Electroporation of Unilamellar Vesicles studied by using a Pore-Mediated Electron Transfer Reaction

CORREA, N. MARIANO; SCHELLY, Z. A.

LANGMUIR

AMER CHEMICAL SOC

Lugar: Washington; Año: 1998 vol. 14 p. 5802 - 5805

0743-7463

The dynamics of electric field-induced pore formation (electroporation) is investigated in 186 nm diameter, unilamellar bilayer vesicles (liposomes) prepared from the phospholipid surfactant dioleoylphosphatidylcholine (DOPC). Formation of reversible transient pores is detected via the spectral changes associated with the electron-transfer reaction between Fe(CN)64- ions entrapped in the interior compartment of the vesicle and Ir(Cl)62- ions placed in the bulk medium. Upon application of a high-voltage square pulse (E = 8 kV/cm) to the suspension, poration occurs only if the pulse length is ≥200 μs. The field-induced elongation of the time average spherical vesicles to prolate ellipsoid in the direction of the applied field E is detected through the transient birefringence of the system. The onset of elongation precedes the availability of pores large enough for Fe(CN)64- to pass through, with an estimated radius of 9.6 Å. The average rate of radius growth of the reversible pores (4 × 10-6 m s-1) is found to be 5 orders of magnitude smaller than that of irreversible electropores in planar black lipid membranes of similar phospholipids.