DICOM-RT Plan Complexity Verification for Volumetric Modulated Arc Therapy ()
1. Introduction
Volumetric modulated arc therapy (VMAT) is a new radiotherapy technique which allows the generation of treatment plans of similar or better quality than those for fixed-field intensity modulated radiation therapy (IMRT) while reducing treatment time per fraction [1] .
Patient-specific quality assurance (QA) for VMAT plans is important in confirming dose distribution. Dosimetric verification is mostly often performed by delivering the treatment plan to a solid water phantom, measuring dosage with an ionization chamber and radiochromic film, and comparing the measured dose to the calculated dose [2] . Various QA devices for VMAT delivery verification have recently been introduced, including a cylindrical diode array (ArcCHECKTM, Sun Nuclear Corporation, Melbourne, FL, USA), two orthogonal diode arrays (Delta4TM phantom, Scandidos, Uppsala, Sweden), an octagonal phantom (OctaviusTM, PTW, Freiburg, Germany), and a two-dimensional ionization chamber array with a gantry-mounted detector matrix to measure fluence (MatriXX/COMPASSTM, IBA Dosimetry, Schwarzenbruck, Germany) [3] -[5] . However, these methods do not evaluate other plan parameters, such as gantry angle or multileaf collimator (MLC) position during VMAT delivery. Rather, we consider it important to analyze plan parameters that influence dosimetric accuracy.
Several authors have reported methods for assessing IMRT and VMAT plan complexity [6] -[12] . The complexity of IMRT and VMAT plans leads to a decreased gamma passing rate in dosimetric results [6] [7] [11] . Our previous study investigated dosimetry measurements of VMAT plan parameters using DICOM-RT verification and compared them to mechanical dose errors using a log file [13] . Despite the necessity of assessing VMAT plan complexity to ensure secure treatment planning, however, methods for quantitative assessment of VMAT plan complexity are still lacking.
The purpose of this study was to compare DICOM-RT plan parameters with VMAT dose measured with a 2D array detector.
2. Materials and Methods
2.1. Treatment Planning
We randomly selected ten prostate cancer, four maxillary sinus cancer, and four malignant pleural mesothelioma cases and created VMAT plans. These patients underwent computed tomography scanning (Aquilion LBTM, Toshiba, Otawara, Japan) of the area to be treated. Prostate cancer patients also underwent magnetic resonance imaging (MRI). Monte Carlo dose calculations (MonacoTM version 3.0, Elekta, Maryland Heights Missouri, USA) were performed on the CT data with a grid size of 3 mm and variance of 3%. A linear accelerator (SynergyTM, Elekta, Crawley, UK) with a 6 or 10 MV photon beam and an MLC leaf width of 10 mm was used for VMAT delivery. Treatment plans were transferred from the TPS to a Desktop Pro 7.01TM linac control system via a record and verify system (MosaiqTM version 1.6, Elekta, Sunnyvale, CA, USA).
2.1.1. Prostate Cancer
Gross tumor volume (GTV) was defined as visible tumor on CT and MRI. The clinical target volume (CTV) was defined as the prostate plus the proximal half of the seminal vesicles. The planning target volume (PTV) was formed by extending the CTV 10 mm outward in the axial plane except posteriorly in the region of the rectum-prostate interface, where the margin was set at 5 mm. The rectum, bladder, and femoral head were contoured as organs at risk (OAR). All plans consisted of a 360˚ clockwise arc with a 0˚ collimator angle. A dose of 74 Gy in 37 fractions was prescribed to 95% of the PTV, and maximum dose was restricted to 110% of the prescribed dose. Dose constraints for OARs were as follows: percentage of volume receiving 70 Gy (V70Gy) < 15%; V60Gy < 25%; V40 Gy < 50%; bladder, V65Gy < 25%, V40Gy < 50%. The range of PTVs was 53.7 - 117.4 cc. The range of Monitor Units (MU) was 415 - 612.
2.1.2. Maxillary Sinus Cancer
GTV was defined as visible tumor at the brain window settings. CTV was defined by adding an isotropic margin of 5 mm to the GTV. PTV was defined by adding an isotropic margin of 3 mm to the CTV. The normal brain, brainstem, spinal cord, optic chiasm, ipsilateral and contralateral eyes, and ipsilateral and contralateral optic nerves were contoured as OARs. A dose of 66 Gy in 33 fractions was prescribed to 95% of the PTV, and maximum dose was restricted to 110% of the prescribed dose. The dose-volume criteria used for the VMAT optimization can be found in our previous work [14] . We used gantry rotation angles of 180˚. The range of PTVs was 68.6 - 175.4 cc. The range of MU was 342 - 464.
