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16.05.2024 15:08

Customised production of antiviral coatings and cell culture surfaces

Pressestelle Uni Kiel Presse, Kommunikation und Marketing
Christian-Albrechts-Universität zu Kiel

    The method of material scientists from Kiel enables first comprehensive comparison of polymer coatings for biomedical applications

    The stop buttons on the bus or the protective glass at the registration desk in the medical office: Every day we come into contact with a wide range of surfaces. Special polymer coatings give them functional properties, for example antiviral behaviour. A team from the Department of Materials Science at Kiel University has now for the first time comprehensively compared various biomedical coatings and investigated what happens when they interact with the skin, with cells or with viruses. The results have been published in the scientific journal Advanced Materials Interfaces and applied in a first industrial project with antiviral glass.

    In collaboration with the University Medical Centre Schleswig-Holstein in Kiel (UKSH), the Nanotechnology Research Centre Egypt and the National Cancer Institute of Cairo University, researchers of Kiel University have comprehensively compared six coating materials for biomedical applications. The team investigated the bio-interface-performance of the material surfaces to respiratory viruses, cancer cells and fibroblasts. "For example, we looked at where key proteins, such as the spike protein of the coronavirus, dock onto material surfaces and show antiviral behaviour," says materials scientist Torge Hartig, first author of the study. For antiviral coatings against coronaviruses, the team was able to show that such interactions can also be calculated to narrow down the number of potential materials.

    Production method makes comparison possible for the first time

    This detailed investigation is only possible because of the method the team of Kiel produces the coatings. For many years, they have been working on the initiated chemical vapour deposition (iCVD) at Professor Franz Faupel's Chair for Multicomponent Materials. "This enables us to produce transparent coatings and adjust their thickness with high precision between 10 nanometres and 10 micrometres. Their surface is ultra-smooth, extremely uniform and has no disturbing defects," says Hartig.

    This is crucial because many factors typically play a role in contact with coatings. With conventional polymer coatings, for example, the surface topography, chemical processes, solvent residues or material defects can influence interactions with viruses or cells. "With our technology, we produce coatings that are so pure that all other factors apart from chemical processes can be excluded and we can fundamentally analyse the actual interactions between the coating and viruses or cells," continues Hartig, who is doing his doctorate thesis on biomedical iCVD coatings.

    From ambulances to supermarket checkouts: coatings tested with window manufacturers

    The materials scientists can control their production process very well and thus predict and define the functional properties of their coatings in a targeted manner - for example, to fulfil the high requirements in biomedical environments. "We can coat products for cell culture in such a way that the cells adhere better and are easier to cultivate," says Dr Stefan Schröder, leader of the iCVD activities at the Chair. As their method requires no solvents and only few chemicals, it is also significantly more environmentally friendly than conventional wet-chemical coating processes.

    Together with a window manufacturer from Southern Germany, the materials scientists from Kiel have put their findings into practice. The collaboration was funded by the Zentrales Innovationsprogramm Mittelstand (Central Innovation Programme for small and medium-sized enterprises, SMEs) of the German Federal Ministry for Economic Affairs and Climate Action. "We compared several antiviral coatings and applied the best one to window glass," says Schröder. Large glass facades cannot yet be coated, "but small surfaces that are exposed to a lot of contact, such as touch displays in hospitals and ambulances, filters in breathing masks or cash registers at supermarket checkouts," says Schröder, who also wrote his doctoral thesis on the iCVD process.

    Own company in preparation

    A team from the chair now wants to apply the iCVD research of recent years on an industrial scale and is currently preparing a spin-off. They are funded by the EXIST research transfer programme of the Federal Ministry for Economic Affairs and Climate Action, which is co-funded by the European Union. "Our goal is to produce particularly high-quality coatings with customised properties for medicine and industry," says Hartig, who joined the start-up initiative "conformally" while still working on his doctorate. In addition to antiviral properties, these coatings can also be water-repellent or insulating, for example - or even a combination of both.

    Some of the materials used in the study were developed in the Collaborative Research Centre "SFB 1261: Magnetoelectric Sensors: From Composite Materials to Biomagnetic Diagnosis" and in the Research Training Group 2154 "Materials for Brain" at Kiel University, funded by the German Research Foundation DFG.

    About the iCVD process:
    Unlike other wet chemical coating methods such as vapour deposition, the iCVD (initiated chemical vapour deposition) process recombines the starting molecules to produce high-quality material layers down to nanometre-thickness. Vapours are introduced into a reaction chamber for this purpose. Hot filaments break the bonds and the molecules hit the surface to be coated, where they form a thin film, even on uneven or porous surfaces.

    Wissenschaftliche Ansprechpartner:

    Prof. Franz Faupel
    Chair for Multicomponent Materials, Kiel University
    Phone: +49 431 880-6225

    Dr. Stefan Schröder
    Chair for Multicomponent Materials, Kiel University
    Phone: +49 431 880-6232


    iCVD Polymer Thin Film Bio-Interface-Performance for Fibroblasts, Cancer-Cells, and Viruses Connected to Their Functional Groups and In Silico Studies. Torge Hartig, Asmaa T. Mohamed, Nasra F. Abdel Fattah, Aydin Gülses, Tim Tjardts, Esther Afiba Kangah, Kwing Pak Gabriel Chan, Salih Veziroglu, Yahya Acil, Oral Cenk Aktas, Jörg Wiltfang, Samah A Loutfy, Thomas Strunskus, Franz Faupel, Amal Amin, and Stefan Schröder. Adv. Mater. Interfaces 2024, 11, 2300587.

    Weitere Informationen: Link to the press release further information Priority Research Area KiNSIS of Kiel University


    For the first time, Materials scientists Torge Hartig (left) and Stefan Schröder have compared the properties of polymer coatings for biomedical applications in a comprehensive study.
    For the first time, Materials scientists Torge Hartig (left) and Stefan Schröder have compared the p ...
    Photo: Julia Siekmann, Uni Kiel

    Merkmale dieser Pressemitteilung:
    Journalisten, Wirtschaftsvertreter, Wissenschaftler
    Biologie, Medizin, Werkstoffwissenschaften
    Forschungsergebnisse, Wissenschaftliche Publikationen


    For the first time, Materials scientists Torge Hartig (left) and Stefan Schröder have compared the properties of polymer coatings for biomedical applications in a comprehensive study.

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