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Enhancement of cell membrane permeability by using charged nanoparticles and a weak external electric field.

Hideya NakamuraTakumi OkamuraMasaya TajimaRyuji KawanoMisa YamajiShuji OhsakiSatoru Watano
Published in: Physical chemistry chemical physics : PCCP (2023)
Because the cell membrane is the main barrier of intracellular delivery, it is important to facilitate and control the translocation of extracellular compounds across it. Our earlier molecular dynamics simulations suggested that charged nanoparticles under a weak external electric field can enhance the permeability of the cell membrane without disrupting it. However, this membrane permeabilization approach has not been tested experimentally. This study investigated the membrane crossing of a model compound (dextran with a M w of 3000-5000) using charged nanoparticles and a weak external electric field. A model bilayer lipid membrane was prepared by using a droplet contact method. The permeability of the membrane was evaluated using the electrophysiological technique. Even when the applied electric field was below the critical strength for membrane breakdown, dextran was able to cross the membrane without causing membrane breakdown. These results indicate that adding nanomaterials under a weak electric field may enhance the translocation of delivery compounds across the cell membrane with less damage, suggesting a new strategy for intracellular delivery systems.
Keyphrases
  • molecular dynamics simulations
  • oxidative stress
  • molecular docking
  • mass spectrometry
  • high resolution
  • fatty acid
  • high speed
  • atomic force microscopy