An End-to-End Examination of Geometric Accuracy of IGRT Using a New Digital Accelerator Equipped with On-Board Imaging System

摘要

The Varian’s new digital linear accelerator (LINAC), TrueBeam^™ STx, is equipped with high dose rate flattening filter free (FFF) mode (6 MV and 10 MV), high definition multileaf collimator (HDMLC) (2.5 mm leaf width), as well as onboard imaging (OBI) capabilities. A series of end-to-end phantom tests were performed TrueBeam-based IGRT to determine the geometric accuracy of image-guided setup and dose delivery process for all beam modalities delivered using IMRT and RapidArc^™. In these tests, an anthropomorphic phantom with a Ball Cube II insert and the analysis software (FilmQA^™ (3cognition)) were used to evaluate the accuracy of TrueBeam^™ image-guided setup and dose delivery. Laser cut EBT2 films with 0.15 mm accuracy were embedded into the phantom. The phantom with the film inserted was first scanned with a GE Discovery-ST CT scanner, and the images were then imported to the planning system. Plans with steep dose fall off surrounding hypothetical targets of different sizes were created using RapidArc and IMRT with FFF and WFF (with flattening filter) beams. Four RapidArc plans (6 MV and 10 MV FFF) and five IMRT plans (6 MV and 10 MV FFF; 6 MV, 10 MV and 15 MV WFF) were studied. The RapidArc plans with 6 MV FFF were planned with target diameters of 1 cm (0.52 cc), 2 cm (4.2 cc), and 3 cm (14.1 cc), and all other plans were planned with a target diameter of 3 cm. Both onboard planar and volumetric imaging procedures were used for phantom setup and target localization. The IMRT and RapidArc plans were then delivered, and the film measurements were compared with the original treatment plans using a Gamma criteria of 3%/1 mm and 3%/2 mm. The shifts required in order to align the film measured dose with the calculated dose distributions was attributed to be the targeting error. Targeting accuracy of image-guided treatment using TrueBeam^™ was found to be within 1 mm. For irradiation of the 3 cm target, the Gammas (3%, 1 mm) were found to be above 90% in all plan deliveries. For irradiations of smaller targets (2 cm and 1 cm), similar accuracy was achieved for 6 MV and 10 MV beams. Slightly degraded accuracy was observed for irradiations with higher energy beam (15 MV). In general, Gammas (3%, 2 mm) were found to be above 97% for all the plans. Our end-to-end tests showed an excellent relative dosimetric agreement and sub millimeter targeting accuracy for 6 and 10 MV beams, using both FFF and WFF delivery methods. However, increased deviations in spatial and dosimetric accuracy were found when treating lesions smaller than 2 cm or with 15 MV beam.