Low electric field parameters required to induce death of cancer cells

Irreversible electroporation (IRE) is a novel technique that deals with killing undesirable cells, mainly cancer cells, directly without using any cytotoxic drugs. Commonly in this technique very high electric field up to 1000?V/cm is used but for very short exposure time (nanoseconds). Low electric fields (LEFs) are used before to internalize molecules and drugs inside the cells (electroendocytosis) but mainly not in killing the cells. The aim of this work is to determine the ability of using LEFs to kill cancer cells (Hela cells). The Physics idea is in making LEFs energy equivalent to IRE energy. Four IRE protocols were selected to represent very high, high, moderate and mild voltages IRE, then we make equivalent energy for each of these protocols using different LEFs’ parameters of different amplitudes (7, 10, 14 and 20?V), different pulse numbers (40, 80, 160 and 320 pulses), different frequencies from 0.5 to 106.86?Hz and different pulse widths from 9.38 to 2000?ms. Each of the calculated LEF equivalent to IRE was applied on Hela cell line. The results show complete destruction of the cancer cells for all the tested exposure protocols. This damage was not due to thermal effect because the measured temperature was not changed before and after the exposure. The possible effect mechanism is discussed. It was concluded that the lethal effect on the cancer cells can be achieved using LEFs if the same energy equivalent to IRE is used. This work will help in using low-risk drug-free techniques in cancer treatment.     

INHIBITION OF EHRLICH TUMOR GROWTH IN MICE BY ELECTRIC INTERFERENCE THERAPY (IN VIVO STUDIES)

A study of solid tumor growth retardation by employing extremely low frequency (ELF) electric fields has been carried out. ELF electric fields were generated in tumor tissue in mice by the interference of two high frequency sinusoidal waves with the beat frequency centered at the tumor core. The results indicated a pronounced decrease in tumor growth rate in animals exposed to a 5-Hz interferential frequency for 1 hr daily. The 1 hr/day treatment produced a greater retardation effect than the 1 hr/week treatment. This indicates that treatment duration at the applied field frequency appears to play an important role in tumor growth delay. The dielectric properties of the tumor cells showed higher permittivity and conductivity values than homologous normal tissue. The permittivity of tumor cells treated daily with 5 Hz reaches nearly the same value as control tissue. Moreover, histological studies show that tumor tissues treated daily with the same frequency undergo partial regression and shrinkage of the aggregates of neoplastic cells leaving very little of them. We conclude that this new interferential technique is promising for tumor treatment in which a resonating electric field affects cell-to-cell communication.     

Cell-based screening for membranal and cytoplasmatic markers using dielectric spectroscopy

Dielectric spectroscopy (DS) of living biological cells is based on the analysis of the complex dielectric permittivity of cells suspended in a physiological medium. It provides knowledge on the polarization–relaxation response of cells to external electric field as function of the excitation frequency. This response is strongly affected by both structural and molecular properties of cells and therefore, can reveal rare insights on cell physiology and behaviour. This study demonstrates the mapping potential of DS after cytoplasmatic and membranal markers for cell-based screening analysis. The effect of membrane permittivity and cytoplasm conductivity was examined using tagged MBA and MDCK cell lines respectively. Comparing the permittivity spectra of tagged and native cell lines reveals clear differences between the analyzed suspensions. In addition, differences on the matching dielectric properties of cells were obtained. Those findings support the high distinction resolution and sensitivity of DS after fine molecular and cellular changes, and hence, highlight the high potential of DS as non invasive screening tool in cell biology research.     

Dielectric single cell spectra in snow algae

Single cell dielectric spectroscopy is introduced to investigate the passive electric properties of individual snow algal cells at different developmental stages. This non-destructive technique characterises the conductivities and permittivities of cell compartments, such as the cell wall, cytoplasm and membrane. To calculate the conductivities and permittivities in a quantitative manner, multi-shelled models are introduced. Dielectric spectra of snow algae are determined by the cell wall which has been found to have an extremely low permittivity of 3–5. Very likely this is a consequence of the high content of Al-Fe silicates and a low water content. Compared with cells and protoplasts of higher plants, the cell interior has a lower internal conductivity. Received: 20 May 1997 / Accepted: 11 May 1998     

