Alenka Maček Lebar scite author profile

Electropermeabilization (electroporation) is a technique widely used to introduce various membrane-impermeable molecules into cells in vitro or in vivo. In this study we determined the effect of different electric-field intensities on electropermeabilization and electrosensitivity of a variety of tumor-cell lines in vitro. For this purpose we used two assays: propidium iodide uptake for measurement of cell electropenneabilization, and the clonogenic or MTT assay for determination of electrosensitivity. Our results showed that electropermeabilization of almost all cell lines tested occurred at 600 V/cm. In contrast, a marked difference in electrosensitivity existed among these cell lines. Our results could be of great importance for pharmacological and biochemical studies in vilro, and for prediction and determination of tumor response in vivo to electropermeabilization combined with chemotherapeutic drugs (electrochemotherapy) and gene therapy.

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Feasibility of Employing Model-Based Optimization of Pulse Amplitude and Electrode Distance for Effective Tumor Electropermeabilization

Šel

Lebar

Miklavčič

2007

IEEE Trans. Biomed. Eng.

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Abstract-In electrochemotherapy (ECT) electropermeabilization, parameters (pulse amplitude, electrode setup) need to be customized in order to expose the whole tumor to electric field intensities above permeabilizing threshold to achieve effective ECT. In this paper, we present a model-based optimization approach toward determination of optimal electropermeabilization parameters for effective ECT. The optimization is carried out by minimizing the difference between the permeabilization threshold and electric field intensities computed by finite element model in selected points of tumor. We examined the feasibility of model-based optimization of electropermeabilization parameters on a model geometry generated from computer tomography images, representing brain tissue with tumor. Continuous parameter subject to optimization was pulse amplitude. The distance between electrode pairs was optimized as a discrete parameter. Optimization also considered the pulse generator constraints on voltage and current. During optimization the two constraints were reached preventing the exposure of the entire volume of the tumor to electric field intensities above permeabilizing threshold. However, despite the fact that with the particular needle array holder and pulse generator the entire volume of the tumor was not permeabilized, the maximal extent of permeabilization for the particular case (electrodes, tissue) was determined with the proposed approach.Model-based optimization approach could also be used for electro-gene transfer, where electric field intensities should be distributed between permeabilizing threshold and irreversible threshold-the latter causing tissue necrosis. This can be obtained by adding constraints on maximum electric field intensity in optimization procedure.

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Chapter Seven Electroporation of Planar Lipid Bilayers and Membranes

Pavlin¹,

Kotnik²,

Miklavčič³

et al. 2008

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Determination of the lipid bilayer breakdown voltage by means of linear rising signal

Kramar

Miklavčič

Lebar

2007

Bioelectrochemistry

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Molecular-Level Characterization of Lipid Membrane Electroporation using Linearly Rising Current

et al. 2012

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We present experimental and theoretical results of electroporation of small patches of planar lipid bilayers by means of linearly rising current. The experiments were conducted on ~120-μm-diameter patches of planar phospholipid bilayers. The steadily increasing voltage across the bilayer imposed by linearly increasing current led to electroporation of the membrane for voltages above a few hundred millivolts. This method shows new molecular mechanisms of electroporation. We recorded small voltage drops preceding the breakdown of the bilayer due to irreversible electroporation. These voltage drops were often followed by a voltage re-rise within a fraction of a second. Modeling the observed phenomenon by equivalent electric circuits showed that these events relate to opening and closing of conducting pores through the bilayer. Molecular dynamics simulations performed under similar conditions indicate that each event is likely to correspond to the opening and closing of a single pore of about 5 nm in diameter, the conductance of which ranges in the 100-nS scale. This combined experimental and theoretical investigation provides a better quantitative characterization of the size, conductance and lifetime of pores created during lipid bilayer electroporation. Such a molecular insight should enable better control and tuning of electroporation parameters for a wide range of biomedical and biotechnological applications.

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