment alone.

The BioElectricSurface consortium is funded by the European Commission under its Framework 7 NMP- Nanosciences, Nanotechnologies, Materials and new Production Technologies programme.  The project, which is led from the Materials and Surface Science Institute (MSSI), University of Limerick, has received funding of €5million for this major transnational research effort. The following partners are involved in the project: University of Limerick, Ireland; Wroclaw University of Technology, Poland; Technical University Dresden, Germany; Danish Technological Institute, Denmark; Comenius University, Slovakia; University Politehnica of Bucharest, Romania; Ben-Gurion University of the Negev, Israel, Peter Brehm, Germany; Cook Medical, Ireland; Wroclaw Medical University, Poland; Balton Sp. Z.o.o., Poland and National University Ireland, Galway, Ireland.

Industry enquires in tailoring this technology for particular textiles are welcomed. Contact the Project Coordinator Dr. Tofail Syed by e-mail at Tofail.Syed@ul.ie or Exploitation Manager John Mulcahy at John.Mulcahy@ul.ie

The BioElectricSurface research leading to these results has received funding from the European Community's Seventh Framework Programme (FP7/2007-2011) under grant agreement n212533. This communication reflects the views only of the author, and the Commission cannot be held responsible for any use which may be made of the information contained therein.

 


UL Ceremonies 
University of Limerick, Limerick, Ireland, T: +353 (0)61 202700  :  Disclaimer   :  Privacy & Cookie Statement  :  Contact  :  Location