School of Physics, National University of Ireland Galway, University Road, Galway, Ireland.
Joint Department of Physics, Institute of Cancer Research and Royal Marsden NHS Foundation Trust, London, UK.
Med Phys. 2017 Oct;44(10):5020-5033. doi: 10.1002/mp.12464. Epub 2017 Aug 20.
The aim of this study was to estimate changes in surface dose due to the presence of the Clarity Autoscan™ ultrasound (US) probe during prostate radiotherapy using Monte Carlo (MC) methods.
MC models of the Autoscan US probe were developed using the BEAMnrc/DOSXYZnrc code based on kV and MV CT images. CT datasets were converted to voxelized mass density phantoms using a CT number-to-mass density calibration. The dosimetric effect of the probe, in the contact region (an 8 mm × 12 mm single layer of voxels), was investigated using a phantom set-up mimicking two scenarios (a) a transperineal imaging configuration (radiation beam perpendicular to the central US axial direction), and (b) a transabdominal imaging configuration (radiation beam parallel to the central US axial direction). For scenario (a), the dosimetric effect was evaluated as a function of the probe to inferior radiation field edge distance. Clinically applicable distances from 5 mm separation to 2 mm overlap were determined from the radiotherapy plans of 27 patients receiving Clarity imaging. Overlaps of 3 to 14 (1 to 3 SD) mm were also considered to include the effect of interfraction motion correction. The influence of voxel size on surface dose estimation was investigated. Approved clinical plans from two prostate patients were used to simulate worst-case dosimetric impact of the probe when large couch translations were applied to correct for interfraction prostate motion.
The dosimetric impact of both the MV and kV probe models agreed within ±2% for both beam configurations. For scenario (a) and 1 mm voxel model, the probe gave mean dose increases of 1.2% to 4.6% (of the dose at isocenter) for 5 mm separation to 0 mm overlap in the probe-phantom contact region, respectively. This increased to 27.5% for the largest interfraction motion correction considered (14 mm overlap). For separations of ≥ 2 mm dose differences were < 2%. Simulated dose perturbations were found to be superficial; for the 14 mm overlap the dose increase reduced to < 3% at 5.0 mm within the phantom. For scenario (b), dose increases due to the probe were < 5% in all cases. The dose increase was underestimated by up to ~13% when the voxel size was increased from 1 mm to 3 mm. MC simulated dose to the PTV and OARs for the two clinical plans considered showed good agreement with commercial treatment planning system results (within 2%). Mean dose increases due to the presence of the probe, after the maximum interfraction motion correction, were ~16.3% and ~8.0%, in the contact region, for plan 1 and plan 2, respectively.
The presence of the probe results in superficial dose perturbations for patients with an overlap between the probe and the radiation field present in either the original treatment plan or due to translation of the radiation field to simulate correction of interfraction internal prostate motion.
本研究旨在使用蒙特卡罗(MC)方法估计由于前列腺放射治疗过程中存在 Clarity Autoscan™超声(US)探头而导致的表面剂量变化。
使用 BEAMnrc/DOSXYZnrc 代码基于千伏(kV)和兆伏(MV)CT 图像开发了 Autoscan US 探头的 MC 模型。将 CT 数据集转换为体素化质量密度体模,使用 CT 数到质量密度校准。通过模拟两种情况(a)经会阴成像配置(射线束垂直于中央 US 轴向)和(b)经腹成像配置(射线束平行于中央 US 轴向)的体模设置来研究探头在接触区域(8mm×12mm 单层体素)的剂量学效应。对于情况(a),评估了探头与下方辐射场边缘的距离对剂量的影响。从接受 Clarity 成像的 27 名患者的放射治疗计划中确定了从 5mm 分离到 2mm 重叠的临床适用距离。还考虑了 3 至 14(1 至 3 个标准差)mm 的重叠,以包括分次内运动校正的影响。研究了体素大小对表面剂量估算的影响。使用来自两名前列腺患者的批准临床计划来模拟当大的治疗床平移用于校正分次内前列腺运动时探头对最坏情况剂量学的影响。
对于两种光束配置,MV 和 kV 探头模型的剂量学影响均在±2%以内。对于情况(a)和 1mm 体素模型,当探头-体模接触区域的探头与体模之间的分离距离从 5mm 增加到 0mm 时,探头分别导致剂量增加 1.2%至 4.6%(在等中心处的剂量)。当考虑到最大的分次内运动校正时,这一数值增加到 27.5%(重叠 14mm)。对于分离距离≥2mm,剂量差异<2%。模拟的剂量扰动被发现是表面性的;在 14mm 重叠的情况下,在体模内的 5.0mm 处,剂量增加减少到<3%。对于情况(b),在所有情况下,由于探头导致的剂量增加均<5%。当体素尺寸从 1mm 增加到 3mm 时,剂量估计值低估了高达13%。对于考虑的两个临床计划,MC 模拟的 PTV 和 OAR 剂量与商业治疗计划系统的结果具有很好的一致性(<2%)。在经过最大分次内运动校正后,在接触区域中,计划 1 和计划 2 中由于探头的存在而导致的平均剂量增加分别为16.3%和~8.0%。
对于探头与射束之间存在重叠的患者,或者由于射束平移以模拟分次内前列腺内运动校正而导致探头与射束之间存在重叠的情况下,探头会导致表面剂量的小剂量波动。