MyDEP: A New Computational Tool for Dielectric Modeling of Particles and Cells

Dielectrophoresis (DEP) and electrorotation (ROT) are two electrokinetic phenomena exploiting nonuniform electric fields to exert a force or torque on biological particles suspended in liquid media. They are widely used in lab-on-chip devices for the manipulation, trapping, separation, and characterization of cells, microorganisms, and other particles. The DEP force and ROT torque depend on the respective polarizabilities of the particle and medium, which in turn depend on their dielectric properties and on the field frequency. In this work, we present a new software, MyDEP, which implements several particle models based on concentric shells with adjustable dielectric properties. This tool enables the study of the variation in DEP and ROT spectra according to different parameters, such as the field frequency and medium conductivity. Such predictions of particle behavior are very useful for choosing appropriate parameters in DEP experiments. The software also enables the study of the homogenized properties of spherical or ellipsoidal multishell particles and provides a database containing published cell properties. Equivalent electrical conductivity and relative permittivity of the cell alone and in suspension can be calculated. The software also offers the ability to create graphs of the evolution of the crossover frequencies with the electric field frequency. These graphs can be directly exported from the software.     

Dielectric Properties of Normal and Metastatic Lymph Nodes Ex Vivo From Lung Cancer Surgeries

The dielectric properties of normal and tumor human tissues have been widely reported in recent years. However, the dielectric properties of intrathoracic lymph nodes (LNs) have not been reported. In this communication, we measured the dielectric properties (i.e., permittivity and conductivity) of ex vivo intrathoracic LNs obtained from lung cancer surgeries. Results show that the permittivity and conductivity of metastatic LNs are higher than those of normal LNs over the frequency range of 1 MHz–4 GHz. Statistically significant differences are observed at single specific frequencies (64, 128, 298, 433, and 915 MHz and 2.45 GHz). Our study provides the basic data to support future-related research and fills the research gap on the dielectric properties of LNs in the lungs. Bioelectromagnetics. 2020;41:148–155. © 2020 Bioelectromagnetics Society.     

Apparatus for the electrical characterisation of conductive fluids

Non-invasive and fully automated conductimetric measurements of electrolyte and bacterial samples were achieved in a closed volume test cell, comprising a magnetic field coil and detector. By monitoring field induced currents in sample electrolytes the magnitude of the sample current was shown to vary as the inverse of the sample impedance. The impedance characteristic was shown to be that of an LCR resonant circuit. This characteristic is primarily a function of the applied frequency and the solution/cell properties being dependent on the solution conductivity and dielectric permittivity at any given concentration. Small changes in sample dielectric permittivity in the presence of a large background conductivity are shown to be significant.The apparatus described can provide fixed or swept frequency conductivity measurements in the range 1 kHz to 2.25 MHz with a lower conductivity sensitivity of 0.9 × 10⁻³ Scm⁻¹. Bulk impedimetric characteristics of cell suspensions are derived by a two stage measurement.     

Citric Acid Fermentation

Abstract

Dielectrophoresis is the motion of particles caused by electrical polarization effects in inhomogeneous (nonuniform) electric fields. Unlike electrophoresis, the particles do not require a net electrical charge for motion to occur and AC rather than DC fields are employed to exploit the dielectric properties of the particles. Factors controlling the effective dielectric properties of cells and microorganisms include electrical double layers associated with surface charges, the conductivity and permittivity of their membranes and any cell walls, and their morphologies and structural architectures. In recent years, several laboratories have developed separation and manipulation techniques for cells and microorganisms based on dielectrophoresis, using both static and traveling AC fields. In this article, the basic physical factors influencing the dielectrophoretic behavior of particles are outlined, and ways in which these can be employed to achieve selective separation of cells and microorganisms are described.     

Reaction of 3-ethoxy-2-oxobutyraldehyde bis(thiosemicarbazonato) Cu(II) with Ehrlich cells. Binding of copper to metallothionein and its relationship to zinc metabolism and cell proliferation

The copper complex of 3-ethoxy-2-oxobutyraldehyde bis(thiosemicarbazone) or CuKTS is reduced and dissociated upon reaction with Ehrlich cells. Titration of the cells with the complex leads to the specific binding of copper to metallothionein with 1 to 1 displacement of its complement of zinc. Under conditions of complete titration of metallothionein, 1.25-2.5 nmol CuKTS/10(7) cells, cellular DNA synthesis is rapidly inhibited but no long term effects on cell proliferation are observed. The kinetics of redistribution of Cu and Zn in Ehrlich cells in culture and in animals were studied after pulse reaction of CuKTS with cells. After exposure of cells to the noncytotoxic concentration of 2.5 nmol of CuKTS/10(7) cells, nonmetallothionein bound copper is lost rapidly from the cells, after which copper in metallothionein decays. New zinc metallothionein is made as soon as exposed cells are placed in culture. New synthesis stops when the level of zinc in metallothionein reaches control levels. A second pulse treatment of cells with CuKTS to displace zinc from metallothionein again stimulates new synthesis of the protein to restore its normal concentration. The kinetics of metal metabolism in Ehrlich cells exposed to 5.5 nmol of CuKTS/10(7) cells, which inhibits cell proliferation, are qualitatively similar except there is a pronounced lag before new zinc metallothionein is synthesized. The Ehrlich ascites tumor in mice responds to CuKTS similarly to cells in culture. It is also shown that cultured Ehrlich cells do not make extra zinc metallothionein in the presence of high levels of ZnCl2, and fail to accumulate copper in the presence of large concentrations of CuCl2.     

