• DocumentCode
    1050581
  • Title

    Computational modeling evidence of a nonthermal electromagnetic interaction mechanism with living cells: microwave nonlinearity in the cellular sodium ion channel

  • Author

    Stoykov, Nikolay S. ; Jerome, Joseph W. ; Pierce, Lauren C. ; Taflove, Allen

  • Author_Institution
    Rehabilitation Inst. of Chicago, IL, USA
  • Volume
    52
  • Issue
    8
  • fYear
    2004
  • Firstpage
    2040
  • Lastpage
    2045
  • Abstract
    A computational hydrodynamics model consisting of a system of four coupled time-domain partial differential equations is applied to study the response of the cellular sodium ion channel to a microwave electric-field excitation. The model employs a dynamic conservation law formulation, which has not been previously applied to this problem. Results indicate that the cellular sodium ion channel exhibits an electrical nonlinearity at microwave frequencies, which generates an intermodulation spectrum when excited by an amplitude-modulated electric field. Intermodulation products having frequencies down to 50 MHz, and very likely well below 50 MHz, appear possible. This is a new nonthermal microwave interaction mechanism with living tissues that, if observable below 0.1 MHz, could enable the stimulation of excitable biological tissues, and thereby have significant implications for human health and safety.
  • Keywords
    bioelectric phenomena; biological effects of microwaves; biological tissues; cellular effects of radiation; intermodulation; sodium; time-domain analysis; 50 MHz; Na; amplitude modulated electric field; cellular sodium ion channel; computational hydrodynamics model; computational modeling evidence; dynamic conservation law formulation; electrical nonlinearity; excitable biological tissue; human health; intermodulation spectrum; living cell; living tissues; microwave electric field excitation; microwave nonlinearity; nonthermal electromagnetic interaction mechanism; nonthermal microwave interaction mechanism; safety; time-domain partial differential equation; Biological tissues; Computational modeling; Health and safety; Humans; Hydrodynamics; Microwave frequencies; Microwave generation; Nonlinear dynamical systems; Partial differential equations; Time domain analysis; Computational modeling; living cells; microwaves; nonlinearity; nonthermal electromagnetic interactions;
  • fLanguage
    English
  • Journal_Title
    Microwave Theory and Techniques, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0018-9480
  • Type

    jour

  • DOI
    10.1109/TMTT.2004.831924
  • Filename
    1318802