Electrostrictive forces on vesicles with compartmentalized permittivity and conductivity conditions

IEEE Transactions on Dielectrics and Electrical Insulation

Volumn 16, Issue 5, 2009, Pages 1280-1287

  Rey, Jose I ^a   Connolly, Richard J ^a   Jaroszeski, Mark J ^a   Hoff, Andrew M ^a,b   Llewellyn, J Anthony ^a   Gilbert, Richard ^a  

^a UNIVERSITY OF SOUTH FLORIDA   (United States)

^b University of South Florida   (United States)

Author keywords

Biological cells; Biological effects of electromagnetic radiation; Biological tissues; Biomembranes; Electromechanical effects; Electrostriction; Lipid bilayer vesicle model

Indexed keywords

BIOLOGICAL CELLS; BIOLOGICAL EFFECTS OF ELECTROMAGNETIC RADIATION; BIOLOGICAL TISSUES; BIOMEMBRANES; ELECTROMECHANICAL EFFECTS; LIPID BILAYER VESICLE MODEL;

BIOLOGICAL RADIATION EFFECTS; CELL MEMBRANES; DIELECTRIC MATERIALS; ELECTRIC FIELDS; ELECTRIC PROPERTIES; ELECTROMAGNETIC WAVE EMISSION; ELECTROMAGNETIC WAVES; ELECTRON OPTICS; ELECTROSTRICTION; HISTOLOGY; LIPID BILAYERS;

PERMITTIVITY;

EID: 70449395290     PISSN: 10709878     EISSN: None     Source Type: Journal    
DOI: 10.1109/TDEI.2009.5293939     Document Type: Article

References (33)

