Presentation is loading. Please wait.

Presentation is loading. Please wait.

Vijayanand Vajrala, James R. Claycomb, Hugo Sanabria, John H. Miller 

Published byFrancis Marier Modified over 5 years ago

Similar presentations

Presentation on theme: "Vijayanand Vajrala, James R. Claycomb, Hugo Sanabria, John H. Miller "— Presentation transcript:

1 Effects of Oscillatory Electric Fields on Internal Membranes: An Analytical Model 
Vijayanand Vajrala, James R. Claycomb, Hugo Sanabria, John H. Miller  Biophysical Journal  Volume 94, Issue 6, Pages (March 2008) DOI: /biophysj Copyright © 2008 The Biophysical Society Terms and Conditions

2 Figure 1 Schematic of the three-membrane cell model. The outer shell represents the plasma membrane, and the inner two shells represent the OMMs and IMMs. Biophysical Journal  , DOI: ( /biophysj ) Copyright © 2008 The Biophysical Society Terms and Conditions

3 Figure 2 Electric field vector plot and potential distribution near the plasma membrane with mobile surface charges in an alternating electric field. The uniform electric field in the cell is greater at (a) 106Hz than at (b) 102Hz. The excitation field is 1.0V/cm. Biophysical Journal  , DOI: ( /biophysj ) Copyright © 2008 The Biophysical Society Terms and Conditions

4 Figure 3 Variation of the induced potential across the plasma membrane with frequency of the excitation field in the whole cell, three-membrane model (a) without free charges and (b) with a surface charge density of 0.01C/m2 on the outer and 0.001C/m2 on the inner membrane surface. The excitation field is 1.0V/cm. Biophysical Journal  , DOI: ( /biophysj ) Copyright © 2008 The Biophysical Society Terms and Conditions

5 Figure 4 Variation of the induced potential across the OMM with frequency of the excitation field in the whole cell, three-membrane model (a) without free charges and (b) with a surface charge density of 0.01C/m2 on the outer and 0.001C/m2 on the inner membrane surface. The excitation field is 1.0V/cm. Biophysical Journal  , DOI: ( /biophysj ) Copyright © 2008 The Biophysical Society Terms and Conditions

6 Figure 5 Variation of the induced potential across the IMM with frequency of the excitation field in the whole cell, three-membrane model (a) without free charges and (b) with a surface charge density of 0.01C/m2 on the OMM and 0.001C/m2 on the IMM surface. The excitation field is 1.0V/cm. Biophysical Journal  , DOI: ( /biophysj ) Copyright © 2008 The Biophysical Society Terms and Conditions

7 Figure 6 Variation of the induced potential across the OMM with frequency of the excitation field in the isolated mitochondrion, two-membrane model (a) without free charges and (b) with a surface charge density of 0.01C/m2 on the OMM and 0.001C/m2 on the IMM surface. The excitation field is 1.0V/cm. Biophysical Journal  , DOI: ( /biophysj ) Copyright © 2008 The Biophysical Society Terms and Conditions

8 Figure 7 Variation of the induced potential across the IMM with frequency of the excitation field in the isolated mitochondrion, two-membrane model (a) without free charges and (b) with a surface charge density of 0.01C/m2 on the OMM and 0.001C/m2 on the IMM surface. The excitation field is 1.0V/cm. Biophysical Journal  , DOI: ( /biophysj ) Copyright © 2008 The Biophysical Society Terms and Conditions

9 Figure 8 Change in induced inner mitochondrial transmembrane potential with frequency of the excitation field for matrix conductivities of (a) 0.1, (b) 0.01, and (c) 0.001S/m. The excitation field is 1.0V/cm. Biophysical Journal  , DOI: ( /biophysj ) Copyright © 2008 The Biophysical Society Terms and Conditions

10 Figure 9 Finite element calculation showing the distribution of (a) potential and (b) electric field strength in the two-membrane model at 1MHz with parameters and dimensions given in Table 1. The partial cross section near the polar cap of the mitochondrion shows the matrix, IMM, inner membrane space, OMM, and suspending medium. The excitation field is 1.0V/cm incident from right to left in this figure. Biophysical Journal  , DOI: ( /biophysj ) Copyright © 2008 The Biophysical Society Terms and Conditions

Download ppt "Vijayanand Vajrala, James R. Claycomb, Hugo Sanabria, John H. Miller "

Similar presentations

Chapter 22: The Electric Field II: Continuous Charge Distributions

Chapter 22: The Electric Field II: Continuous Charge Distributions
Creep Function of a Single Living Cell Nicolas Desprat, Alain Richert, Jacqueline Simeon, Atef Asnacios Biophysical Journal Volume 88, Issue 3, Pages 2224-2233.

Creep Function of a Single Living Cell Nicolas Desprat, Alain Richert, Jacqueline Simeon, Atef Asnacios Biophysical Journal Volume 88, Issue 3, Pages
Light-Scattering Studies of Protein Solutions: Role of Hydration in Weak Protein-Protein Interactions A. Paliwal, D. Asthagiri, D. Abras, A.M. Lenhoff,

Light-Scattering Studies of Protein Solutions: Role of Hydration in Weak Protein-Protein Interactions A. Paliwal, D. Asthagiri, D. Abras, A.M. Lenhoff,
A Charged, Thin Sheet of Insulating Material + + + + + + + + + + +

A Charged, Thin Sheet of Insulating Material
3-6. Conductors in Static Electric Field

3-6. Conductors in Static Electric Field
Kinetic Properties of the Cardiac L-Type Ca2+ Channel and Its Role in Myocyte Electrophysiology: A Theoretical Investigation Gregory M. Faber, Jonathan.

