J. Kolb, W. Frey, J.A. White, S. Beebe, R. Joshi, K. Schoenbach
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引用次数: 1
摘要
为了研究哺乳动物细胞在暴露于持续60 ns的脉冲电场时的膜充电,我们实时测量了暴露期间和暴露后的跨膜电压变化,即与所给电脉冲的持续时间相比,分辨率较短。外加电场在5kv /cm ~ 90kv /cm之间变化。在所有条件下,在曝光的前5ns,电池超极化极的电压变化大于1v。薄膜的进一步超极化可达1.6 V,这取决于外加电场的强度。阳极处至少1.4 V的变化将导致孔打开并允许离子交换。在达到这个最大值后,电位差立即开始重新调整。原则上,去极化极处的电压遵循相同的模式。然而,这种变化通常要低1 V,这就限制了去极化的最大值为0.6 V
Cell Membrane Charging in Intense Nanosecond Pulsed Electric Fields
In order to study membrane charging in mammalian cells during exposure to pulsed electric fields of 60 ns duration we measured transmembrane voltage changes during and after exposure in real-time, i.e. with a resolution that is short compared to the duration of the administered electrical pulse. The applied electric field was varied between 5 kV/cm and 90 kV/cm. Under all conditions the voltage at the hyperpolarized pole of the cell is changing by more than 1 V during the first 5 ns of the exposure. A further hyperpolarization of the membrane of up to 1.6 V depends on the strength of the applied field. A change of at least 1.4 V at the anode will cause pores to open and allow ion exchange. Immediately after this maximum is reached, potential differences start to readjust. In principle, voltages at the depolarized pole follow the same pattern. However, the change is, in general lower by 1 V, limiting the depolarization to a maximum of 0.6 V
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