Han Min Cheol, Yun Yongdo, Kim Taeho, Han Soorim, Kim Changhwan, Kim Dong Wook, Lee Ho, Kim Hojin, Hong Chae-Seon, Kim Jin Sung
Department of Radiation Oncology, Yonsei Cancer Center, Heavy Ion Therapy Research Institute, Yonsei University College of Medicine, Seoul, Korea.
Department of Radiation Oncology, Yonsei Cancer Center, Heavy Ion Therapy Research Institute, Yonsei University College of Medicine, Seoul, Korea.
Phys Med. 2025 Aug;136:105051. doi: 10.1016/j.ejmp.2025.105051. Epub 2025 Jul 11.
Carbon-ion radiation therapy (CIRT) achieves potent tumor control by leveraging the unique physical and biological properties of carbon ions, such as the Bragg peak and high relative biological effectiveness. However, the presence of implanted markers or embolization coils can alter the beam range; therefore, clinical planning becomes complex. This study developed and validated a computer-aided design (CAD)-based Monte Carlo (MC) dose calculation system to accurately assess the geometric effects of materials inserted in CIRT.
A gold fiducial marker, typically used for prostate CIRT, was evaluated in both experimental and simulation settings. Gafchromic™ EBT3 films, placed at multiple depths in a solid-water phantom, were used to measure the dose distributions. Simultaneously, a Tornado Embolization Microcoil™ (Cook Medical) for hepatic transcatheter arterial chemoembolization was modeled using CAD and simulated by considering different orientations. MC simulations were performed using TOol for PArticle Simulation, with the beam parameters obtained from the Heavy Ion Therapy Center used for validation.
The film-based and MC-based dose profiles showed a similar range shift for the fiducial marker, despite the linear energy-transfer dependence of the films. The orientation of the microcoil slightly affected the range shift (∼0.1 mm). Moreover, CAD-based modeling demonstrated a more accurate representation than using simplified geometries.
The developed CAD-based MC simulation system is reliable and practical for evaluating the dosimetric impact of implanted materials on CIRT. Although MC simulations require extended computational time, the ability to incorporate absolute dose data and precisely model complex structures enhances the confidence in treatment planning.
碳离子放射治疗(CIRT)通过利用碳离子独特的物理和生物学特性,如布拉格峰和高相对生物学效应,实现有效的肿瘤控制。然而,植入标记物或栓塞线圈的存在会改变射束范围;因此,临床计划变得复杂。本研究开发并验证了一种基于计算机辅助设计(CAD)的蒙特卡罗(MC)剂量计算系统,以准确评估CIRT中插入材料的几何效应。
在实验和模拟环境中对一种通常用于前列腺CIRT的金基准标记物进行了评估。放置在固体水模体多个深度处的Gafchromic™ EBT3薄膜用于测量剂量分布。同时,使用CAD对用于肝动脉化疗栓塞的Tornado栓塞微线圈™(库克医疗公司)进行建模,并考虑不同方向进行模拟。使用粒子模拟工具进行MC模拟,其射束参数从用于验证的重离子治疗中心获得。
尽管薄膜存在线能量转移依赖性,但基于薄膜和基于MC的剂量分布曲线显示基准标记物的射程偏移相似。微线圈的方向对射程偏移有轻微影响(约0.1毫米)。此外,基于CAD的建模比使用简化几何形状更准确地表示。
所开发的基于CAD的MC模拟系统对于评估植入材料对CIRT剂量学的影响是可靠且实用的。尽管MC模拟需要较长的计算时间,但纳入绝对剂量数据和精确模拟复杂结构的能力增强了对治疗计划的信心。
