Ochoa-Parra Pamela, Schweins Luisa, Abbani Nelly, Ghesquière-Diérickx Laura, Gehrke Tim, Jakubek Jan, Marek Lukas, Granja Carlos, Dinkel Fabian, Echner Gernot, Winter Marcus, Mairani Andrea, Harrabi Semi, Jäkel Oliver, Debus Jürgen, Martišíková Mária, Kelleter Laurent
Heidelberg Institute for Radiation Oncology HIRO, National Center for Radiation Research in Oncology NCRO, Heidelberg, Germany.
Department of Physics and Astronomy, Heidelberg University, Heidelberg, Germany.
Med Phys. 2024 Dec;51(12):9217-9229. doi: 10.1002/mp.17408. Epub 2024 Sep 22.
In-vivo monitoring methods of carbon ion radiotherapy (CIRT) includes explorations of nuclear reaction products generated by carbon-ion beams interacting with patient tissues. Our research group focuses on in-vivo monitoring of CIRT using silicon pixel detectors. Currently, we are conducting a prospective clinical trial as part of the In-Vivo Monitoring project (InViMo) at the Heidelberg Ion Beam Therapy Center (HIT) in Germany. We are using an innovative, in-house developed, non-contact fragment tracking system with seven mini-trackers based on the Timepix3 technology developed at CERN.
This article focuses on the implementation of the mini-tracker in Monte Carlo (MC) based on FLUKA simulations to monitor secondary charged nuclear fragments in CIRT. The main objective is to systematically evaluate the simulation accuracy for the InViMo project.
The implementation involved integrating the mini-tracker geometry and the scoring mechanism into the FLUKA MC simulation, utilizing the finely tuned HIT beam line. The systematic investigation included varying mini-tracker angles (from to in steps) during the irradiation of a head-sized phantom with therapeutic carbon-ion pencil beams. To evaluate our implemented FLUKA framework, a comparison was made between the experimental data and data obtained from MC simulations. To ensure the fidelity of our comparison, experiments were performed at the HIT using the parameters and setup established in the simulations.
Our research demonstrates high accuracy in reproducing characteristic behaviors and dependencies of the monitoring method in terms of fragment distributions in the mini-tracker, track angles, emission profiles, and fragment numbers. Discrepancies in the number of detected fragments between the experimental data and the data obtained from MC simulations are less than 4% for the angles of interest in the InViMo detection system.
Our study confirms the potential of our simulation framework to investigate the performance of monitoring inter-fractional anatomical changes in patients undergoing CIRT using secondary nuclear charged fragments escaping from the irradiated patient.
碳离子放射治疗(CIRT)的体内监测方法包括对碳离子束与患者组织相互作用产生的核反应产物的探索。我们的研究小组专注于使用硅像素探测器对CIRT进行体内监测。目前,我们正在德国海德堡离子束治疗中心(HIT)开展一项前瞻性临床试验,作为体内监测项目(InViMo)的一部分。我们正在使用一种创新的、内部开发的非接触式碎片跟踪系统,该系统有七个基于欧洲核子研究组织(CERN)开发的Timepix3技术的微型跟踪器。
本文重点介绍基于FLUKA模拟的微型跟踪器在蒙特卡罗(MC)中的实现,以监测CIRT中的次级带电核碎片。主要目的是系统评估InViMo项目的模拟准确性。
实现过程包括将微型跟踪器的几何形状和计分机制集成到FLUKA MC模拟中,并利用经过精细调整的HIT束流线路。系统研究包括在用治疗性碳离子笔形束照射头部大小的体模时,改变微型跟踪器的角度(以 步长从 到 )。为了评估我们实现的FLUKA框架,将实验数据与MC模拟获得的数据进行了比较。为确保比较的准确性,在HIT使用模拟中确定的参数和设置进行了实验。
我们的研究表明,在微型跟踪器中的碎片分布、轨道角度、发射轮廓和碎片数量方面,在重现监测方法的特征行为和相关性方面具有很高的准确性。对于InViMo检测系统中感兴趣的角度,实验数据与MC模拟获得的数据之间检测到的碎片数量差异小于4%。
我们的研究证实了我们的模拟框架在利用从受照射患者体内逸出的次级核带电碎片研究接受CIRT治疗的患者分次间解剖变化监测性能方面的潜力。
