Effect of different low electric field conditions on the dielectric properties of Ehrlich tumor

Studies of low electric fields (LEFs) effects on the permeability of the cell membrane are of great interest in molecular medicine. Electroendocytosis is a novel technique depends on using LEFs to incorporate macromolecules as anticancer drugs or genes into the cells. There are wide debates about the optimum electric conditions for electroendocytosis. In this article, Ehrlich tumor tissues were exposed to different LEFs voltages and frequencies in vitro. Dielectric properties before and after the exposure were determined. The results indicated that the exposed groups have significant high permittivity and conductivity compared to unexposed group, as well as having significant low impedance. The results indicated that dielectric measurements can be used to indicate the efficiency of electroendocytosis that as permittivity and conductivity of cell membranes increase, more molecules can passed into the cells. It was also indicated that, as the pulse amplitude increases, the LEFs influence increases, while changing pulse frequency has no obvious effect on dielectric properties of Ehrlich tumor.     

Optimization of Electrotransfection Conditions of Mammalian Cells with Different Biological Features

We introduced eukaryotic expression plasmid pEGFP-N1 encoding green fluorescent protein (GFP) genes into cells with different biological features through electroporation. The effects of conditions, including voltage, capacitor flow, pulse cycle, DNA dosage and buffer, on transfection efficiency were investigated based on fluorescent microscopy and posttransfection survival rate of cells by staining with trypan blue. Better electrotransfection outcomes were achieved in the following epithelial cells: Vero cells at 300?V/850???F, PK15 cells at 300?V/500???F, MDCK cells at 200?V/600???F, F81 cells at 200?V/500???F, cancer cells MB49 at 300?V/400???F, Hela cells at 200?V/450???F, HF-29 cells at 300?V/800???F and B16F1 cells at 200?V/650???F. Among fibroblast cells, better electrotransfection was achieved in BHK21 cells at 300?V/600???F and ST cells at 200?V/750???F. RPMI-1640 medium without antibiotics and serum demonstrated higher electrotransfection efficiency and cell survival rate than other cell culture media as electroporation buffer. Our findings further prove that electroporation transfection is an effective method for genetic transfection. Cells with different biological features require varying transfection conditions to obtain higher transfection efficiency of target genes.     

A Numerical Investigation of the Electric and Thermal Cell Kill Distributions in Electroporation-Based Therapies in Tissue

Electroporation-based therapies are powerful biotechnological tools for enhancing the delivery of exogeneous agents or killing tissue with pulsed electric fields (PEFs). Electrochemotherapy (ECT) and gene therapy based on gene electrotransfer (EGT) both use reversible electroporation to deliver chemotherapeutics or plasmid DNA into cells, respectively. In both ECT and EGT, the goal is to permeabilize the cell membrane while maintaining high cell viability in order to facilitate drug or gene transport into the cell cytoplasm and induce a therapeutic response. Irreversible electroporation (IRE) results in cell kill due to exposure to PEFs without drugs and is under clinical evaluation for treating otherwise unresectable tumors. These PEF therapies rely mainly on the electric field distributions and do not require changes in tissue temperature for their effectiveness. However, in immediate vicinity of the electrodes the treatment may results in cell kill due to thermal damage because of the inhomogeneous electric field distribution and high current density during the electroporation-based therapies. Therefore, the main objective of this numerical study is to evaluate the influence of pulse number and electrical conductivity in the predicted cell kill zone due to irreversible electroporation and thermal damage. Specifically, we simulated a typical IRE protocol that employs ninety 100-µs PEFs. Our results confirm that it is possible to achieve predominant cell kill due to electroporation if the PEF parameters are chosen carefully. However, if either the pulse number and/or the tissue conductivity are too high, there is also potential to achieve cell kill due to thermal damage in the immediate vicinity of the electrodes. Therefore, it is critical for physicians to be mindful of placement of electrodes with respect to critical tissue structures and treatment parameters in order to maintain the non-thermal benefits of electroporation and prevent unnecessary damage to surrounding healthy tissue, critical vascular structures, and/or adjacent organs.     