有限元法计算各向异性介质球头模型电位分布

在脑电正问题研究中,脑神经元所产生的电活动可用电流偶极子来模拟.本文提出把大脑看作各向异性介质球,即同时考虑电容效应、电导效应对脑内电流偶极子产生的电位的影响,并用有限元法推导出偶极子在各向异性介质球模型中的电位分布计算公式.结果表明介质的电容效应对电位分布是有影响的,反映了大脑活组织电特性,对外来不同频率的信号刺激有不同的响应.同时有限元法对大脑内某一区域内电位分布求解表明,测量较深层组织的电特性变化敏感的特点,可获得更多的测量信息.     

Usefulness of ficoll in electric field-mediated cell fusion

Electrofusion is a technique that enables the production of new cell types with desired properties to be done. Ehrlich ascites tumor cells are fused by means of an electric field. Under too harsh external field strength or pulse length conditions, however, membrane breakdown leads to a loss of cellular cytoplasm. Addition of the high polymer Ficoll to the fusion medium increases its density and osmotic pressure, thus preventing cytoplasm from running out and, therefore, maintaining cell viability. Fusion between cells of different sizes is made possible or facilitated by means of Ficoll, as big cells do not lose their cytoplasm under conditions required for enhancing membrane permeability of the small cells. In presence of the proteolytic enzyme pronase, addition of Ficoll to the fusion medium further raises the fusion percentage compared to the exclusive addition of pronase. The fusion of cells of different densities is also greatly facilitated and its percentage increased by addition of Ficoll, thus obviating the necessity to perform electrofusion under conditions of microgravity.     

Estimation of the physical properties of neurons and glial cells using dielectrophoresis crossover frequency

We successfully determine the ranges of dielectric permittivity, cytoplasm conductivity, and specific membrane capacitance of mouse hippocampal neuronal and glial cells using dielectrophoresis (DEP) crossover frequency (CF). This methodology is based on the simulation of CF directly from the governing equation of a dielectric model of mammalian cells, as well as the measurements of DEP CFs of mammalian cells in different suspension media with different conductivities, based on a simple experimental setup. Relationships between the properties of cells and DEP CF, as demonstrated by theoretical analysis, enable the simultaneous estimation of three properties by a straightforward fitting procedure based on experimentally measured CFs. We verify the effectiveness and accuracy of this approach for primary mouse hippocampal neurons and glial cells, whose dielectric properties, previously, have not been accurately determined. The estimated neuronal properties significantly narrow the value ranges available from the literature. Additionally, the estimated glial cell properties are a valuable addition to the scarce information currently available about this type of cell. This methodology is applicable to any type of cultured cell that can be subjected to both positive and negative dielectrophoresis.     

间断性低氧对大鼠腓肠肌介电性能的影响

目的：在40Hz～110MHz频率范围观察间断性低氧暴露4周大鼠离体腓肠肌细胞介电性能的改变。方法：采用低压氧舱建立模拟低氧模型,雄性SD大鼠随机分为间断低氧组和正常对照组。利用Agilent 4294A阻抗分析仪测量了离体大鼠腓肠肌的交流阻抗,通过频域介电谱、Cole—Cole图、介电损耗因子频谱、电导率虚部频谱和介电损耗角正切频谱的数据分析,观察间断性低氧暴露对大鼠离体腓肠肌细胞介电性能的影响。结果：间断性低氧暴露4周大鼠腓肠肌的介电常数（εL,εh）降低,介电增量△ε减小,绝缘性降低;低频电导率κL升高,高频电导率κh降低,电导率增量△κ降低;特征频率（f1,f2）增加;介电损失峰值ε”peak、电导率虚部峰值κ”peak和损耗角正切峰值婶谳均降低。结论：间断性低氧暴露致骨骼肌细胞介电性能降低,但其特征频率增加。     

