Publications (38) View all
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Article: SU-E-T-27: A New Tool for HDR Brachytherapy Treatment QA.
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ABSTRACT: Purpose: Similarly as in external beam radiotherapy, brachytherapy treatments need to undergo patient specific verification of dosimetry and parameter consistency prior to their application in order to guarantee patient safety. Thus, a tool for HDR brachytherapy treatment QA has been developed in interactive data programming language (IDL). Main functions of this tool are: verification of (1) the dose calculation accuracy and (2) the transfer of treatment relevant parameters from the treatment planning system (TPS) to the treatment control system (TCS). Methods: In the developed tool the planned dwell positions from the TPS and dwell times from the TCS as well as an independently determined source strength at treatment date are used to compute doses at selected points and compared with the corresponding TPS values. For this independent dose computation either published TG43 or in-house Monte Carlo calculated values of the HDR source can be used. To ensure correct data transfer from TPS to TCS, parameters such as channel mapping, treatment length of each channel, step size, dwell times and source strength at treatment date are additionally exported from the TCS and automatically compared with the corresponding TPS parameters. During 2012, the QA tool has been applied for 20 patient plans generated with Oncentra Masterplan. Results: After validation and generation of a graphical user interface the QA tool was implemented in clinical routine. The time needed for a patient specific treatment QA could be reduced to less than 15 minutes due to the new tool. A median number of 300 dose points per patient have been verified. The mean doses calculated for each patient agree with the TPS results within 1.1%. Conclusions: The newly developed QA tool has been proven to be a very efficient and accurate instrument for brachytherapy treatment QA and is integrated as part of the QA protocol.Medical Physics 06/2012; 39(6):3708. · 2.83 Impact Factor -
Article: SU-E-T-507: Dose Calculation Quality of AcurosXB Involving a HD120 MLC Compared with Monte Carlo Methods.
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ABSTRACT: Purpose: Advanced radiation therapy requires highly sophisticated dose calculation algorithms such as finite element based Boltzmann solvers or Monte Carlo (MC) methods. MC is commonly accepted as the golden standard method for dose calculation in high energy treatments and thus it is used for benchmarking other algorithms. In this work the quality of dose distribution calculated using the Boltzmann solver based AcurosXB algorithm within Eclipse (Varian Medical Systems) is investigated for volumetric modulated arc treatment (VMAT) plans involving the high definition MLC (HD120 MLC) by comparing doses with the validated Swiss Monte Carlo Plan (SMCP).Materials & Methods: Within SMCP and Eclipse using AcurosXB, 10 VMAT H&N patient plans and corresponding verification plans were recalculated using fixed MUs. In SMCP, radiation transport and dose calculation were performed using VMC++ with a statistical uncertainty of 1%. The voxel size was 2.5 mm for SMCP and AcurosXB and the same material composition data was used for CT conversion. Dose volume histograms (DVH) were used in order to quantify the difference between the dose distributions of the patient plans. In addition, calculated verification plans were compared with measurements carried out with the Delta4 system (Scandidos) by using the gamma evaluation with 3%/3 mm criteria of points having a dose larger than 20% of isocenter dose. Results: DVHs for the patient plans showed good agreement between SMCP and AcurosXB calculations. Overall AcurosXB lead to an underestimation of the median dose values by about 1%. For measured total dose distributions of the verification plans on average 98.6% and 99.0% of the points fullfil the gamma criteria for the dose calculated using AcurosXB and SMCP, respectively. Conclusions: Resulting AcurosXB dose distributions for VMAT H&N plans involving a HD120 MLC are in good agreement with calculated SMCP dose distributions. Conflict of Interest: This work was supported by Varian Medical Systems.Medical Physics 06/2012; 39(6):3822. · 2.83 Impact Factor -
Article: Monte Carlo implementation, validation, and characterization of a 120 leaf MLC.