Magnetic fields with frequency of 217 Hz can reduce cell apoptosis caused by electrochemotherapy

Nowadays, due to the wide use of mobile phones, extensive studies have been carried out on the effects of magnetic field (MF) on public health. In this paper, we study the effect of 217 Hz MF similar to that generated by GSM900 mobile phones on cancer and healthy cells treated with electric pulse and cytotoxic drug. The experiments conducted include exposure to (a) electric pulses alone (4000 square-wave electric pulses with low amplitude of 70 V/cm and frequency of 5 kHz), (b) electric pulses following MF exposure, (c) electrochemotherapy (electric pulses and cytotoxic drug) alone and (d) MF exposure with subsequent electrochemotherapy. The results indicate that the percentage of apoptosis decreases significantly (p < 0.05) in treatment groups using electrochemotherapy after MF exposure compared to that in treatment groups using electrochemotherapy alone. We observed that 217 Hz MF similar to that generated by GSM900 mobile phones can incur resistance of the cells in response to electric pulses. Our findings implied the existence of amplitude window effect in alternations induced by extremely low-frequency MF.     

A statistical model for multidimensional irreversible electroporation cell death in tissue

Background  

Irreversible electroporation (IRE) is a minimally invasive tissue ablation technique which utilizes electric pulses delivered by electrodes to a targeted area of tissue to produce high amplitude electric fields, thus inducing irreversible damage to the cell membrane lipid bilayer. An important application of this technique is for cancer tissue ablation. Mathematical modelling is considered important in IRE treatment planning. In the past, IRE mathematical modelling used a deterministic single value for the amplitude of the electric field required for causing cell death. However, tissue, particularly cancerous tissue, is comprised of a population of different cells of different sizes and orientations, which in conventional IRE are exposed to complex electric fields; therefore, using a deterministic single value is overly simplistic.     

Facilitation of electroporative drug uptake and cell killing by electrosensitization

Cell permeabilization by electric pulses (EP), or electroporation, is widely used for intracellular delivery of drugs and plasmids, as well as for tumour and tissue ablation. We found that cells pre‐treated with 100‐μs EP develop delayed hypersensitivity to subsequent EP applications. Sensitizing B16 and CHO cells by splitting a single train of eight 100‐μs EP into two trains of four EP each (with 5‐min. interval) decreased the LD₅₀ 1.5–2 times. Sensitization profoundly enhanced the electroporation‐assisted uptake of bleomycin, a cell‐impermeable cytotoxic agent accepted for killing tumours by electrochemotherapy. EP exposures that were not lethal per se caused cell death in the presence of bleomycin and proportionally to its concentration. Sensitizing cells by a split‐dose EP exposure increased bleomycin‐mediated lethality to the same extent as a 10‐fold increase in bleomycin concentration when using a single EP dose. Likewise, sensitization by a split‐dose EP exposure (without changing the overall dose, pulse number, or amplitude) enhanced the electroporative uptake of propidium up to fivefold. Enhancement of the electroporative uptake appears a key mechanism of electrosensitization and may benefit electrochemotherapy and numerous applications that employ EP for cell permeabilization.     

A Three-Dimensional In?Vitro Tumor Platform for Modeling Therapeutic Irreversible Electroporation

Irreversible electroporation (IRE) is emerging as a powerful tool for tumor ablation that utilizes pulsed electric fields to destabilize the plasma membrane of cancer cells past the point of recovery. The ablated region is dictated primarily by the electric field distribution in the tissue, which forms the basis of current treatment planning algorithms. To generate data for refinement of these algorithms, there is a need to develop a physiologically accurate and reproducible platform on which to study IRE in vitro. Here, IRE was performed on a 3D in vitro tumor model consisting of cancer cells cultured within dense collagen I hydrogels, which have been shown to acquire phenotypes and respond to therapeutic stimuli in a manner analogous to that observed in in vivo pathological systems. Electrical and thermal fluctuations were monitored during treatment, and this information was incorporated into a numerical model for predicting the electric field distribution in the tumors. When correlated with Live/Dead staining of the tumors, an electric field threshold for cell death (500 V/cm) comparable to values reported in vivo was generated. In addition, submillimeter resolution was observed at the boundary between the treated and untreated regions, which is characteristic of in vivo IRE. Overall, these results illustrate the advantages of using 3D cancer cell culture models to improve IRE-treatment planning and facilitate widespread clinical use of the technology.     