Complex Dielectric Properties of Sulfate-Reducing Bacteria Suspensions

Sulfate-reducing bacteria (SRB) can potentially enhance the remediation of heavy metals in the subsurface. Previous geophysical research has demonstrated the sensitivity of electrical measurements to SRB-mediated mineral transformation in porous media. However, the inherent dielectric properties of SRB and their direct contribution to the electrical properties of porous media are poorly understood. We studied the complex dielectric properties of SRB (Desulfovibrio vulgaris) suspensions at different concentrations and at different growth stages using a two-electrode dielectric spectroscopy measurement over the frequency range of 20 Hz to 1 MHz. Our results show higher dielectric responses (relative dielectric permittivity, real and imaginary conductivity) occurred with higher bacteria concentration at frequencies <10 kHz. Additionally, permittivity and conductivity both decreased as cells aged from mid-log phase to late stationary phase. Our results suggest that dielectric spectroscopy measurements can be used to noninvasively monitor biomass and various growth stages of SRB. Our work advances the interpretation of electrical signals associated with SRB observed in the subsurface.     

The effect of polycations on cell membrane stability and transport processes

Summary The interaction of poly-l-lysines of different molecular weights (PL) with Ehrlich ascites tumor cells was studied experimentally with respect to cell surface binding, cell electrophoresis, cytotoxicity and membrane permeability. Although they decrease the net negative charge of Ehrlich ascites cells similarly at low PL concentrations, low molecular weight PL was less cytotoxic and less damaging to the potassium transport mechanism than was high molecular weight PL. At certain PL concentrations, membrane damage was reversible on reincubation in PL-free media. The amount of bound polylysine as determined with fluorescent labeled polylysine was compared by electrophoresis to the amount of polylysine expressed on the electrokinetic surface. The results indicated that only a small fraction of polylysine bound to Ehrlich ascites tumor cells was electrokinetically detectable. The adsorption of polylysine to Ehrlich ascites tumor cells was not describable by the usual adsorption isotherms. It is suggested that the same number of monomeric lysine units of high and low molecular weight PL are adsorbed at the cell electrokinetic surface, but cytotoxicity is dependent on molecular weight. Although the negative charge of human red blood cells could be reversed at low PL concentrations, no such effect could be observed for ELD (a subline of Ehrlich ascites carcinoma) cells even at high PL concentrations. The relationship of PL binding to the stimulation of macromolecular uptake is discussed.     

Electroendocytosis Is Driven by the Binding of Electrochemically Produced Protons to the Cell’s Surface

Electroendocytosis involves the exposure of cells to pulsed low electric field and is emerging as a complementary method to electroporation for the incorporation of macromolecules into cells. The present study explores the underlying mechanism of electroendocytosis and its dependence on electrochemical byproducts formed at the electrode interface. Cell suspensions were exposed to pulsed low electric field in a partitioned device where cells are spatially restricted relative to the electrodes. The cellular uptake of dextran-FITC was analyzed by flow cytometery and visualized by confocal microscopy. We first show that uptake occurs only in cells adjacent to the anode. The enhanced uptake near the anode is found to depend on electric current density rather than on electric field strength, in the range of 5 to 65 V/cm. Electrochemically produced oxidative species that impose intracellular oxidative stress, do not play any role in the stimulated uptake. An inverse dependence is found between electrically induced uptake and the solution’s buffer capacity. Electroendocytosis can be mimicked by chemically acidifying the extracellular solution which promotes the enhanced uptake of dextran polymers and the uptake of plasmid DNA. Electrochemical production of protons at the anode interface is responsible for inducing uptake of macromolecules into cells exposed to a pulsed low electric field. Expanding the understanding of the mechanism involved in electric fields induced drug-delivery into cells, is expected to contribute to clinical therapy applications in the future.     

Dielectrophoretic analysis of microbes in water

Traditional microbiological methods are still used extensively for analysis of micro-organisms in water. However, they are inefficient due to a high labour input requirement, a low sample capacity, and often a long time lag before results are available. Analytical stages involving incubation and growth (enrichments and colony isolation) contribute the greatest delay in reporting, although subsequent identification can also be protracted. The use of electrometric growth analysers (measuring impedance, conductance or capacitance changes) is now more common in water microbiology. Although these instruments can provide more rapid results and provide increased handling capacity, the bacterial generation times required to provide detectable changes cause delays and suitable selective media are not fully developed for all microbes of interest. Most other recent methods have equally disappointing drawbacks and thus extensive research continues in order to realise the ambition of 'real-time' analytical microbiology. Several research groups have demonstrated the potential of dielectrophoresis in providing microbial concentration, separation and identification systems which are not limited by bacterial growth and are therefore extremely rapid. Dielectrophoresis occurs when cells are placed in non-uniform electric fields. The cells move towards the electrodes (regardless of the direction of the applied field) as determined by their dielectric properties (conductivity and permittivity) rather than by their charge as occurs in electrophoresis. Also, the polarisability of the cells, and therefore the polarity and magnitude of the dielectrophoretic force, varies as a function of the electric field frequency. Because the dielectric properties of a particular cell type have characteristic frequency-dependent components, if cell collection at electrodes is observed across a frequency range, the collection spectrum produced is distinctive for the cell type under investigation. This can be exploited for analytical and separation applications in microbiology. This paper will describe rapid analytical techniques based on electrokinetic phenomena under research and development at York. These include dielectrophoretic enrichment, concentration and characterisation systems for the analysis of water bacteria and protozoa.     