1. R. Dimova, K. A. Riske, S. Aranda, N. Bezlyepkina, R. L. Knorr, and R. Lipowsky, "Giant vesicles in electric fields", SoftMatter, Vol.3, pp. 817-827, 2007.
2. J. Teissie, M. Golzio, and M. P. Rols, "Mechanisms of cell membrane electropermeabilization: A minireview of our present (lack of) knowledge", Biochimica et Biophysica Acta (BBA)-General Subjects, Vol.1724, pp. 270-280, 2005.
3. T. J. Lewis, "A model for bilayer membrane electroporation based on resultant electromechanical stress", IEEE Trans. Dielectr. Electr. Insul., Vol.10, pp. 769-777, 2003.
4. T. J. Lewis, "The piezoelectric effect", IEEE Conf. Electr. Insul. Dielectr. Phenomena (CEIDP), pp. 717-720, 2005.
5. A. D. Rey, "Liquid crystal model of membrane flexoelectricity," Phys. Rev. E (Statistical, Nonlinear, and Soft Matter Physics), Vol.74, p. 011710, 2006.
6. L.-T. Gao, X.-Q. Feng, Y.-J. Yin, and H. Gao, "An electromechanical liquid crystal model of vesicles", J. Mech. Phys. Solids, Vol.56, pp. 2844-2862, 2008.
7. U. Zimmermann, U. Friedrich, H. Mussauer, P. Gessner, K. Hamel, and V. Sukhorukov, "Electromanipulation of mammalian cells: fundamentals and application", IEEE Trans. Plasma Sci., Vol.28, pp. 72-82, 2000.
8. P. Phillip and J. R. Bradley, "Electrostriction of anisotropic tissue", Phys. Rev. E (Statistical, Nonlinear, and Soft Matter Physics), Vol.75, p. 021903, 2007.
9. M. Kummrow and W. Helfrich, "Deformation of giant lipid vesicles by electric fields", Phys. Rev. A, vol.44, p. 8356, 1991.
10. S. Aranda, K. A. Riske, R. Lipowsky, and R. Dimova, "Morphological Transitions of Vesicles Induced by Alternating Electric Fields", Biophysical J., Vol.95, pp. L19-L21, 2008.
11. M. D. Mitov, P. Méléard, M. Winterhalter, M. I. Angelova, and P. Bothorel, "Electric-field-dependent thermal fluctuations of giant vesicles", Physical Review E, Vol.48, p. 628, 1993.
12. V. L. Sukhorukov, H. Mussauer, and U. Zimmermann, "The Effect of Electrical Deformation Forces on the Electropermeabilization of Erythrocyte Membranes in Low-and High-Conductivity Media", J. Membrane Biology, Vol.163, pp. 235-245, 1998.
13. H. Engelhardt and E. Sackmann, "On the measurement of shear elastic moduli and viscosities of erythrocyte plasma membranes by transient deformation in high frequency electric fields", Biophysical J., Vol.54, pp. 495-508, 1988.
14. F. Thom and H. Gollek, "Calculation of mechanical properties of human red cells based on electrically induced deformation experiments," J. Electrostatics, Vol.64, pp. 53-61, 2006.
15. T. J. Byers and D. Branton, "Visualization of the protein associations in the erythrocyte membrane skeleton", Proc. National Academy of Sciences of the United States of America, Vol.82, pp. 6153-6157, 1985.
16. N. Mohandas and E. Evans, "Mechanical Properties of the Red Cell Membrane in Relation to Molecular Structure and Genetic Defects", Annual Rev. Biophysics and Biomolecular Structure, Vol.23, pp. 787-818, 1994.
17. J. C. Weaver, "Electroporation of biological membranes from multicellular to nano scales", IEEE Trans. Dielectr. Electr. Insul., Vol.10, pp. 754-768, 2003.
18. R. P. Joshi, Q. Hu, K. H. Schoenbach, and S. J. Beebe, "Energylandscape-model analysis for irreversibility and its pulse-width dependence in cells subjected to a high-intensity ultrashort electric pulse", Phys. Rev. E, Vol.69, p. 051901, 2004.
19. K. H. Schoenbach, S. J. Beebe, E. S. Buescher, "Intracellular effect of ultrashort electrical pulses", Bioelectromagnetics, Vol.22, pp. 440-448, 2001.
20. A. Ivorra and B. Rubinsky, "In vivo electrical impedance measurements during and after electroporation of rat liver", Bioelectrochemistry, Vol.70, pp. 287-295, 2007.
21. G. H. Markx and C. L. Davey, "The dielectric properties of biological cells at radiofrequencies: applications in biotechnology", Enzyme and Microbial Technology, Vol.25, pp. 161-171, 1999.
22. Comsol-AB, "Comsol Multiphysics AC/DC Module," 3.4 2007.
23. J. W. Ashe, D. K. Bogen, and S. Takashima, "Deformation of biological cells by electric fields: Theoretical prediction of the deformed shape", Ferroelectrics, Vol.86, pp. 311-324, 1988.
24. H. Hyuga, K. J. Kinosita, and N. Wakabayashi, "Deformation of Vesicles under the Influence of Strong Electric Fields", Japanese J. Appl. Phys., Vol.30, pp. 1141-1148, 1991. (Pubitemid 21698817)
25. A. Montalibet, J. Jossinet, A. Matias, and D. Cathignol, "Electric current generated by ultrasonically induced Lorentz force in biological media", Medical and Biological Engineering and Computing, Vol.39, pp. 15-20, 2001.
26. E. Tekle, H. Oubrahim, S. M. Dzekunov, J. F. Kolb, K. H. Schoenbach, and P. B. Chock, "Selective Field Effects on Intracellular Vacuoles and Vesicle Membranes with Nanosecond Electric Pulses", Biophysical J., Vol.89, pp. 274-284, 2005.
27. R. P. Joshi, Q. Hu, and K. H. Schoenbach, "Dynamical modeling of cellular response to short-duration, high-intensity electric fields," IEEE Trans. Dielectr. Electr. Insul., Vol.10, pp. 778-787, 2003.
28. K. A. Riske and R. Dimova, "Electro-Deformation and Poration of Giant Vesicles Viewed with High Temporal Resolution", Biophysical J., Vol.88, pp. 1143-1155, 2005.
29. M. Neek-Amal, A. Lajevardipour, and H. R. Sepangi, "Electric field effects on Nano-Scale bio-membrane of spherical cells", Physica A: Statistical Mechanics and its Applications, Vol.388, pp. 120-128, 2009.
30. G. Bryant and J. Wolfe, "Electromechanical stresses produced in the plasma membranes of suspended cells by applied electric fields," J. Membrane Biology, Vol.96, pp. 129-139, 1987.
31. R. P. Joshi, Q. Hu, K. H. Schoenbach, and H. P. Hjalmarson, "Theoretical predictions of electromechanical deformation of cells subjected to high voltages for membrane electroporation", Phys. Rev. E, Vol.65, p. 021913, 2002.
32. D. Needham and R. M. Hochmuth, "Electro-mechanical permeabilization of lipid vesicles. Role of membrane tension and compressibility", Biophysical J., Vol.55, pp. 1001-1009, 1989.
33. P. M. Vlahovska, R. S. Gracia, S. Aranda-Espinoza, and R. Dimova, "Electrohydrodynamic model of vesicle deformation in alternating electric fields", Biophysical J., Vol.96, pp. 4789-4803, 2009.