Effects of pulsed electric fields on mouse spleen lymphocytes in vitro

The effects of pulsed electric fields on cell membranes were investigated. In vitro exposure of mouse splenocytes to a single high-voltage pulse resulted in an increase in membrane permeability that was dependent on both the electric field strength and the pulse duration. Exposure to a 2 μs, 3.0 kV/cm pulse resulted in the induction of a 1.26 V transmembrane potential, and elicited a 50% loss of intracellular K⁺. These results are in agreement with previous studies of the effects of pulsed electric fields on erythrocytes and microorganisms. The effect of pulsed electric fields on the functional integrity of lymphocytes was i vestigated by measuring [³H]thymidine incorporation by cells cultured in the presence and absence of various mitogens following exposure to an electrical pulse. No statistically significant effects on the response of mouse spleen lymphocytes to concanavalin A, phytohemagglutinin or lipopolysaccharide were observed following exposure to 2 μs electric pulses at amplitudes of up to 3.5 kV/cm. Exposure to a single 10 μs pulse of 2.4–3.5 kV/cm produced a statistically significant reduction in the response of lymphocytes to lipopolysaccharide stimulation that was attributed to cell death.     

Differential effects in cells exposed to ultra-short, high intensity electric fields: cell survival, DNA damage, and cell cycle analysis

High power, nanosecond pulsed electric field (nsPEF) effects have been focused on bacterial decontamination, but the impact on mammalian cells is now being revealed. During nsPEF applications, electrical pulses of 10, 60 or 300 ns durations were applied to cells using electric field amplitudes as high as 300 kV/cm. Because of the ultra-short pulse durations, the energy transferred to cells is negligible, and only non-thermal effects are observed. We investigated the genotoxicity of nsPEF on adherent and non-adherent cell lines including 10 human lines and one mouse cell line with different origin and growth characteristics. We present data examining the effects of nsPEF exposure on cell survival assessed by clonogenic formation or live cell count; DNA damage determined by the comet assay and chromosome aberrations; and cell cycle parameters by measuring the mitotic indices of exposed cells. Using each of these indicators, we observed differential effects among cell types with non-adherent cells being more sensitive to the genotoxic effects of nsPEF exposures than adherent cells. Non-adherent cultures showed a rapid decrease in cell viability (90%), induction of DNA damage, and a decrease in the number of cells reaching mitosis after one 60 ns pulse with an electric field intensity of 60 kV/cm. These effects were not observed in cells grown as adherent cultures, with the exception of the mouse 3T3 cell line, which showed survival characteristics similar to non-adherent cultures. These data suggest that nsPEF genotoxicity may be cell type specific, and therefore have potential applications in the selective removal of one cell type from another, for example, in diseased states.     

Effects of exposure protocols on induction of kinetochore-plus and -minus micronuclei by arsenite in diploid human fibroblasts.

Arsenic, widely distributed in the environment, is a potent human carcinogen. Arsenite genotoxicity has been observed in a variety of cells and animal systems. However, the underlying mechanism is not completely clear. In this study, human fibroblasts (HFW) were treated with 1.25-10 microM arsenite for 24 h (low dose and long exposure) and 5-80 microM for 4 h (high dose and short exposure), and the arsenite accumulation, cytotoxicity, and micronucleus (MN) induction were examined. By these two different protocols, HFW cells showed equivalent levels of arsenite accumulation, but exhibited different kinetics of cell killing and different types of MN generation. Arsenite induced mainly kinetochore-positive MN (K+-MN) in HFW cells by low dose exposure whereas mainly kinetochore-negative MN (K--MN) was induced by high dose exposure. Catalase reduced both K+- and K--MN induced by these two exposure protocols. Except for the case of K+-MN induction by the high dose exposure protocol, N-acetyl-cysteine (NAC) in both low and high dose protocols was also shown to effectively reduce arsenite-induced MN. The present results imply that oxidative stress is involved in arsenite-induced MN in diploid human fibroblasts. However, different protocols for arsenite exposure may result in different cellular damage.     

