Characterization of cell membrane permeability in vitro part I: Transport behavior induced by single-pulse electric fields

Daniel C. Sweeney, James C. Weaver, Rafael V. Davalos

Research output: Contribution to journalArticlepeer-review

16 Scopus citations

Abstract

Most experimental studies of electroporation focus on permeabilization of the outer cell membrane. Some experiments address delivery of ions and molecules into cells that should survive; others focus on efficient killing of the cells with minimal temperature rise. A basic method for quantifying electroporation effectiveness is measuring the membrane’s diffusive permeability. More specifically, comparisons of membrane permeability between electroporation protocols often rely on relative fluorescence measurements, which are not able to be directly connected to theoretical calculations and complicate comparisons between studies. Here we present part I of a 2-part study: a research method for quantitatively determining the membrane diffusive permeability for individual cells using fluorescence microscopy. We determine diffusive permeabilities of cell membranes to propidium for electric field pulses with durations of 1 to 1000 μs and strengths of 170 to 400 kV/m and show that diffusive permeabilities can reach 1.3+0.4×10 8 m/s. This leads to a correlation between increased membrane permeability and eventual propidium uptake. We also identify a subpopulation of cells that exhibit a delayed and significant propidium uptake for relatively small single pulses. Our results provide evidence that cells, especially those that uptake propidium more slowly, can achieve large permeabilities with a single electrical pulse that may be quantitatively measured using standard fluorescence microscopy equipment and techniques.

Original languageEnglish
JournalTechnology in Cancer Research and Treatment
Volume17
DOIs
StatePublished - Jan 2018
Externally publishedYes

Funding

The authors would like to acknowledge the ICTAS Center for Engineered Health for their gracious financial support of this work. The authors would like to acknowledge the ICTAS Center for Engineered Health for their gracious financial support of this work. The author(s) disclosed receipt of the following financial support for the research, authorship, and/or publication of this article: Funding for this work was graciously provided for DCS and RVD by the NSF CAREER Award CBET-1055913, the NSF IGERT DGE-09661, and the NIH P01-CA207206. Funding for JCW was graciously provided by AFOSR MURI Grant FA9550-15-1-0517.

FundersFunder number
AFOSR MURI
National Science FoundationDGE-09661, CBET-1055913
National Institutes of Health
National Cancer InstituteP01CA207206
Directorate for Engineering1055913
Air Force Office of Scientific ResearchFA9550-15-1-0517
Institute for Critical Technologies and Applied Science, Virginia Tech

    Keywords

    • Diffusion
    • Electroporation
    • Propidium
    • Pulsed electric fields
    • Transport

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