A scaling law for membrane permeabilization with nanopulses

A scaling law for membrane permeabilization with nanopulses

Experimental studies of plasma membrane permeabilization, caused by single, intense, submicrosecond square wave pulses, indicate that the product of electric field amplitude and pulse duration (the electrical impulse) can be considered a similarity or scaling factor. A model based on the hypothesis...

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Bibliographic Details
Published in:IEEE transactions on dielectrics and electrical insulation Vol. 16; no. 5; pp. 1224 - 1235
Main Authors: Schoenbach, K., Joshi, R., Beebe, S., Baum, C.
Format: Journal Article
Language:English
Published: New York IEEE 01-10-2009
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Bioelectric phenomena
Biological cells
Biomembranes
Cells (biology)
Electric charge
Electric fields
electropermeabilization
electroporation
Law
Membrane effects
Membranes
Nanobioscience
Nanomaterials
nanoporation
Nanoporous materials
nanosecond electric fields
Nanostructure
Permeability
Plasma transport processes
Plasma waves
random rotation
Roots
Similarity
Studies
USA Councils
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Summary:Experimental studies of plasma membrane permeabilization, caused by single, intense, submicrosecond square wave pulses, indicate that the product of electric field amplitude and pulse duration (the electrical impulse) can be considered a similarity or scaling factor. A model based on the hypothesis that the intensity of membrane permeabilization effects is linearly dependent on the electric charge transferred through the permeabilized membrane, provides results, which are consistent with the empirical observations. For multiple pulses, bioelectric effects caused by ultrashort pulses were found to scale with the square root of the pulse number. This square root dependence on the pulse number points to a statistical motion of cells between pulses with respect to the applied electric field, and can be explained using an extension of the random walk statistical results to random rotations. Besides membrane permeabilization, the scaling law has also been shown to hold for secondary bioelectric effects, which are caused by permeability changes in the plasma membrane or subcellular membranes.
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ISSN:1070-9878
1558-4135
DOI:10.1109/TDEI.2009.5293932