5-氟尿嘧啶增强HeLa细胞对自然杀伤细胞敏感性研究

目的用5-氟尿嘧啶（5-fluorouracil,5-FU）处理HeLa细胞,检测其NKG2D配体MICA的表达及其对NK92细胞杀伤敏感性的变化。方法不同浓度的5-Fu处理HeLa细胞,在不同时间点用半定量PCR及流式细胞术检测HeLa细胞表面的NKG2D配体MICA在RNA及蛋白水平的表达变化情况,用MTT法检测NKG2D抗体封闭NK92细胞的NKG2D受体前后,NK92细胞对HeLa细胞的杀伤作用。结果不同浓度的5．Fu作用于HeLa细胞后,半定量RT—PCR结果显示MICA表达随5-Fu作用浓度增加逐渐增高。而且40μg／ml5．Fu作用于HeLa细胞后随着作用时间的延长（0、8、16、24h）MICA表达增加,流式细胞术检测结果表明,MICA表达的增加主要依赖于未凋亡细胞的MICA表达。在40μg／ml5-FU作用24h,效靶比为2．5：1,5：1,10：1,20：1时都检测到NK92细胞对HeLa细胞的杀伤增强,杀伤作用可部分被NKG2D抗体抑制。结论5-FU能够上调HeLa细胞表面NKG2D配体MICA的表达,增强HeLa细胞对NK92细胞的敏感性,提示化疗联合NK细胞免疫治疗宫颈癌可产生协同作用,提高治疗效果。     

Effect of external electric current on adsorption of lead by Penicillium polonicum

Abstract

Lead is a major source of environmental pollution that has recently been the focus of a great deal of research. Bioremediation has been shown to be effective in remediation of lead pollution. Penicillium polonicum is a fungus with highly efficient adsorption of lead. In this study, the influence of electric current on the growth characteristics and adsorption of lead by the strain were investigated through applying different external voltages (1.5, 1.25, 1.0, 0.75, and 0.5?V). The results indicated that the electric current with voltage ranges from 1.0 to 1.25?V could promote the adsorption of lead. In addition, morphological characteristics and the quantity of lead-containing minerals formed on the surface of P. polonicum differed greatly under different experimental conditions. Further, the electric current intensity and electric energy consumption at voltages of 1.0, 1.25, and 1.5?V were higher than the blank control group, suggesting that the strain could utilize the energy supplied by an external electrochemical workstation to improve lead adsorption. After applying an external current, the lead adsorption of P. polonicum was affected by electric current changing the growth environment of the fungus and the electron transfer reaction between electrodes and P. polonicum.     

Differences in the electric birefringence of spectrin dimers and tetramers as shown by the fast reversing electric pulse method

The electric birefringence of purified Spectrin has been examined in medium of low ionic strength ai 20°C and for electric fields smaller than 4 × 10⁴ V m^?1. using the reversing electric pulse method. This technique allows study of the permanent and induced dipole electric moment of macromolecules more easily than in measurements using only rectangular pulses. We show that spectrin heterodimers and heterotetramers have different electro-optical properties. The relaxation time of the tetramer (7 μs) is significantly longer than that of the dimer (4.5 μs). Tetramers and dimers have also different polarizability parameters.     

High-frequency irreversible electroporation (H-FIRE) for non-thermal ablation without muscle contraction

Background

Therapeutic irreversible electroporation (IRE) is an emerging technology for the non-thermal ablation of tumors. The technique involves delivering a series of unipolar electric pulses to permanently destabilize the plasma membrane of cancer cells through an increase in transmembrane potential, which leads to the development of a tissue lesion. Clinically, IRE requires the administration of paralytic agents to prevent muscle contractions during treatment that are associated with the delivery of electric pulses. This study shows that by applying high-frequency, bipolar bursts, muscle contractions can be eliminated during IRE without compromising the non-thermal mechanism of cell death.

