Lowther Nicholas, Myronakis Marios, Harris Thomas, Berbeco Ross, Jacobson Matt, Etemadpour Roshanak, Ferguson Dianne, Fueglistaller Rony, Arroyo Pablo Corral, Birrer Vera, Bruegger Raphael, Morf Daniel, Lehmann Mathias, Hu Yue-Houng
Department of Radiation Oncology, Brigham and Women's Hospital, Dana-Farber Cancer Institute, Harvard Medical School, Boston, USA.
Varian Medical Systems Imaging Laboratory, Baden-Dattwil, Switzerland.
Med Phys. 2025 Sep;52(9):e18093. doi: 10.1002/mp.18093.
Online adaptive radiation therapy (ART) offers a paradigm shift in radiotherapy by enabling adjustments to the planned dose based on daily anatomical variation. In the context of cone-beam computed tomography (CBCT) for online ART on a standard linac, thoracic and abdominal treatment sites in particular present unique challenges due to the typically large treatment volumes, mobile anatomy, scatter-induced image quality degradation, and hounsfield unit (HU) limitations. A recent hardware and software upgrade for a standard linac, Varian TrueBeam (TB) v4.1 HyperSight, seeks to overcome these challenges through implementation of a larger kV imager panel (i.e., 43 × 43 cm), increased gantry speed (i.e., from 6 to 9°/s), and improved HU accuracy. However, investigation of the new upgrade is essential to harness the full potential of these advancements.
We report on physical characterization and a digital Monte Carlo (MC) model of the new imaging system hardware.
The open-source GEANT4 Application for Tomographic Emission (GATE) MC toolkit, which allows scintillation systems, including CBCT, to be accurately modeled, was utilized. All physical components of the new TB upgrade were modeled from vendor-provided geometry and material specifications. The model was validated using physical measurements acquired on the upgraded system. Specifically, the modulation transfer function (MTF), noise power spectrum (NPS), profiles across the physically larger detector, scatter-to-primary ratio (SPR), and loss in spatial resolution as a function of the increased gantry speed and an object's distance from isocenter. The latter was quantified using the pixel distance between the 15% and 85% intensities of the over-sampled edge spread function (ESF) for source-to-edge-phantom distances (SEPDs) of 80, 100, and 120 cm. Focal spot motion was also characterized by the MTF at SEPD of 100 cm.
The MTF was 0.901 and 0.889 mm for the measurement and simulation, respectively, for a 125 kVp beam. The normalized root mean square error (nRMSE) was 0.013. While small, the model displayed degraded spatial resolution accuracy for other beam qualities. The general trend of the physically measured normalized noise power spectrum (nNPS) curves was reproduced with the model at all beam energies; however, a small systematic offset was observed. Excellent agreement was observed between central-image x- and y-profiles of measured and MC-generated projections, indicating correct modeling of the larger imaging detector. Simulated SPRs closely agreed with those of measurement. The measured ESF widths for the 6 and 9°/s acquisitions were both 2.5 pixels, indicating no reduction in spatial resolution in the projection space as a result of the increased acquisition speed. The effect of focal spot blurring due to increased gantry speed was accurately modeled, considering ESF width differences no larger than 0.5 pixels were observed for all SEPDs. Decreased spatial resolution in projection images was observed for SEPDs of 80 and 120 cm compared to 100 cm.
The MC model of the novel TB 4.1 HyperSight upgrade accurately reproduced physical measurements acquired on the new system. The model will be used alongside physical testing on the new TB platform, working towards an online CBCT-based ART protocol for thoracic and abdominal treatments.
在线自适应放射治疗(ART)通过根据每日解剖结构变化调整计划剂量,为放射治疗带来了范式转变。在标准直线加速器上用于在线ART的锥形束计算机断层扫描(CBCT)的背景下,胸部和腹部治疗部位尤其面临独特挑战,因为治疗体积通常较大、解剖结构可移动、散射导致图像质量下降以及亨氏单位(HU)存在局限性。标准直线加速器Varian TrueBeam(TB)v4.1 HyperSight最近进行了硬件和软件升级,旨在通过采用更大的千伏成像面板(即43×43厘米)、提高机架速度(即从6°/秒提高到9°/秒)以及提高HU精度来克服这些挑战。然而,对新升级进行研究对于充分发挥这些进步的潜力至关重要。
我们报告新成像系统硬件的物理特性和数字蒙特卡罗(MC)模型。
使用开源的用于断层发射的GEANT4应用程序(GATE)MC工具包,该工具包允许对包括CBCT在内的闪烁系统进行精确建模。新TB升级的所有物理组件均根据供应商提供的几何形状和材料规格进行建模。使用在升级系统上获取的物理测量数据对模型进行验证。具体而言,调制传递函数(MTF)、噪声功率谱(NPS)、在物理尺寸更大的探测器上的剖面、散射与原发射线比率(SPR)以及作为机架速度增加和物体与等中心距离的函数的空间分辨率损失。后者使用源到边缘模体距离(SEPD)为80、100和120厘米时过采样边缘扩展函数(ESF)的15%和85%强度之间的像素距离进行量化。焦点斑运动也通过100厘米SEPD处的MTF进行表征。
对于125 kVp束,测量和模拟的MTF分别为0.901和0.889毫米。归一化均方根误差(nRMSE)为0.013。虽然较小,但该模型显示出其他束质的空间分辨率精度有所下降。在所有束能量下,模型均再现了物理测量的归一化噪声功率谱(nNPS)曲线的总体趋势;然而,观察到存在小的系统偏差。在测量和MC生成的投影的中心图像x和y剖面上观察到极佳的一致性,表明对更大的成像探测器进行了正确建模。模拟的SPR与测量值密切吻合。6°/秒和9°/秒采集的测量ESF宽度均为2.5像素,表明采集速度增加并未导致投影空间中的空间分辨率降低。考虑到在所有SEPD下观察到的ESF宽度差异不超过0.5像素,准确模拟了由于机架速度增加导致的焦点斑模糊效应。与100厘米相比,80厘米和120厘米的SEPD在投影图像中观察到空间分辨率降低。
新型TB 4.1 HyperSight升级的MC模型准确再现了在新系统上获取的物理测量数据。该模型将与新TB平台上的物理测试一起使用,致力于制定基于在线CBCT的胸部和腹部治疗ART方案。