2.1.3. Malignant Pleural Mesothelioma
The CTV was defined as the entire hemithoracic pleural space and involved nodal stations. The PTV was generally extended by 5 mm outside the CTV. The contralateral lung, liver, heart, esophagus, kidneys, and spinal cord were contoured as OARs. A dose of 54 Gy in 30 fractions was prescribed to 95% of the PTV, and maximum dose was restricted to 115% of the prescribed dose. Dose constraints for OARs were given as follows: contralateral lung, V5Gy < 60%, V20Gy < 10%, mean dose < 10.0 Gy; liver, V30Gy < 33%, mean dose < 30 Gy; heart, V45Gy < 50%, D1% < 60 Gy; contralateral kidney, V15Gy < 20%; and spinal cord, Dmax < 47 Gy. We used two gantry rotation angles of 210˚ to reduce dose to the contralateral lung. The first arc rotation was clockwise, and the second arc was counterclockwise. The range of PTVs was 1346.7 - 2920.2 cc. The range of MU was 634 - 994.
2.2. Calculation of Plan Parameters
We calculated plan parameters using MATLAB software (MathWorks Inc., Natick, MA, USA), defining the specified gantry angle position, MLC leaf position, and cumulative delivered MUs for each segment. We calculated the gantry angle position, MLC positions, and MUs with a DICOM-RT plan which calculated the gantry and MLC parameters for each segment. We defined the gantry parameters from differences in position between gantry angle positions for each segment (degrees/MU). We defined MLC parameters using the number of MU at different positions of adjacent MLC leaves for each segment (mm/MU). We defined comprehensive parameters from positions of adjacent MLC leaves between gantry angle positions for each segment (mm/degree). The absolute value of the 95th percentile of the plan parameter for VMAT was investigated.
2.3. Dosimetric Measurement
The dosimetric QA system used for dose verification measurements of the VMAT delivery consisted of a twodimensional multiple-diode array detector (MapCHECK2TM, Sun Nuclear Corporation, Melbourne, FL, USA) encased within a rectangular solid water phantom (MapPHAN2TM, Sun Nuclear Corporation, Melbourne, FL, USA). The enclosure phantom has a cross-sectional area of 30 × 30 cm2 parallel to the detector plane. Because the detector’s build-up material was not made of water equivalent, the depth from the phantom surface to the detector plane was adjusted to be a water-equivalent length of 10 cm on each side of the detector plane. Total dose distribution during VMAT delivery was measured in the coronal plane by the detector. The source-to-detector distance was 100 cm when the beam was delivered perpendicular to the detector plane. Gamma analysis with percent dose acceptance criteria and distance to agreement criteria of 3%/3mm and 2%/2mm (3%/3mm, 2%/2mm) passing criteria under a dose threshold of 10% of the maximum dose on each plane were used. The Van Dyk percent difference criterion was used [15] .
3. Results
Table 1 shows the gamma passing rate analysis of the dose calculated vs. measured by the detector. The gamma passing rate (3%/3mm) of all treatment sites was approximately 100% for the VMAT plan. Gamma passing rates using stricter gamma criteria (2%/2mm) were 97.4% (range: 93.8% - 100.0%), 97.8% (range: 94.3% - 99.4%) and 92.0% (range: 89.3% - 94.6%) for prostate cancer, maxillary sinus cancer, and malignant pleural mesothelioma VMAT deliveries, respectively. Malignant pleural mesothelioma showed lower passing rates than prostate and maxillary sinus cancers.
Figures 1-3 show frequency histograms of calculated parameters for prostate cancer, maxillary sinus cancer, and malignant pleural mesothelioma VMAT plans, respectively. Averages of 95th-percentile values for the calculated plan parameters for the three treatment sites are summarized in Table 2. Calculated degrees/MU for malignant pleural mesothelioma VMAT plans were lower than those for the other treatment sites. In contrast, calculated mm/MU and mm/degree for malignant pleural mesothelioma VMAT plans were higher than those for the other treatment sites.
Figures 4-6 show plots of calculated degrees/MU, mm/MU, and mm/degree as a function of the gamma passing rate (2%/2mm) for all cases. The gamma passing rate did not correlate with calculated degrees/MU or mm/MU, with a coefficient of determination (R2) of 0.27 and 0.39, respectively. Conversely, the gamma passing rate correlated with calculated mm/degree, with a coefficient of determination (R2) of 0.60.
