Resealing dynamics of a cell membrane after electroporation
- 26 December 2002
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review E
- Vol. 66 (6) , 062905
- https://doi.org/10.1103/physreve.66.062905
Abstract
The membrane of a living cell consists of a bilayer of amphipolar lipid molecules as well as much larger proteins. Transmembrane potentials of up to 120 mV are physiologic and well tolerated, but when the potential is more than 300 mV, this lipid bilayer is unstable. Pores are then formed through which measurable flow of ions can occur. We follow currents through frog muscle cell membranes under 4-ms pulses of up to 440 mV. We present a theory that allows us to describe the relaxation of the current back to zero after the pulse in terms of membrane parameters. We obtain a line tension of which is similar to that found in artificial lipid bilayers.
Keywords
This publication has 8 references indexed in Scilit:
- Kinetics of sealing for transient electropores in isolated mammalian skeletal muscle cellsBioelectromagnetics, 1999
- Understanding the Electroporation of Cells and Artificial Bilayer MembranesPhysical Review Letters, 1998
- Dynamically stabilized pores in bilayer membranesBiophysical Journal, 1997
- Theory of electroporation: A reviewBioelectrochemistry and Bioenergetics, 1996
- An improved double vaseline gap voltage clamp to study electroporated skeletal muscle fibersBiophysical Journal, 1994
- Effect of voltage on pores in membranesPhysical Review A, 1987
- Transient aqueous pores in bilayer membranes: A statistical theoryBioelectrochemistry and Bioenergetics, 1986
- Stability of lipid bilayers and red blood cell membranesPhysics Letters A, 1975