Abstract
Electroporation has been widely used in delivering foreign biomolecules into cells, but there is still much room for improvement, such as cell viability and integrity. In this manuscript, we investigate the distribution and the toxicity of pH changes during electroporation, which significantly decreases cell viability. A localized pH gradient forms between anode and cathode leading to a localized distribution of cell death near the electrodes, especially cathodes. The toxicity of hydroxyl ions is severe and acute due to their effect in the decomposition of phospholipid bilayer membrane. On the other hand, the electric field used for electroporation aggravates the toxicity of hydroxyl because the electropermeabilization of cell membrane makes bilayer structure more loosen and vulnerable. We also investigate the side effects during scaling down the size of electrodes in electroporation microchips. Higher percentage of cells is damaged when the size of electrodes is smaller. At last, we propose an effective strategy to constrain the change of pH by modifying the composition of electroporation buffer. The modified buffer decreases the changes of pH, thus enables high cell viability even when the electric pulse duration exceeds several milliseconds. This ability has potential advantage in some applications that require long-time electric pulse stimulation.
Highlights
Microfabrication technology was utilized in developing electroporation devices[22,23]
We explored the application of electric filed and verified that the electric field increased the harmful effects of pH changes
We figured out the mechanism of cell death during electroporation, analyzed the scaling down effect of microchips and proposed a strategy to improve cell viability
Summary
Microfabrication technology was utilized in developing electroporation devices[22,23]. Cells near the electrodes were dramatically damaged, swollen, and eventually ruptured. They claimed that the high level of electric pulse might accelerate this phenomenon, but did not show convincing results to support that. Huang et al.[28] monitored the changes of pH on annular interdigitated microchip during electroporation. They found that dead cells were seen to cluster around the cathodes. Wu et al.[45] proposed an novel distributed electrode network to neutralize ions by using a tri-phase pulse. Assisting with tri-phase stimulation mode, they found the distributed electrode network was able to avoid the dramatic changes of pH during electroporation. Besides the geometric considerations (since as the size of device decreases, the effective electroporation volume reduces46), pH changes was found to become more severe and influent more percentage of electroporation volume as the device size being decreased
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