RESUMO
PURPOSE: Small animal irradiators are equipped with x-ray beams and cone collimators with millimeter dimensions to be used in preclinical research. The use of small fields in the kV energy range may require the application of energy-dependent, field size-dependent, or depth-dependent correction factors to the dosimetric data acquired for treatment planning system (TPS) commissioning purposes to obtain accurate dose values. Considering that these corrections are also detector dependent, the suitability of a synthetic single-crystal diamond detector for small-field relative dosimetry in a preclinical irradiator (220-kVp) was evaluated to avoid the necessity of applying correction factors during TPS commissioning. METHODS: The detector response was assessed during the transition for field sizes ranging from 20 × 20 mm2 to 3 × 3 mm2 , using the small animal radiation research platform (SARRP). The percentage depth dose distributions (PDDs), lateral profiles and output factors (OFs) were measured. The PDDs for the synthetic diamond detector were compared to the distributions acquired using a small-volume microchamber (0.016 cm3 ) and with Monte Carlo calculations using the MC3D in-house software package. The profiles and OFs were compared to the data from a silicon solid-state detector and to radiochromic film data provided by the manufacturer; for the OF determination, measurements made using a microchamber were added for comparison. The performance of several detectors used as references was previously validated for relative dosimetry in preclinical irradiators. A commercial TPS was commissioned for the factor-based algorithm, using the data acquired with the diamond detector, and no additional correction factors were applied. To verify the performance of the TPS and the accuracy of the dosimetric methodology, radiochromic film irradiation in water was conducted, and two-dimensional (2D) dose distributions in the coronal and axial planes were compared under different gamma criteria. RESULTS: Compared with the microchamber and MC3D distributions, the agreement of the PDDs using the synthetic diamond detector was better than 2%. The profile data exhibited very good agreement compared with the data from the silicon detector, with an average and a maximum difference of 0.31 and 0.39 mm in the penumbras, respectively. Compared with the data from the radiochromic film, the average and maximum differences were equal to 0.77 and 0.89 mm, respectively. Very good agreement, within 1%, was obtained between the OFs measured with the synthetic diamond detector and the radiochromic film, compared only for the cone collimators. The validation of the TPS commissioning using gamma criteria compared to film showed an average passing rate of 100% and 93.2% with a global gamma criterion of 1 mm/3% for the coronal and axial planes, respectively, including the 3 × 3 mm2 field size and penumbra regions. CONCLUSIONS: Synthetic diamond is a suitable detector for the complete relative dosimetry of small x-ray fields. The commissioning of the TPS with its own beam dosimetric data exhibited encouraging results even in a 3 × 3 mm2 field and penumbra region. This methodology allows for the prediction of 2D dose distributions with an accuracy in water ranging from 3 to 5% compared to the 2D distribution from film dosimetry.
Assuntos
Diamante , Radiometria , Animais , Dosimetria Fotográfica , Método de Monte Carlo , Raios XRESUMO
Improvements in dosimetry in preclinical radiation research facilitate the application of results to the newest radiotherapy techniques, reducing gaps that hinder translation. Currently, guidelines for small-field kV photon dosimetry of small animal irradiators have not been published, and most of the publications are based on radiochromic film dosimetry. In this study, we evaluated the performance of four detectors, three ionization chambers (ICs): (PTW Advanced Markus, PTW Semiflex 31010, PTW PinPoint-3D 31016) and one solid-state detector (PTW 60017 unshielded Diode E) regarding their suitability for relative dosimetry of the small animal radiation research platform SARRP (220 kVp). The measurements were performed in a high-resolution 3D scanning phantom, centering the detectors in the field following the in-plane and cross-plane profiles method at two depths. Depth dose curves (PDDs) and profiles were measured in water for field sizes ranging from 40 × 40 mm2 to 5 × 5 mm2. Quantitative analysis was performed through global and local dose differences (DDs) between the PDDs and the Advanced Markus parallel plate IC data and through the gamma index (γ) criteria for profiles compared against data from EBT3 films provided by the manufacturer. Compared to the Advanced Markus IC, the PDD results suggest that PinPoint-3D is suitable for depth measurements at this beam quality, even near the surface, with agreements better than 1%. Semiflex 31010 was accurate to within 1.5% for measurements deeper than 5 mm. Diode E showed a dramatic DD and should not be recommended for the field sizes and kVp evaluated in this study. In agreement with γ analyses, PinPoint-3D and Diode E are good candidates for profile measurements of field sizes from 40 × 40 mm2 to 10 × 10 mm2. For 5 × 5 mm2 profiles, only Diode E showed good results, making it a recommended detector for profile measurements.