用于治疗性碳离子束剂量计算的Geant4核相互作用模型的实验验证

Experimental validation of Geant4 nuclear interaction models in dose calculations of therapeutic carbon ion beams.

作者信息

Jia Yihan, Favaretto Martina, Hartl Lisa, Stock Markus, Georg Dietmar, Grevillot Loïc, Resch Andreas F

机构信息

MedAustron Ion Therapy Center, Wiener Neustadt, Austria.

Department of Radiation Oncology, Medical University of Vienna, Vienna, Austria.

出版信息

Med Phys. 2025 Jul;52(7):e17906. doi: 10.1002/mp.17906. Epub 2025 May 29.

DOI:10.1002/mp.17906

PMID:40442938

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12258006/

Abstract

BACKGROUND

The choice of nuclear interaction models in Monte Carlo simulations affects the dose calculation accuracy for light ion beam therapy.

PURPOSE

This study aimed to evaluate the dose calculation accuracy and simulation time of three GATE-RTiON/Geant4 physics lists for therapeutic carbon ion beams, assessing their suitability for independent dose calculation in patient-specific quality assurance (PSQA).

METHODS

The normalized beam models for physics lists QGSP_BIC_HP_EMZ, QGSP_INCLXX_HP_EMZ, and Shielding_EMZ were validated against measurements regarding the accuracy of range, spot size and reference dose. Normalized transversal dose profiles ( ) and field size factor (FSF) were compared with measurements. The accuracy of simulated target dose in 103 fields (various energies, field sizes, depths, and dose gradient complexity) of energy-modulated scanned beams was evaluated at 3181 positions. The median of global dose difference was calculated at different depth ranges.

RESULTS

The three physics lists with validated beam models showed similar accuracy in and FSF in the Bragg peak region and proximal depths, while QGSP_INCLXX_HP agreed most closely for in the fragmentation tail. Accounting for -related uncertainty, remained within ±1.1% for QGSP_INCLXX_HP, while exhibiting an overall increasing trend with depth for QGSP_BIC_HP (up to 2.3%) and a decreasing trend for Shielding (down to -4.1%), respectively. By tuning the number-of-primaries/monitor unit conversion ( ) as a function of energy, of QGSP_BIC_HP was reduced to within ±1.3%, at the cost of reduced accuracy in the simulated reference dose. The simulation time of Shielding was 1.8 times that of QGSP_BIC_HP and 1.5 times that of QGSP_INCLXX_HP.

CONCLUSIONS

QGSP_INCLXX_HP demonstrated high dosimetric accuracy in the target region of energy-modulated fields. QGSP_BIC_HP and Shielding showed physics model-related inaccuracies in simulated target dose. Additional tuning improved their target dose calculation accuracy with a trade-off of reference dose accuracy. The computationally efficient QGSP_INCLXX_HP and QGSP_BIC_HP are viable candidates for dose calculation applications of carbon ion beam therapy, such as in silico PSQA.

摘要

背景

蒙特卡罗模拟中核相互作用模型的选择会影响轻离子束治疗的剂量计算准确性。

目的

本研究旨在评估三种用于治疗性碳离子束的GATE-RTiON/Geant4物理列表的剂量计算准确性和模拟时间，评估它们在患者特异性质量保证（PSQA）中进行独立剂量计算的适用性。

方法

针对物理列表QGSP_BIC_HP_EMZ、QGSP_INCLXX_HP_EMZ和Shielding_EMZ的归一化束模型，在射程、光斑尺寸和参考剂量准确性方面与测量值进行了验证。将归一化横向剂量分布（）和射野尺寸因子（FSF）与测量值进行了比较。在3181个位置评估了能量调制扫描束的103个射野（各种能量、射野尺寸、深度和剂量梯度复杂性）中模拟靶区剂量的准确性。计算了不同深度范围内全局剂量差异的中位数。

结果

三种具有经过验证的束模型的物理列表在布拉格峰区域和近端深度的和FSF方面显示出相似的准确性，而QGSP_INCLXX_HP在碎片尾部的方面最为接近。考虑到与相关的不确定性，QGSP_INCLXX_HP的保持在±1.1%以内，而QGSP_BIC_HP随深度总体呈上升趋势（高达2.3%），Shielding则呈下降趋势（低至-4.1%）。通过将初级粒子数/监测单元转换（）作为能量的函数进行调整，QGSP_BIC_HP的降低到±1.3%以内，但代价是模拟参考剂量的准确性降低。Shielding的模拟时间是QGSP_BIC_HP的1.8倍，是QGSP_INCLXX_HP的1.5倍。

结论

QGSP_INCLXX_HP在能量调制射野的靶区显示出高剂量学准确性。QGSP_BIC_HP和Shielding在模拟靶区剂量方面表现出与物理模型相关的不准确性。额外调整提高了它们的靶区剂量计算准确性，但以牺牲参考剂量准确性为代价。计算效率高的QGSP_INCLXX_HP和QGSP_BIC_HP是碳离子束治疗剂量计算应用（如计算机模拟PSQA）的可行候选方案。