Biofilms and Biofouling
Biofilms and Biofouling Research Project
Why this project matters
Biofilms shape environmental processes, industrial performance, and many clinically important infections. They are structurally complex, dynamic, and often resistant to conventional treatment. Traditional observaion of biofilm development is informative, but it is frequently slow, labor-intensive, and difficult to scale.
Our project was initiated to change this vision. We develop a digital biology framework in which electron microscopy, high-throughput image processing, neural networks, synthetic data generation, and graph-based representations are combined with experimental microbiology and materials science. The result is a new way to observe biofilms not only as isolated images, but as quantitative systems that can be measured, compared, modeled, and redesigned.
Let us digitize biofilms and gain a new view of biofouling.
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Project objectives
- Create AI-enabled tools for quantitative and scalable analysis of biofilm morphology and growth.
- Translate image-rich experiments into measurable biological and materials-science descriptors.
- Connect digital analysis with real applications in sensing, antibiofilm materials, environmental monitoring, and sustainable catalysis.
- Open the methodology for collaboration with biologists, chemists, materials scientists, and environmental researchers.
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Publications: AI tools |
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Digital biology approach for macroscale studies of biofilm growth and biocide effects with electron microscopy Digital Discovery 2023, 2, 1522-1539 |
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Deep generative modeling of annotated bacterial biofilm images npj Biofilms and Microbiomes 2025, 11:16 |
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Deep learning-based high-information-content graph representation of early stage bacterial biofilms npj Biofilms and Microbiomes 2026 |
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Publications: Applications |
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"3-in-1" Hybrid Biocatalysts: Association of Yeast Cells Immobilized in a Sol-Gel Matrix for Determining Sewage Pollution ACS Applied Materials & Interfaces 2023, 15, 47779-47789 |
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Multicationic Quaternary Ammonium Compounds: A Framework for Combating Bacterial Resistance ACS Infectious Diseases 2023, 9, 1206-1220 |
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From Antibacterial to Antibiofilm Targeting: An Emerging Paradigm Shift in the Development of Quaternary Ammonium Compounds (QACs) ACS Infectious Diseases 2023, 9, 394-422 |
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Electroactive biofilms from activated sludge: Mechanistic insights into electron transport on nanostructured electrodes for the development of biosensors and microbial fuel cell devices Biosensors and Bioelectronics 2025, article 118195 |
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Aerobic bacteria-supported biohybrid palladium catalysts for efficient cross-coupling reactions Journal of Catalysis 2024, 429, 115238 |
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Designing Effective Antimicrobial Agents: Structural Insights into the Antibiofilm Activity of Ionic Liquids Journal of Medicinal Chemistry 2025, 68, 2105-2123 |
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Preparation of Hybrid Sol-Gel Materials Based on Living Cells of Microorganisms and Their Application in Nanotechnology Nanomaterials 2022, 12, 1086 |
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Sustainable catalysts in a short time: harnessing bacteria for swift palladium nanoparticle production Nanoscale 2025, 17, 5289-5300 |