4. Discussions
In this study, we investigated the relationship between plan parameters and dosimetric results for VMAT delivery. The dosimetric results (3%/3mm) showed VMAT was capable of delivering accurate doses for all treatment
Table 1. Gamma analysis passing rates measured by 2D diode detector. Percent dose acceptance criteria and distance to agreement criteria are (3%/3mm) and (2%/2mm) for clinical criteria and more restricted constraints, respectively. The analyzed data are displayed as mean with ranges in parentheses.
Table 2. Mean 95th-percentile values for DICOM-calculated plan parameters, with range in parentheses.
Figure 1. Frequency histograms of calculated degrees/MU for (a) prostate cancer, (b) maxillary sinus cancer, and (c) malignant pleural mesothelioma VMAT plans, respectively.
Figure 2. Frequency histograms of calculated mm/MU for (a) prostate cancer, (b) maxillary sinus cancer, and (c) malignant pleural mesothelioma VMAT plans, respectively.
Figure 3. Frequency histograms of calculated mm/degree for (a) prostate cancer, (b) maxillary sinus cancer, and (c) malignant pleural mesothelioma VMAT plans, respectively.
Figure 4. Gamma passing rate as a function of gantry angle divided by MU for each segment (degrees/MU). Gamma passing rate did not correlate with calculated degrees/MU.
Figure 5. Gamma passing rate as a function of MLC travel distance divided by MU for each segment (mm/MU). Gamma passing rate did not correlate with calculated mm/MU.
Figure 6. Gamma passing rate as a function of MLC travel distance divided by gantry angle for each segment (mm/degree). Gamma passing rates correlated with calculated mm/degree.
sites offered to patients. In our clinical practice, the tolerance level for passing rates is set to 95% at 3% and 3 mm gamma analysis. A 95% pass rate at 3% and 3 mm was obtained in 100% of the evaluated plans. This is clearly a good result which confirms the reliability of VMAT planning and delivery. The average gamma passing rates (2%/2mm) were 97.4%, 97.8%, and 92.0% for prostate cancer, maxillary sinus cancer, and malignant pleural mesothelioma VMAT deliveries, respectively. Malignant pleural mesothelioma VMAT delivery offered a slightly lower passing rate in the gamma index analysis. This finding is useful in understanding the beam characteristics of VMAT delivery. Limitations of our experimental devices include a lack of dosimetric accuracy for film dosimetry and spatial resolution issues for 2D diode arrays. Given the complexity of VMAT delivery, an accurate high resolution 3D quality assurance system would be ideal.
Plan parameters for VMAT differed for the three treatment sites. Calculated mm/MU and mm/degree for malignant pleural mesothelioma VMAT deliveries were higher than for other treatment sites, because malignant pleural mesothelioma is associated with a much larger PTV. Accordingly, degrees/MU for malignant pleural mesothelioma VMAT delivery were lower than those for prostate cancer and maxillary sinus cancer patients, because malignant pleural mesothelioma requires a larger total MU. Total MU can be easily used to determine beam complexity, but cannot be used to assess VMAT plan complexity, because beam path-length differs by patient and treatment site. Other indices for evaluating VMAT plan complexity are available. Masi et al. reported that average leaf travel (LT), modulation complexity score applied to VMAT (MCSv), MU value, and a multiplicative combination of LT and MCSv (LTMCS) were potential indices for scoring VMAT plan complexity using threshold values [11] .
The gamma passing rate showed a relationship with calculated mm/degree. The complexity of the VMAT plan is mainly due to the need to account for the motion of the gantry and MLC during rotation. Plan complexity is also affected by PTV size, locations of the tumor and OARs, required tumor dose, and dose-volume constraints of the OAR. Additionally, VMAT delivery also differs from IMRT delivery with regard to MLC motion. MLC motion in VMAT delivery is back and forth, resulting in a large amount of leaf travel; this movement may lead to discrepancies between calculated and delivered doses. Larger PTVs may need special attention to the increased mm/degree with MLC travel (Figure 7). Chen et al. reported that the average gamma passing rate decreased from 98% to 80% when the allowable leaf motion increased from 3 to 20 mm/degree [16] . If such motion were used to achieve a VMAT plan, control point angular separation would need to be more precise [11] [16] . Calculated mm/degree can be easily computed and understood.
5. Conclusion
We showed a relationship between DICOM-RT plan parameters and passing rates obtained by pretreatment dosimetric verification plans. DICOM-calculated mm/degree can be used to assess VMAT plan complexity, although increasing mm/degree may lead to increased dosimetric errors. We conclude that dose distribution calculated by
Figure 7. Calculated mm/degree as a function of PTV volume. Larger PTV volume led to a higher calculated mm/degree, resulting from a greater distance of leaf travel.
a TPS is more reliable at smaller mm/degree.
NOTES
*Corresponding author.