AI Article Synopsis
- The study addresses the challenge of biofilm resistance and antimicrobial resistance (AMR), highlighting the need for innovative monitoring methods and examining the potential of bacteriophages against bacterial biofilms.
- A new real-time, label-free radiofrequency sensor is developed, which improves on traditional methods like optical density measurements and confocal microscopy by allowing for the continuous monitoring of bacteria and biofilm growth.
- The sensor offers enhanced detection of various biofilm stages and interactions, aiding in the understanding of biofilm dynamics and helping to guide effective therapeutic strategies to combat AMR.
Article Abstract
Confronting the challenge of biofilm resistance and widespread antimicrobial resistance (AMR), this study emphasizes the need for innovative monitoring methods and explores the potential of bacteriophages against bacterial biofilms. Traditional methods, like optical density (OD) measurements and confocal microscopy, crucial in studying biofilm-virus interactions, often lack real-time monitoring and early detection capabilities, especially for biofilm formation and low bacterial concentrations. Addressing these gaps, we developed a new real-time, label-free radiofrequency sensor for monitoring bacteria and biofilm growth. The sensor, an open-ended coaxial probe, offers enhanced monitoring of bacterial development stages. Tested on a biological model of bacteria and bacteriophages, our results indicate the limitations of traditional OD measurements, influenced by factors like sedimented cell fragments and biofilm formation on well walls. While confocal microscopy provides detailed 3D biofilm architecture, its real-time monitoring application is limited. Our novel approach using radio frequency measurements (300 MHz) overcomes these shortcomings. It facilitates a finer analysis of the dynamic interaction between bacterial populations and phages, detecting real-time subtle changes. This method reveals distinct phases and breakpoints in biofilm formation and virion interaction not captured by conventional techniques. This study underscores the sensor's potential in detecting irregular viral activity and assessing the efficacy of anti-biofilm treatments, contributing significantly to the understanding of biofilm dynamics. This research is vital in developing effective monitoring tools, guiding therapeutic strategies, and combating AMR.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11013890 | PMC |
| http://dx.doi.org/10.3390/s24072042 | DOI Listing |
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