Kinetic Properties of the Cardiac L-Type Ca2+ Channel and Its Role in Myocyte Electrophysiology: A Theoretical Investigation Gregory M. Faber, Jonathan.
Determination of the Interfacial Water Content in Protein-Protein Complexes from Free Energy Simulations Peter Monecke, Thorsten Borosch, Jürgen Brickmann,

Determination of the Interfacial Water Content in Protein-Protein Complexes from Free Energy Simulations Peter Monecke, Thorsten Borosch, Jürgen Brickmann,
The Dynamics and Mechanics of Endothelial Cell Spreading Cynthia A. Reinhart-King, Micah Dembo, Daniel A. Hammer Biophysical Journal Volume 89, Issue 1,

The Dynamics and Mechanics of Endothelial Cell Spreading Cynthia A. Reinhart-King, Micah Dembo, Daniel A. Hammer Biophysical Journal Volume 89, Issue 1,
High-Resolution Waveguide THz Spectroscopy of Biological Molecules N. Laman, S. Sree Harsha, D. Grischkowsky, Joseph S. Melinger Biophysical Journal Volume.

High-Resolution Waveguide THz Spectroscopy of Biological Molecules N. Laman, S. Sree Harsha, D. Grischkowsky, Joseph S. Melinger Biophysical Journal Volume.
Molecular Model of a Cell Plasma Membrane With an Asymmetric Multicomponent Composition: Water Permeation and Ion Effects Robert Vácha, Max L. Berkowitz,

Molecular Model of a Cell Plasma Membrane With an Asymmetric Multicomponent Composition: Water Permeation and Ion Effects Robert Vácha, Max L. Berkowitz,
Intrinsic Disorder and Functional Proteomics Predrag Radivojac, Lilia M. Iakoucheva, Christopher J. Oldfield, Zoran Obradovic, Vladimir N. Uversky, A.

Intrinsic Disorder and Functional Proteomics Predrag Radivojac, Lilia M. Iakoucheva, Christopher J. Oldfield, Zoran Obradovic, Vladimir N. Uversky, A.
Tue. Feb. 3 – Physics Lecture #26 Gauss’s Law II: Gauss’s Law, Symmetry, and Conductors 1. Electric Field Vectors and Electric Field Lines 2. Electric.

Tue. Feb. 3 – Physics Lecture #26 Gauss’s Law II: Gauss’s Law, Symmetry, and Conductors 1. Electric Field Vectors and Electric Field Lines 2. Electric.
Yield Strength of Human Erythrocyte Membranes to Impulsive Stretching Fenfang Li, Chon U Chan, Claus Dieter Ohl Biophysical Journal Volume 105, Issue 4,

Yield Strength of Human Erythrocyte Membranes to Impulsive Stretching Fenfang Li, Chon U Chan, Claus Dieter Ohl Biophysical Journal Volume 105, Issue 4,
Thermal Fluctuations of Red Blood Cell Membrane via a Constant-Area Particle- Dynamics Model Gianluca Marcelli, Kim H. Parker, C. Peter Winlove Biophysical.

Thermal Fluctuations of Red Blood Cell Membrane via a Constant-Area Particle- Dynamics Model Gianluca Marcelli, Kim H. Parker, C. Peter Winlove Biophysical.
Structure of the Alamethicin Pore Reconstructed by X-Ray Diffraction Analysis Shuo Qian, Wangchen Wang, Lin Yang, Huey W. Huang Biophysical Journal Volume.

Structure of the Alamethicin Pore Reconstructed by X-Ray Diffraction Analysis Shuo Qian, Wangchen Wang, Lin Yang, Huey W. Huang Biophysical Journal Volume.
A Hydrodynamic Model for Hindered Diffusion of Proteins and Micelles in Hydrogels Ronald J. Phillips Biophysical Journal Volume 79, Issue 6, Pages 3350-3353.

A Hydrodynamic Model for Hindered Diffusion of Proteins and Micelles in Hydrogels Ronald J. Phillips Biophysical Journal Volume 79, Issue 6, Pages
Spatiotemporal Image Correlation Spectroscopy (STICS) Theory, Verification, and Application to Protein Velocity Mapping in Living CHO Cells Benedict Hebert,

Spatiotemporal Image Correlation Spectroscopy (STICS) Theory, Verification, and Application to Protein Velocity Mapping in Living CHO Cells Benedict Hebert,
Mesoscale Simulation of Blood Flow in Small Vessels Prosenjit Bagchi Biophysical Journal Volume 92, Issue 6, Pages 1858-1877 (March 2007) DOI: 10.1529/biophysj.106.095042.

Mesoscale Simulation of Blood Flow in Small Vessels Prosenjit Bagchi Biophysical Journal Volume 92, Issue 6, Pages (March 2007) DOI: /biophysj
Determination of the Orientation and Dynamics of Ergosterol in Model Membranes Using Uniform 13C Labeling and Dynamically Averaged 13C Chemical Shift Anisotropies.

Determination of the Orientation and Dynamics of Ergosterol in Model Membranes Using Uniform 13C Labeling and Dynamically Averaged 13C Chemical Shift Anisotropies.
Analytical Solutions of Poisson's Equation for Realistic Geometrical Shapes of Membrane Ion Channels Serdar Kuyucak, Matthew Hoyles, Shin-Ho Chung Biophysical.

Analytical Solutions of Poisson's Equation for Realistic Geometrical Shapes of Membrane Ion Channels Serdar Kuyucak, Matthew Hoyles, Shin-Ho Chung Biophysical.

Similar presentations

Ads by Google