• Title of article

    Inverse planning anatomy-based dose optimization for HDR-brachytherapy of the prostate using fast simulated annealing algorithm and dedicated objective function

  • Author/Authors

    Lessard، Etienne نويسنده , , Pouliot، Jean نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2001
  • Pages
    -772
  • From page
    773
  • To page
    0
  • Abstract
    An anatomy-based dose optimization algorithm is developed to automatically and rapidly produce a highly conformal dose coverage of the target volume while minimizing urethra, bladder, and rectal doses in the delivery of an high dose-rate (HDR) brachytherapy boost for the treatment of prostate cancer. The dwell times are optimized using an inverse planning simulated annealing algorithm (IPSA) governed entirely from the anatomy extracted from a CT and by a dedicated objective function (cost function) reflecting clinical prescription and constraints. With this inverse planning approach, the focus is on the physicianʹs prescription and constraint instead of on the technical limitations. Consequently, the physicianʹs control on the treatment is improved. The capacity of this algorithm to represent the physicianʹs prescription is presented for a clinical prostate case. The computation time (CPU) for IPSA optimization is less than 1 min (41 s for 142 915 iterations) for a typical clinical case, allowing fast and practical dose optimization. The achievement of highly conformal dose coverage to the target volume opens the possibility to deliver a higher dose to the prostate without inducing overdosage of urethra and normal tissues surrounding the prostate. Moreover, using the same concept, it will be possible to deliver a boost dose to a delimited tumor volume within the prostate. Finally, this method can be easily extended to other anatomical sites.
  • Keywords
    short circuit current , power quality , transient over voltage , Fault current limiter
  • Journal title
    MEDICAL PHYSICS
  • Serial Year
    2001
  • Journal title
    MEDICAL PHYSICS
  • Record number

    1572