by Alexander B. Tesler, Wolfgang H. Goldmann
Abstract:
ABSTRACT Traditional treatment of biofouling with toxic paints or antibiotics has significant limitations and challenges, including negative impacts on surrounding ecosystems and the emergence of resistant microbial strains. Antibiotics often prove ineffective in penetrating the dense and protective structure of biofilms, rendering traditional antimicrobial approaches less effective and leading to chronic infections. Toxic paints, while initially effective in reducing microbial colonization, contribute to long‐term environmental contamination and harm non‐target organisms. In contrast, novel technologies such as aerophilic surfaces, a special type of superhydrophobic surface, and liquid‐infused slippery surfaces offer promising alternatives to conventional biofilm management technologies. While aerophilic surfaces create a physical barrier that inhibits biofilm formation by reducing the direct contact of aqueous media with solid surfaces, liquid‐infused slippery surfaces enhance the anti‐biofouling effect by maintaining a protective lubricating layer that prevents organisms from settling. These nontoxic technologies not only provide a more sustainable and effective means of combating biofilms but also minimize the environmental impact associated with conventional treatments. By leveraging the unique properties of advanced materials, we can increase the durability and effectiveness of surfaces, leading to improved outcomes in various fields, including medical devices and marine applications.
Reference:
Alexander B. Tesler, Wolfgang H. GoldmannAnti‐Biofouling Coatings Based on Ultra‐Slippery SurfacesIn Cell Biology International, 2025.
Bibtex Entry:
@article{tesler_antibiofouling_2025, title = {Anti‐{Biofouling} {Coatings} {Based} on {Ultra}‐{Slippery} {Surfaces}}, issn = {1065-6995, 1095-8355}, url = {Tesler 2025 Cell Biology Int.pdf}, doi = {10.1002/cbin.70065}, abstract = {ABSTRACT Traditional treatment of biofouling with toxic paints or antibiotics has significant limitations and challenges, including negative impacts on surrounding ecosystems and the emergence of resistant microbial strains. Antibiotics often prove ineffective in penetrating the dense and protective structure of biofilms, rendering traditional antimicrobial approaches less effective and leading to chronic infections. Toxic paints, while initially effective in reducing microbial colonization, contribute to long‐term environmental contamination and harm non‐target organisms. In contrast, novel technologies such as aerophilic surfaces, a special type of superhydrophobic surface, and liquid‐infused slippery surfaces offer promising alternatives to conventional biofilm management technologies. While aerophilic surfaces create a physical barrier that inhibits biofilm formation by reducing the direct contact of aqueous media with solid surfaces, liquid‐infused slippery surfaces enhance the anti‐biofouling effect by maintaining a protective lubricating layer that prevents organisms from settling. These nontoxic technologies not only provide a more sustainable and effective means of combating biofilms but also minimize the environmental impact associated with conventional treatments. By leveraging the unique properties of advanced materials, we can increase the durability and effectiveness of surfaces, leading to improved outcomes in various fields, including medical devices and marine applications.}, language = {en}, urldate = {2025-08-04}, journal = {Cell Biology International}, author = {Tesler, Alexander B. and Goldmann, Wolfgang H.}, month = jul, year = {2025}, pages = {cbin.70065}, }