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ABSTRACT: Recently, the new high definition multileaf collimator (HD120 MLC) was commercialized by Varian Medical Systems providing high resolution in the center section of the treatment field. The aim of this work is to investigate the characteristics of the HD120 MLC using Monte Carlo (MC) methods. Based on the information of the manufacturer, the HD120 MLC was implemented into the already existing Swiss MC Plan (SMCP). The implementation has been configured by adjusting the physical density and the air gap between adjacent leaves in order to match transmission profile measurements for 6 and 15 MV beams of a Novalis TX. These measurements have been performed in water using gafchromic films and an ionization chamber at an SSD of 95 cm and a depth of 5 cm. The implementation was validated by comparing diamond measured and calculated penumbra values (80%-20%) for different field sizes and water depths. Additionally, measured and calculated dose distributions for a head and neck IMRT case using the DELTA(4) phantom have been compared. The validated HD120 MLC implementation has been used for its physical characterization. For this purpose, phase space (PS) files have been generated below the fully closed multileaf collimator (MLC) of a 40 × 22 cm(2) field size for 6 and 15 MV. The PS files have been analyzed in terms of energy spectra, mean energy, fluence, and energy fluence in the direction perpendicular to the MLC leaves and have been compared with the corresponding data using the well established Varian 80 leaf (MLC80) and Millennium M120 (M120 MLC) MLCs. Additionally, the impact of the tongue and groove design of the MLCs on dose has been characterized. Calculated transmission values for the HD120 MLC are 1.25% and 1.34% in the central part of the field for the 6 and 15 MV beam, respectively. The corresponding ionization chamber measurements result in a transmission of 1.20% and 1.35%. Good agreement has been found for the comparison between transmission profiles resulting from MC simulations and film measurements. The simulated and measured values for the penumbra agreed within <0.5 mm for all field sizes, depths, and beam energies, and a good agreement has been found between the measured and the calculated dose distributions for the IMRT case. The total energy spectra are almost identical for the three MLCs. However, the mean energy, fluence and energy fluence are significantly different. Due to the different leaf widths of the MLCs, the shape of these distributions is different, each representing its leave structure. Due to the increase in width from the inner to the outer HD120 MLC leaves, the fluence and energy fluence clearly decrease below the outer leaves. The MLC80 and the M120 MLC resulted in an increase of the fluence and energy fluence compared with those resulted for the HD120 MLC. The dose reduction can exceed 20% compared with the dose of the open field due to the tongue and groove design of the HD120 MLC. The HD120 MLC has been successfully implemented into the SMCP. Comparisons between MC calculations and measurements show very good agreement. The SMCP is now able to calculate accurate dose distributions for treatment plans using the HD120 MLC.Medical Physics 10/2011; 38(10):5311-20. · 2.83 Impact Factor -
Article: Validation of the Swiss Monte Carlo Plan for a static and dynamic 6 MV photon beam.
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ABSTRACT: Monte Carlo (MC) based dose calculations can compute dose distributions with an accuracy surpassing that of conventional algorithms used in radiotherapy, especially in regions of tissue inhomogeneities and surface discontinuities. The Swiss Monte Carlo Plan (SMCP) is a GUI-based framework for photon MC treatment planning (MCTP) interfaced to the Eclipse treatment planning system (TPS). As for any dose calculation algorithm, also the MCTP needs to be commissioned and validated before using the algorithm for clinical cases. Aim of this study is the investigation of a 6 MV beam for clinical situations within the framework of the SMCP. In this respect, all parts i.e. open fields and all the clinically available beam modifiers have to be configured so that the calculated dose distributions match the corresponding measurements. Dose distributions for the 6 MV beam were simulated in a water phantom using a phase space source above the beam modifiers. The VMC++ code was used for the radiation transport through the beam modifiers (jaws, wedges, block and multileaf collimator (MLC)) as well as for the calculation of the dose distributions within the phantom. The voxel size of the dose distributions was 2mm in all directions. The statistical uncertainty of the calculated dose distributions was below 0.4%. Simulated depth dose curves and dose profiles in terms of [Gy/MU] for static and dynamic fields were compared with the corresponding measurements using dose difference and γ analysis. For the dose difference criterion of ±1% of D(max) and the distance to agreement criterion of ±1 mm, the γ analysis showed an excellent agreement between measurements and simulations for all static open and MLC fields. The tuning of the density and the thickness for all hard wedges lead to an agreement with the corresponding measurements within 1% or 1mm. Similar results have been achieved for the block. For the validation of the tuned hard wedges, a very good agreement between calculated and measured dose distributions was achieved using a 1%/1mm criteria for the γ analysis. The calculated dose distributions of the enhanced dynamic wedges (10°, 15°, 20°, 25°, 30°, 45° and 60°) met the criteria of 1%/1mm when compared with the measurements for all situations considered. For the IMRT fields all compared measured dose values agreed with the calculated dose values within a 2% dose difference or within 1 mm distance. The SMCP has been successfully validated for a static and dynamic 6 MV photon beam, thus resulting in accurate dose calculations suitable for applications in clinical cases.Zeitschrift für Medizinische Physik 01/2011; 21(2):124-34. · 1.21 Impact Factor -
Article: Monte Carlo dose calculation on deforming anatomy.
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ABSTRACT: This article presents the implementation and validation of a dose calculation approach for deforming anatomical objects. Deformation is represented by deformation vector fields leading to deformed voxel grids representing the different deformation scenarios. Particle transport in the resulting deformed voxels is handled through the approximation of voxel surfaces by triangles in the geometry implementation of the Swiss Monte Carlo Plan framework. The focus lies on the validation methodology which uses computational phantoms representing the same physical object through regular and irregular voxel grids. These phantoms are chosen such that the new implementation for a deformed voxel grid can be compared directly with an established dose calculation algorithm for regular grids. Furthermore, separate validation of the aspects voxel geometry and the density changes resulting from deformation is achieved through suitable design of the validation phantom. We show that equivalent results are obtained with the proposed method and that no statistically significant errors are introduced through the implementation for irregular voxel geometries. This enables the use of the presented and validated implementation for further investigations of dose calculation on deforming anatomy.Zeitschrift für Medizinische Physik 01/2011; 21(2):113-23. · 1.21 Impact Factor