Methods

A combination of analytical, numerical, and experimental techniques were performed to investigate high-frequency irreversible electroporation (H-FIRE). A theoretical model for determining transmembrane potential in response to arbitrary electric fields was used to identify optimal burst frequencies and amplitudes for in vivo treatments. A finite element model for predicting thermal damage based on the electric field distribution was used to design non-thermal protocols for in vivo experiments. H-FIRE was applied to the brain of rats, and muscle contractions were quantified via accelerometers placed at the cervicothoracic junction. MRI and histological evaluation was performed post-operatively to assess ablation.

Results

No visual or tactile evidence of muscle contraction was seen during H-FIRE at 250 kHz or 500 kHz, while all IRE protocols resulted in detectable muscle contractions at the cervicothoracic junction. H-FIRE produced ablative lesions in brain tissue that were characteristic in cellular morphology of non-thermal IRE treatments. Specifically, there was complete uniformity of tissue death within targeted areas, and a sharp transition zone was present between lesioned and normal brain.

Conclusions

H-FIRE is a feasible technique for non-thermal tissue ablation that eliminates muscle contractions seen in IRE treatments performed with unipolar electric pulses. Therefore, it has the potential to be performed clinically without the administration of paralytic agents.     

7.0-T Magnetic Resonance Imaging Characterization of Acute Blood-Brain-Barrier Disruption Achieved with Intracranial Irreversible Electroporation

The blood-brain-barrier (BBB) presents a significant obstacle to the delivery of systemically administered chemotherapeutics for the treatment of brain cancer. Irreversible electroporation (IRE) is an emerging technology that uses pulsed electric fields for the non-thermal ablation of tumors. We hypothesized that there is a minimal electric field at which BBB disruption occurs surrounding an IRE-induced zone of ablation and that this transient response can be measured using gadolinium (Gd) uptake as a surrogate marker for BBB disruption. The study was performed in a Good Laboratory Practices (GLP) compliant facility and had Institutional Animal Care and Use Committee (IACUC) approval. IRE ablations were performed in vivo in normal rat brain (n = 21) with 1-mm electrodes (0.45 mm diameter) separated by an edge-to-edge distance of 4 mm. We used an ECM830 pulse generator to deliver ninety 50-μs pulse treatments (0, 200, 400, 600, 800, and 1000 V/cm) at 1 Hz. The effects of applied electric fields and timing of Gd administration (−5, +5, +15, and +30 min) was assessed by systematically characterizing IRE-induced regions of cell death and BBB disruption with 7.0-T magnetic resonance imaging (MRI) and histopathologic evaluations. Statistical analysis on the effect of applied electric field and Gd timing was conducted via Fit of Least Squares with α = 0.05 and linear regression analysis. The focal nature of IRE treatment was confirmed with 3D MRI reconstructions with linear correlations between volume of ablation and electric field. Our results also demonstrated that IRE is an ablation technique that kills brain tissue in a focal manner depicted by MRI (n = 16) and transiently disrupts the BBB adjacent to the ablated area in a voltage-dependent manner as seen with Evan''s Blue (n = 5) and Gd administration.     

Calculation of Externally Applied Electric Field Intensity for Disruption of Cancer Cell Proliferation

It is already known that electrostatic, magnetostatic, extremely low-frequency electric fields, and pulsed electric field could be utilized in cancer treatment. The healing effect depends on frequency and amplitude of electric field. In the present work, a simple theoretical model is developed to estimate the intensity of electrostatic field that damages a living cell during division. By this model, it is shown that magnification of electric field in the bottleneck of dividing cell is enough to break chemical bounds between molecules by an avalanche process. Our model shows that the externally applied electric field of 4?V/cm intensity is able to hurt a cancer cell at the dividing stage.     

