• DocumentCode
    1584491
  • Title

    Nanoelectropulse Intracellular Perturbation and Electropermeabilization Technology: Phospholipid Translocation, Calcium Bursts, Chromatin Rearrangement, Cardiomyocyte Activation, and Tumor Cell Sensitivity

  • Author

    Vernier, P. Thomas ; Sun, Yinghua ; Wang, Jingjing ; Thu, Mya Mya ; Garon, Edward ; Valderrabano, Miguel ; Marcu, Laura ; Koeffler, H. Phillip ; Gundersen, Martin A.

  • Author_Institution
    Dept. of Electr. Eng.-Electrophys., Univ. of Southern California, Los Angeles, CA
  • fYear
    2006
  • Firstpage
    5850
  • Lastpage
    5853
  • Abstract
    Nanosecond, megavolt-per-meter pulsed electric fields scramble the asymmetric arrangement of phospholipids in the plasma membrane, release intracellular calcium, trigger cardiomyocyte activity, and induce apoptosis in mammalian cancer cells, without the permeabilizing effects associated with longer, lower-field pulses. Dose dependencies with respect to pulse width, amplitude, and repetition rate, and total pulse count are observed for all of these phenomena. Sensitivities vary among cell types; cells of lymphoid origin growing in suspension are more susceptible to nanoelectropulse exposure than solid tumor lines. Simple electrical models of the cell are useful for first-order explanations, but more sophisticated treatments will be required for analysis and prediction at both biomolecular and tissue levels
  • Keywords
    bioelectric phenomena; biological effects of fields; biomembrane transport; calcium; cancer; cardiology; lipid bilayers; tumours; apoptosis; biological tissue; biomolecule; calcium bursts; cardiomyocyte activation; chromatin rearrangement; electrical models; electropermeabilization technology; intracellular calcium release; lymphoid cell; mammalian cancer cells; nanoelectropulse intracellular perturbation; phospholipid translocation; plasma membrane; pulse amplitude; pulse repetition rate; pulse width; pulsed electric fields; solid tumor lines; suspension; total pulse count; tumor cell sensitivity; Biomedical engineering; Biomembranes; Calcium; Cancer; Cardiology; Nanobioscience; Neoplasms; Plasmas; Space vector pulse width modulation; Tumors; bioelectric phenomena; biomembranes; cancer; cardiac synchronization; electropermeabilization; intracellular calcium; nanosecond megavolt-per-meter electric pulses; tumor;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Engineering in Medicine and Biology Society, 2005. IEEE-EMBS 2005. 27th Annual International Conference of the
  • Conference_Location
    Shanghai
  • Print_ISBN
    0-7803-8741-4
  • Type

    conf

  • DOI
    10.1109/IEMBS.2005.1615820
  • Filename
    1615820