Modeling of Transmembrane Potential in Realistic Multicellular Structures before Electroporation

Murovec, T.; Sweeney, Dan; Latouche, Eduardo L.; Davalos, Rafael V.; Brosseau, Christian

doi:10.1016/j.bpj.2016.10.005

Cited by 51 publications

(28 citation statements)

References 37 publications

(41 reference statements)

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“…The non-homogeneous sample conductivity could be addressed by applying, high-frequency bipolar pulse protocols (H-FIRE) which mitigate the impedance differences (Bhonsle et al, 2015; Sano et al, 2015) but unfortunately require delivery of higher energy than longer unipolar irreversible electroporation (IRE) pulses (Murovec et al, 2016; Sweeney et al, 2016). However, universal protocols, which allow countering or optimising all the limitations described above, are still not available (Pakhomova et al, 2011; Blumrosen et al, 2016; Yildirim et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Membrane permeabilization of mammalian cells using bursts of high magnetic field pulses

Novickij

Dermol

Grainys

et al. 2017

PeerJ

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BackgroundCell membrane permeabilization by pulsed electromagnetic fields (PEMF) is a novel contactless method which results in effects similar to conventional electroporation. The non-invasiveness of the methodology, independence from the biological object homogeneity and electrical conductance introduce high flexibility and potential applicability of the PEMF in biomedicine, food processing, and biotechnology. The inferior effectiveness of the PEMF permeabilization compared to standard electroporation and the lack of clear description of the induced transmembrane transport are currently of major concern.MethodsThe PEMF permeabilization experiments have been performed using a 5.5 T, 1.2 J pulse generator with a multilayer inductor as an applicator. We investigated the feasibility to increase membrane permeability of Chinese Hamster Ovary (CHO) cells using short microsecond (15 µs) pulse bursts (100 or 200 pulses) at low frequency (1 Hz) and high dB/dt (>106 T/s). The effectiveness of the treatment was evaluated by fluorescence microscopy and flow cytometry using two different fluorescent dyes: propidium iodide (PI) and YO-PRO®-1 (YP). The results were compared to conventional electroporation (single pulse, 1.2 kV/cm, 100 µs), i.e., positive control.ResultsThe proposed PEMF protocols (both for 100 and 200 pulses) resulted in increased number of permeable cells (70 ± 11% for PI and 67 ± 9% for YP). Both cell permeabilization assays also showed a significant (8 ± 2% for PI and 35 ± 14% for YP) increase in fluorescence intensity indicating membrane permeabilization. The survival was not affected.DiscussionThe obtained results demonstrate the potential of PEMF as a contactless treatment for achieving reversible permeabilization of biological cells. Similar to electroporation, the PEMF permeabilization efficacy is influenced by pulse parameters in a dose-dependent manner.

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Section: Introductionmentioning

confidence: 99%

Membrane permeabilization of mammalian cells using bursts of high magnetic field pulses

Novickij

Dermol

Grainys

et al. 2017

PeerJ

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“…At the microscopic cell level, an increase in pulse amplitude leads to an increase of the local electric field at a determined point of the tissue, with the corresponding increment of the TMP of the cells. As mentioned in Murovec et al, electroporation is possible when TMP exceeds a cell/tissue‐type dependent threshold. Thereby, at the cellular level, TMP is a commonly used parameter to quantify the influence of the pulse amplitude .…”

Section: Results Analysismentioning

confidence: 99%

“…As mentioned in Murovec et al, electroporation is possible when TMP exceeds a cell/tissue‐type dependent threshold. Thereby, at the cellular level, TMP is a commonly used parameter to quantify the influence of the pulse amplitude . At the macroscopic tissue level, the pulse amplitude can be quantified as the voltage level applied between plates (Δ V ) or as the corresponding average magnitude of electric field ( E av ), as related by

E_{av} = \frac{∆ V}{D},

where D represents the tissue thickness.…”

