• DocumentCode
    1358548
  • Title

    Numerical simulations of heating patterns and tissue temperature response due to high-intensity focused ultrasound

  • Author

    Curra, Francesco P. ; Mourad, Pierre D. ; Khokhlova, Vera A. ; Cleveland, Robin O. ; Crum, Lawrence A.

  • Author_Institution
    Appl. Phys. Lab., Washington Univ., Seattle, WA, USA
  • Volume
    47
  • Issue
    4
  • fYear
    2000
  • fDate
    7/1/2000 12:00:00 AM
  • Firstpage
    1077
  • Lastpage
    1089
  • Abstract
    The results of this paper show-for an existing high intensity, focused ultrasound (HIFU) transducer-the importance of nonlinear effects on the space/time properties of wave propagation and heat generation in perfused liver models when a blood vessel also might be present. These simulations are based on the nonlinear parabolic equation for sound propagation and the bio-heat equation for temperature generation. The use of high initial pressure in HIFU transducers in combination with the physical characteristics of biological tissue induces shock formation during the propagation of a therapeutic ultrasound wave. The induced shock directly affects the rate at which heat is absorbed by tissue at the focus without significant influence on the magnitude and spatial distribution of the energy being delivered. When shocks form close to the focus, nonlinear enhancement of heating is confined in a small region around the focus and generates a higher localized thermal impact on the tissue than that predicted by linear theory. The presence of a blood vessel changes the spatial distribution of both the heating rate and temperature.
  • Keywords
    biomedical ultrasonics; blood vessels; hyperthermia; liver; physiological models; radiation therapy; bioheat equation; energy spatial distribution; heating patterns; high-intensity focused ultrasound; linear theory; nonlinear effects; nonlinear enhancement; nonlinear parabolic equation; numerical simulations; perfused liver models; shock formation; therapeutic ultrasound wave propagation; tissue temperature response; Acoustic propagation; Biological system modeling; Blood vessels; Electric shock; Liver; Nonlinear equations; Numerical simulation; Space heating; Temperature; Ultrasonic imaging;
  • fLanguage
    English
  • Journal_Title
    Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0885-3010
  • Type

    jour

  • DOI
    10.1109/58.852092
  • Filename
    852092