Abstract
There is an increasing need to develop methods for in vivo verification of the delivery of radiotherapy treatments. Electronic portal imaging devices (EPID's) have been demonstrated to be of use for this application. The basic principle is relatively straightforward, the EPID is used to measure a two‐dimensional (2D) planar exit or portal dose map behind the patient during the treatment delivery that can provide information on any errors in linear accelerator output or changes in the patient anatomy. In this paper we focused on the effect of intra‐fraction motion, particularly respiratory motion, on the measured 2D EPID dose–response. Measurements were made with a breast phantom undergoing one‐dimensional (1D) sinusoidal motion with a range of amplitudes (0.5, 1.0, and 1.5 cm) and frequencies (12, 15, and 20 cycles/min). Further measurements were made with the phantom undergoing breathing sequences measured during patient planning computed tomography simulation. We made use of the quadratic calibration method that converts the EPID images to a surrogate for dose, equivalent thickness of Plastic Water®. Comparisons were made of the 2D thickness maps derived for the different motions compared to the static phantom case and the resulting dose difference analyzed over the “breast” region of interest. A 2D gamma analysis within the same region of interest was performed of the motion images compared to static reference image. Comparisons were made of 1D thickness profiles for the moving and static phantom. The 1D and 2D analyses show the method to be sensitive to the smallest motion amplitude of 0.5 cm tested in the phantom measurements. The results using the phantom demonstrate the method to be a potentially useful tool for monitoring intra‐fraction motion during the delivery of patient radiotherapy treatments as well as more generally providing information on the effects of motion on EPID based in vivo dosimetric verification.
Highlights
Technological advances in the planning and delivery of radiation therapy has led to an increase in complexity of patient treatments.[1]
This paper investigates the effect of respiratory motion on measured Electronic portal imaging devices (EPIDs) images converted to radiological thickness maps
In this paper we have investigated the effect of respiratory type motion on EPIDs calibrated for thickness using the quadratic calibration technique
Summary
Technological advances in the planning and delivery of radiation therapy has led to an increase in complexity of patient treatments.[1]. A 2D integrated measurement of the delivered dose is made during radiation delivery and compared with a reference 2D dose map calculated (or measured) at the EPID plane. The 2D EPID dose measurement can be back‐ projected into a CT‐based model of the patient and compared with a reference dose distribution in the same CT‐based patient model.[7] The CT model can be derived from the treatment planning CT or for a more accurate prediction be based on a treatment time cone beam CT. EPIDs have been shown in a number of studies to be valuable for dosimetric verification of breast radiotherapy treatments.[8,9,10,11,12,13] As already stated this appears to be conceptually straightforward, the implementation of a solution with high accuracy is nontrivial such that the technique is still not in widespread routine clinical use
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