Real-Time Chemical Imaging of Bacterial Activity in Biofilms Using Open-Channel Microfluidics and Synchrotron FTIR Spectromicroscopy

Real-time chemical imaging of bacterial activities can facilitate a comprehensive understanding of the dynamics of biofilm structures and functions. Synchrotron-radiation-based Fourier transform infrared (SR-FTIR) spectromicroscopy can yield high spatial resolution and label-free vibrational signatu...

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Bibliographic Details
Published in:Analytical chemistry (Washington) 2009-10, Vol.81 (20), p.8564-8570
Main Authors: Holman, Hoi-Ying N, Miles, Robin, Hao, Zhao, Wozei, Eleanor, Anderson, L. Meadow, Yang, Haw
Format: Article
Language:English
Subjects:
Absorption
Analytical chemistry
Anti-Bacterial Agents - metabolism
Anti-Bacterial Agents - pharmacology
Applied sciences
Bacteria
Bacteria - drug effects
Bacteria - metabolism
Bacterial Adhesion
Biofilms
Chemical bonds
Chemistry
DNA, Bacterial - metabolism
Escherichia coli - drug effects
Escherichia coli - metabolism
Escherichia coli - physiology
Exact sciences and technology
Fourier transforms
Global environmental pollution
Glycocalyx - metabolism
Infrared imaging systems
Microfluidic Analytical Techniques
Microscopy
Mitomycin - metabolism
Mitomycin - pharmacology
Molecular Imaging - instrumentation
Pollution
Spectrometric and optical methods
Spectroscopy, Fourier Transform Infrared
Synchrotrons
Time Factors
Water - chemistry
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Summary:Real-time chemical imaging of bacterial activities can facilitate a comprehensive understanding of the dynamics of biofilm structures and functions. Synchrotron-radiation-based Fourier transform infrared (SR-FTIR) spectromicroscopy can yield high spatial resolution and label-free vibrational signatures of chemical bonds in biomolecules, but the abundance of water in biofilms has hindered SR-FTIR’s sensitivity in investigating bacterial activity. We developed a simple open-channel microfluidic system that can circumvent the water-absorption barrier for chemical imaging of the developmental dynamics of bacterial biofilms with a spatial resolution of several micrometers. This system maintains a 10 μm thick laminar-flow-through biofilm system that minimizes both the imaging volume in liquid and the signal interference from geometry-induced fringing. Here we demonstrate the ability of the open-channel microfluidic platform to maintain the functionality of living cells while enabling high-quality SR-FTIR measurements. We include several applications that show how microbes in biofilms adapt to their immediate environments. The ability to directly monitor and map bacterial changes in biofilms can yield significant insight into a wide range of microbial systems, especially when coupled to more sophisticated microfluidic platforms.
ISSN:0003-2700
1520-6882
DOI:10.1021/ac9015424