Section: Results Analysismentioning

confidence: 99%

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Simulation of the influence of voltage level and pulse spacing on the efficiency, aggressiveness and uniformity of the electroporation process in tissues using meshless techniques

Salazar

Arcila

Villa

2020

Numer Methods Biomed Eng

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Electroporation is a widely used method consisting of application of high‐voltage, short‐duration electric pulses to increase cell membrane permeability, allowing cellular internalization of medications. In this work, the influence of two primary parameters, voltage level (V) and pulse spacing (N), on electroporation efficiency, uniformity and aggressiveness, as quantified by the total mass transport to viable cells, intracellular concentration gradients and an aggressiveness factor introduced here, is studied by means of numerical simulations of drug transport in electroporated tissues. The global method of approximate particular solutions (Global MAPS) is used to solve the governing equations, together with domain scaling, singular value decomposition and smoothing algorithms, to address the ill‐conditioning of the final system and suppress small scale oscillations. The accuracy of Global MAPS is evaluated by comparing the initial extracellular concentration, Ce, and final intracellular concentration, Ci, with previous finite volume method results, obtaining similar behavior of Ce and Ci along the tissue domain, with some differences for Ci in high‐gradient zones. According to the Global MAPS results, the influence of V and N on Ci is only significant over a certain range, within which the largest drug transport to viable cells occurs. In general, both electroporation efficiency and aggressiveness change in nonuniform manner with V and decrease with N, whereas the electroporation uniformity decreases as V increases and N decreases. The contour plots obtained here can be considered useful tools to compare electroporation‐based treatments in terms of their efficiency, aggressiveness and uniformity, assisting in the selection of a suitable treatment plan for cancer.

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“…However, most of the existing numerical and analytical studies have tackled the modelling of this phenomenon based on various assumptions and constraints to predict and evaluate cell and tissue EP. [1][2][3][4][5][6][7][8][9][10][11][12][13][14] Typically, EP takes place when the transmembrane potential (TMP) exceeds a threshold V ep above which electrically conductive pores start forming in the membrane. [1][2][3] Experimental estimates for V ep fall in the range of 0.5-1.2 V but theoretical estimates point to V ep ¼ 0.258 V. 15 Most of the existing studies have so far assumed that cell membranes are rigid.…”

mentioning

confidence: 99%

Assessing the electro-deformation and electro-poration of biological cells using a three-dimensional finite element model

Shamoon

Dermol–Černe

Rems

et al. 2019

Applied Physics Letters

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In this Letter, we explore how cell electro-deformation and electro-poration are connected. We build a time-domain model of layered concentric shells (a model of biological cells) including their dielectric and elastic properties. We simulate delivery of one trapezoidal voltage pulse to either a single spherical cell or an assembly of three neighboring cells in a specific configuration and calculate cell deformation and pore formation. We describe the qualitative features of the electric field, surface charge density, transmembrane voltage, cell elongation, and pore density distribution at specific times i.e., before, during and after the application of the electric pulse and explore the correlations between them. Our results show that (1) the polarization charge redistribution plays a significant role in the spatial distribution of electrical stresses at μs time scales and (2) the cell deformation and pore density can be correlated with regions of high surface charge density. In future work, our model could be used for understanding basic mechanisms of electro-deformation and electro-poration with high-frequency short bipolar pulses of biological cells in suspension or tissues.

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Modeling of Transmembrane Potential in Realistic Multicellular Structures before Electroporation

Cited by 51 publications

References 37 publications

Membrane permeabilization of mammalian cells using bursts of high magnetic field pulses

Membrane permeabilization of mammalian cells using bursts of high magnetic field pulses

Simulation of the influence of voltage level and pulse spacing on the efficiency, aggressiveness and uniformity of the electroporation process in tissues using meshless techniques

Assessing the electro-deformation and electro-poration of biological cells using a three-dimensional finite element model

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