A new principle of cell sorting by using selective electroporation in a modified flow cytometer

When a strong electric field pulse of a few microseconds is applied to biological cells, small pores are formed in the cell membranes; this process is called electroporation. At high field strengths and/or long pulse durations the membranes will be damaged permanently. This eventually leads to cell kill. We have developed a modified flow cytometer in which one can electroporate individual cells selected by optical analysis. The first experiments with this flow cytometer were designed to use it as a damaging sorter; we used electric pulses of 10 microseconds and resulting field strengths of 2.0 and 3.2 x 10(6) V/m to kill K562 cells and lymphocytes respectively. The hydrodynamically focused cells are first optically analyzed in the usual way in a square flow channel. At the end of this channel the cells are forced to flow through a small Coulter orifice, into a wider region. If optical analysis indicates that a cell is unwanted, the cell is killed by applying a strong electric field across the Coulter orifice. The wanted living cells can be subsequently separated from the dead cells and cell fragments by a method suitable for the particular application (e.g., centrifugation, cell growth, density gradient, etc.). The results of these first experiments demonstrate that by using very simple equipment, sorting by selective killing with electric fields is possible at rates of 1,000 cells/s with a purity of the sorted fraction of 99.9%.     

斑马鱼胚胎和肿瘤细胞评价细胞毒药物活性比较研究*

目的:比较斑马鱼胚胎和肿瘤细胞作为药物筛选模型的优缺点.方法:采用MTT法检测顺铂、紫杉醇、阿霉素、5-氟尿嘧啶四种药物对HL-60和Hela细胞的增殖影响;同时,观察药物对斑马鱼胚胎发育的影响.结果:阿霉素、顺铂及紫杉醇作用于HL-60及Hela细胞的IC50均显著高于作用于斑马鱼胚胎的LD50;而5-FU作用于肿瘤细胞和斑马鱼胚胎的结果与其它药物相反;四种抗肿瘤药物对斑马鱼胚胎的生长发育均有致畸作用.结论:斑马鱼胚胎作为细胞毒类药物筛选模型,对于抗微管类药物较为敏感,但对于抗代谢药敏感性较肿瘤细胞差.     

Quantitative study of electroporation-mediated molecular uptake and cell viability

Electroporation's use for laboratory transfection and clinical chemotherapy is limited by an incomplete understanding of the effects of electroporation parameters on molecular uptake and cell viability. To address this need, uptake of calcein and viability of DU 145 prostate cancer cells were quantified using flow cytometry for more than 200 different combinations of experimental conditions. The experimental parameters included field strength (0.1-3.3 kV/cm), pulse length (0.05-20 ms), number of pulses (1-10), calcein concentration (10-100 microM), and cell concentration (0.6-23% by volume). These data indicate that neither electrical charge nor energy was a good predictor of electroporation's effects. Instead, both uptake and viability showed a complex dependence on field strength, pulse length, and number of pulses. The effect of cell concentration was explained quantitatively by electric field perturbations caused by neighboring cells. Uptake was shown to vary linearly with external calcein concentration. This large quantitative data set may be used to optimize electroporation protocols, test theoretical models, and guide mechanistic interpretations.     

INFLUENCE OF LOW-FREQUENCY ELECTRIC FIELDS ON PROLIFERATION AND IL-8 RELEASE OF HL-60 CELLS

The influence of capacitively coupled extremely low-frequency (ELF) electric fields on proliferation and on interleukin (IL)-8 release of exponentially growing HL-60 cells was examined. The cell suspensions were treated with the field component of interferential current (IFC) using different exposure protocols. Modulation frequencies of 10 and 100 Hz were applied with field strengths between 0.075 and 11.54 V_pp/cm for 48 hr using a 5-min exposure time at every 3 hr. At a field strength of 1 V_pp/cm, the influence of the time between two exposure sessions was examined for different modulation frequencies. All exposure protocols applied have no effect on cell proliferation (p>0.05), but statistical significant reduction (p<0.05) of the IL-8 release at selected modulation frequencies and interval times could be observed.