Dosimetry characterization of 32P catheter‐based vascular brachytherapy source wire

Dosimetry characterization of 32P catheter‐based vascular brachytherapy source wire

Dosimetry measurements and Monte Carlo simulations for a catheter‐based 32P endovascular brachytherapy source wire are described. The measured dose rates were obtained using both radiochromic dye film and an automated plastic scintillator. The investigated source has dimensions of 27 mm in length an...

Full description

Saved in:
Bibliographic Details
Published in:Medical physics (Lancaster) Vol. 27; no. 8; pp. 1770 - 1776
Main Authors: Mourtada, Firas A., Soares, Christopher G., Seltzer, Stephen M., Lott, Sam H.
Format: Journal Article
Language:English
Published: United States American Association of Physicists in Medicine 01-08-2000
Subjects:
32P
Algorithms
beta dosimetry
blood vessels
brachytherapy
Brachytherapy - instrumentation
Brachytherapy - methods
Densitometers
densitometry
dosimetry
Dosimetry/exposure assessment
Film Dosimetry - methods
Humans
Models, Theoretical
Monte Carlo
Monte Carlo Method
Monte Carlo methods
phosphorus
Phosphorus Radioisotopes - therapeutic use
Physicists
Plastics
radiation therapy
Radiation treatment
radioisotopes
Radiometry - methods
restenosis
Software
solid scintillation detectors
Therapeutic applications, including brachytherapy
Vascular Neoplasms - therapy
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Dosimetry measurements and Monte Carlo simulations for a catheter‐based 32P endovascular brachytherapy source wire are described. The measured dose rates were obtained using both radiochromic dye film and an automated plastic scintillator. The investigated source has dimensions of 27 mm in length and 0.24 mm in diameter, and is encapsulated in NiTi. For the radiochromic film measurements, calibrated radiochromic dye film was irradiated at distances between 1 and 5 mm from the source axis in A‐150 plastic, and read out with a high‐resolution scanning densitometer. The depth‐dose curve measured in A‐150 is then converted to that in water using correction factors obtained from Monte Carlo calculations. For the scintillator system, direct measurements in water were acquired at distances between 1 and 6 mm from the center of the source, along the perpendicular bisector of the source axis. The scintillator was calibrated in terms of absorbed‐dose rate in a reference beta‐particle field at multiple depths. The measured dose rates obtained from the film and scintillator measurements were then normalized to the measured source activity, i.e., to convert the measured data to units of cGy/s/mCi. Theoretical dosimetry calculations of the catheter‐based 32P wire geometry were also obtained from Monte Carlo simulations using the Electron Gamma Shower code (EGS4), the Monte Carlo N‐particle transport code (MCNP4B), and CYLTRAN from the Integrated Tiger Series codes (ITS v.3) and found to be in good agreement. The results of both measurements and calculations are expressed as absorbed‐dose rate in water per unit of contained activity (cGy/s/mCi). Comparisons indicate that the measured and calculated dosimetry are in good agreement (<10%) within the relevant treatment distances (1–5 mm). This work fully characterizes the radiation field around a novel 32P beta brachytherapy source in water. The depth‐dose curve can be used to calculate the dose to the vessel wall from a 27 mm 32P source wire centered within the vessel lumen.
ISSN:0094-2405
2473-4209
DOI:10.1118/1.1286551