Next Generation CANCAN Focusing for Remote Stimulation by Nanosecond Electric Pulses

Overview

Journal Bioelectrochemistry

Publisher Elsevier

Specialty Biochemistry

Date 2023 Apr 8

PMID 37030093

Authors

Andrei G Pakhomov

Emily Gudvangen

Uma Mangalanathan

Oleg Kondratiev

Luis Redondo

Iurii Semenov

Affiliations

Soon will be listed here.

Abstract

Focusing electric pulse effects away from electrodes is a challenge because the electric field weakens with distance. Previously we introduced a remote focusing method based on bipolar cancellation, a phenomenon of low efficiency of bipolar nanosecond electric pulses (nsEP). Superpositioning two bipolar nsEP into a unipolar pulse canceled bipolar cancellation ("CANCAN" effect), enhancing bioeffects at a distance despite the electric field weakening. Here, we introduce the next generation (NG) CANCAN focusing with unipolar nsEP packets designed to produce bipolar waveforms near electrodes (suppressing electroporation) but not at the remote target. NG-CANCAN was tested in CHO cell monolayers using a quadrupole electrode array and labeling electroporated cells with YO-PRO-1 dye. We routinely achieved 1.5-2 times stronger electroporation in the center of the quadrupole than near electrodes, despite a 3-4-fold field attenuation. With the array lifted 1-2 mm above the monolayer (imitating a 3D treatment), the remote effect was enhanced up to 6-fold. We analyzed the role of nsEP number, amplitude, rotation, and inter-pulse delay, and showed how remote focusing is enhanced when re-created bipolar waveforms exhibit stronger cancellation. Advantages of NG-CANCAN include the exceptional versatility of designing pulse packets and easy remote focusing using an off-the-shelf 4-channel nsEP generator.

Citing Articles

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PMID: 38909279 PMC: 11365113. DOI: 10.1016/j.bpj.2024.06.021.

Control of the Electroporation Efficiency of Nanosecond Pulses by Swinging the Electric Field Vector Direction.

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