Quantitative Visualization of Molecular Transport through Porous Membranes: Enhanced Resolution and Contrast Using Intermittent Contact-Scanning Electrochemical Microscopy

The use of intermittent contact-scanning electrochemical microscopy (IC-SECM) in diffusion-limited amperometric mode to visualize and quantify mass transport through multiporous membranes is described using dentin as a model example. The IC mode of SECM employs the damping of a vertically modulated...

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Bibliographic Details
Published in:Analytical chemistry (Washington) 2011-09, Vol.83 (17), p.6447-6454
Main Authors: McKelvey, Kim, Snowden, Michael E, Peruffo, Massimo, Unwin, Patrick R
Format: Article
Language:English
Subjects:
Analytical chemistry
Biological and medical sciences
Cell physiology
Chemistry
Chromatographic methods and physical methods associated with chromatography
Electric currents
Electrochemical methods
Exact sciences and technology
Fundamental and applied biological sciences. Psychology
Membrane and intracellular transports
Membranes
Molecular and cellular biology
Molecules
Other chromatographic methods
Scanning electron microscopy
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Summary:The use of intermittent contact-scanning electrochemical microscopy (IC-SECM) in diffusion-limited amperometric mode to visualize and quantify mass transport through multiporous membranes is described using dentin as a model example. The IC mode of SECM employs the damping of a vertically modulated ultramicroelectrode (UME) to achieve positioning close to the receptor side of a membrane. In this way the UME can detect electroactive species close to the pore exit. A key aspect of IC-SECM is that in addition to the direct current (dc) from the diffusion-limited detection of the analyte, an alternating current (ac) also develops due to the motion of the probe. It demonstrates that this ac signal enhances the spatial resolution of SECM detection and allows the hydrodynamic flow of species to be detected from individual closely spaced pores. The experimental deductions are supported by three-dimensional finite element modeling which allows IC-SECM current maps to be analyzed to reveal transport rates through individual pores. The method described should be widely applicable to multiporous membrane transport.
ISSN:0003-2700
1520-6882
DOI:10.1021/ac201489c