Scientific Abstracts and Sessions

Accuracy of dose delivery in external beam radiotherapy is usually verified with electronic portal imaging (EPI) in which the\udtreatment beam is used to check the positioning of the patient. However the resulting megavoltage x-ray images suffer from poor\udquality. The image quality can be improved by developing a special operating mode in the linear accelerator. The existing treatment\udbeam is modified such that it produces enough low-energy photons for imaging. In this work the problem of optimizing the\udbeam/detector combination to achieve optimal electronic portal image quality is addressed. The linac used for this study was modified\udto produce two experimental photon beams. These beams, named Al6 and Al10, were non-flat and were produced by 4MeV electrons\udhitting aluminum targets, 6 and 10mm thick respectively. The images produced by a conventional EPI system (6MV treatment beam\udand camera-based EPID with a Cu plate & Gd2O2S screen ) were compared with the images produced by the experimental beams and\udvarious screens with the same camera). The contrast of 0.8cm bone equivalent material in 5 cm water increased from 1.5% for the\udconventional system to 11% for the combination of Al6 beam with a 200mg/cm2 Gd2O2S screen. The signal-to-noise ratio calculated\udfor 1cGy flood field images increased by about a factor of two for the same EPI systems. The spatial resolution of the two imaging\udsystems was comparable. This work demonstrates that significant improvements in portal image contrast can be obtained by\udsimultaneous optimization of the linac spectrum and EPI detector