Reliable Method for Fabricating Tissue‐Mimicking Materials With Designated Relative Permittivity and Conductivity at 128 MHz

Artificial materials that can simultaneously mimic the relative permittivity and conductivity of various human tissues are usually used in medical applications. However, the method of precisely designing these materials with designated values of both relative permittivity and conductivity at 3 T MRI resonance frequency is lacking. In this study, a reliable method is established to determine the compositions of artificial dielectric materials with designated relative permittivity and conductivity at 128 MHz. Sixty dielectric materials were produced using oil, sodium chloride, gelatin, and deionized water as the main raw materials. The dielectric properties of these dielectric materials were measured using the open‐ended coaxial line method at 128 MHz. Nonlinear least‐squares Marquardt–Levenberg algorithm was used to obtain the formula, establishing the relationship between the compositions of the dielectric materials and their dielectric properties at 128 MHz. The dielectric properties of the blood, gall bladder, muscle, skin, lung, and bone at 128 MHz were selected to verify the reliability of the obtained formula. For the obtained formula, the coefficient of determination and the expanded uncertainties with a coverage factor of k = 2 were 0.991% and 4.9% for relative permittivity and 0.992% and 6.4% for conductivity. For the obtained artificial materials measured using the open‐ended coaxial line method, the maximal difference of relative permittivity and conductivity were 1.0 and 0.02 S/m, respectively, with respect to the designated values. In conclusion, the compositions of tissue‐mimicking material can be quickly determined after the establishment of the formulas with the expanded uncertainties of less than 10%. Bioelectromagnetics. 2021;42:86–94. © 2020 Bioelectromagnetics Society.     

Dielectric and electric properties of synthetic melanin: the effect of europium ions

Detailed studies on dielectric and electric properties of synthetic pirocatechol and indolederived melanin, pure and doped with Eu³⁺, have been performed, D.C. and a.c. electrical conductivity as well as dielectric permittivity and loss angle tg have been investigated. Activation energy of d.c. conductivity for the investigated temperature range (0°C3+ doped to the samples do not influence the values of activation energy, but the addition of Eu³⁺ ions decreases the conductivity values. On the basis of depolarization current curves the energy of trap level referred to Eu³⁺ has been calculated. It equals 0.58 eV for pirocatechol and 0.60 eV for indolemelanin.     

Dielectric behavior of the frog lens in the 100 Hz to 500 MHz range. Simulation with an allocated ellipsoidal-shells model.

In an attempt to correlate the passive electrical properties of the lens tissue with its structure, we measured ac admittances for isolated frog lenses, lens nuclei, and homogenate of cortical fiber cells, over the frequency range 10(2)-5.10(8) Hz. The whole lenses molded into discoid shape show a characteristic "two-step" dielectric dispersion with a huge permittivity increment of the order of 10(5) at 1 kHz. Of the two subdispersions disclosed, dispersion 1 has a permittivity increment (delta epsilon) of 2.10(5) with a characteristic frequency (fc) of 2 kHz, and dispersion 2 has a delta epsilon of 400 with an fc of 2 MHz. In terms of loss tangent, these dispersions are more clearly located as two separate peaks. Data are analyzed using an allocated ellipsoidal-shells model which has been developed by taking into account fiber orientation inside the lens tissue. Dispersion 1 is assigned to the equatorial cortex, where fiber cells run parallel to the applied electric field, and dispersion 2 to the nucleus with a complex fiber arrangement and also to the polar cortex, in which the fiber alignment is predominantly perpendicular. In addition, the model analysis reveals that, in the frog lens, the nucleus occupies approximately 30% in volume and that relative permittivity and conductivity for the cell interior are, respectively, 45 and 3 mS/cm for the cortical cells, and 28 and 0.3 mS/cm for the nuclear cells.