News Release 24-Sep-2024
Peer-Reviewed Publication
Chalmers University of Technology
image:
Illustration of how the razor-sharp flakes of graphene line up together on a surface and can kill bacteria without harming healthy human cells. The bactericidal graphene surfaces developed at Chalmers University of Technology may soon be applied in medical devices thanks to a brand-new method using fridge magnet technology to control the bactericidal effects of graphene.
Credit: Chalmers University of Technology |Yen Sandqvist
With strong bactericidal properties, graphene has the potential to become a game changer in the fight against antibiotic-resistant bacteria. So far there have been no efficient ways to control these properties – and thus no way to make use of graphene’s potential in healthcare. Now researchers at Chalmers University of Technology, in Sweden, have solved the problem by using the same technology found in an ordinary fridge magnet. The result of which, is an ultra-thin acupuncture-like surface that can act as a coating on catheters and implants – killing 99.9 percent of all bacteria on a surface.
Healthcare-associated infections are a widespread problem around the world, causing great suffering, high healthcare costs and a heightened risk of increased antibiotic resistance. Most infections occur in connection with the use of various medical technology products such as catheters, hip prostheses, knee prostheses and dental implants, where bacteria are able to enter the body via a foreign surface. At Chalmers University of Technology, researchers have been exploring how graphene, an atomically thin two-dimensional graphite material, can contribute to the fight against antibiotic resistance and infections in healthcare. The research team has previously been able to show how vertically standing graphene flakes prevent bacteria from attaching to the substrate. Instead, the bacteria are cut to pieces on the razor-sharp flakes and die.
“We are developing a graphene-based, ultra-thin, antibacterial material that can be applied to any surface, including biomedical devices, surgical surfaces and implants to exclude bacteria. “Since graphene prevents bacteria from physically attaching to a surface, it has the added advantage that you do not risk increasing antibiotic resistance, unlike with other chemical alternatives, such as antibiotics,” says Ivan Mijakovic, Professor of Systems Biology at Chalmers University of Technology and one of the authors of the recently published study.
Kills 99.99% of bacteria on a surface
However, the researchers have been facing a challenge. Although its bactericidal properties can be demonstrated in the laboratory, the researchers have not yet managed to control the orientation direction of the graphene flakes– and subsequently not been able to apply the material on surfaces used on medical devices used in healthcare. So far, the bactericidal properties of graphene have only been able to be controlled in one specific direction: the flow direction of the manufacturing process. But now the Chalmers researchers have had a promising breakthrough for a practical application in healthcare – and beyond.
“We have managed to find a way to control the effects of graphene practically in several different directions and with a very high level of uniformity of the orientation. This new orientation method makes it possible to integrate graphene nanoplates into medical plastic surfaces and get an antibacterial surface that kills 99.9% of the bacteria that try to attach. This paves the way for significantly greater flexibility when you want to manufacture bacteria-killing medical devices using graphene”, says Roland Kádár, Professor of Rheology at Chalmers University of technology.
Unpreceded efficiency by controlling magnetic fields
By arranging earth magnets in a circular pattern making the magnetic field inside the array arrange in a straight direction, the researchers were able to induce a uniform orientation of the graphene and reach a very high bactericidal effect on surfaces of any shape.
The method, published in Advanced Functional Materials, is called “Halbach array” and means that the magnetic field inside the magnet array is strengthened and uniform while it is weakened on the other side, enabling a strong unidirectional orientation of graphene. The technology is similar to what you would find in a refrigerator magnet.
“This is the first time the Halbach array method has been used to orient graphene in a polymer nanocomposite. Now that we have seen the results, of course we want these graphene plates to get introduced in the healthcare sector so that we can reduce the number of healthcare-related infections, reduce suffering for patients and counteract antibiotic resistance”, says Viney Ghai, researcher in Rheology and Processing of Soft Matter at Chalmers University of Technology.
The new orientation technology shows significant potential in other areas, for example in batteries, supercapacitors, sensors and durable water-resistant packaging materials.
“Given its broad impact across these areas, this method truly opens up new horizons in material alignment, providing a powerful tool for the successful design and customisation of nanostructures that biomimic the intricate architectures found in natural systems,” says Roland Kádár.
Illustration caption: Illustration of how the razor-sharp flakes of graphene line up together on a surface and can kill bacteria without harming healthy human cells. The bactericidal graphene surfaces developed at Chalmers University of Technology may soon be applied in medical devices thanks to a brand-new method using fridge magnet technology to control the bactericidal effects of graphene.
Illustration credit: Yen Sandqvist
Graphic 2 caption: Composite illustration of the new Halbach array magnetic field orientation setup, where the red/blue arrows indicate the magnetization direction of the individual magnets and a numerical simulation showing the magnetic field lines inside the magnet array, where the magnetic field strength reaches 1 Tesla.
Graphic credit: Roland Kadar; numerical simulation using the Comsol Multiphysics software
More about the research:
Read the study: Achieving Long-Range Arbitrary Uniform Alignment of Nanostructures in Magnetic Fields.
The study has been carried out within the framework of the competence center 2D-TECH hosted by Chalmers University of Technology. The center is financed by Vinnova, Chalmers and 19 industrial partners, and constitutes a Swedish hub for research and innovation in 2D material-based technology for applications in industry.
For more information, contact:
Roland Kádár, Professor of Rheology at the Department of Industrial and Materials Science at Chalmers University of Technology
[email protected]
+46-31-772 12 56
Viney Ghai, Researcher in Rheology and Processing of Soft Matter at the Department of Industrial and Materials Science at Chalmers University of Technology
[email protected]
Ivan Mijakovic, Professor of Systems Biology at the Department of Life Sciences at Chalmers University of Technology
[email protected]
Roland Kádár speaks English and Viney Ghai speaks English, Hindi and Punjabi, and they are both available for live and pre-recorded interviews. At Chalmers there are podcast radio studios and film equipment to be used for inquiries about TV, radio or podcasts.
More about the method:
In laboratory experiments, the researchers exposed different bacterial cultures to graphene surfaces whose magnetic fields had been manipulated according to the new method. In order to calculate how effective the method was, the bacterial survival was measured using CFU (colony-forming unit), a tool that measures the number of microorganisms in a bacterial colony. With the help of so-called Scanning Electron Microscopy (SEM), the researchers were also able to scan bacterial colonies in order to visualise and confirm using images the physical disturbance of the graphene on the bacterial cells.
More supporting material – film:
Watch the film on how a tiny layer of graphene flakes becomes a deadly weapon and kills bacteria, stopping infections during procedures such as implant surgery: https://youtu.be/qkTmNKiGTlM
Journal
Advanced Functional Materials
DOI
10.1002/adfm.202406875
Method of Research
Computational simulation/modeling
Subject of Research
Not applicable
Article Title
Achieving Long-Range Arbitrary Uniform Alignment of Nanostructures in Magnetic Fields
Article Publication Date
27-Jun-2024
COI Statement
The authors declare no conflict of interest.
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