Dose perturbations at tissue interfaces during parallel linac-MR treatments: The “Lateral Scatter Electron Return Effect” (LS-ERE)

IF 3.2 2区医学 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

Medical physics Pub Date : 2024-08-17 DOI:10.1002/mp.17363

Stephen Steciw, B. Gino Fallone, Eugene Yip

{"title":"Dose perturbations at tissue interfaces during parallel linac-MR treatments: The “Lateral Scatter Electron Return Effect” (LS-ERE)","authors":"Stephen Steciw, B. Gino Fallone, Eugene Yip","doi":"10.1002/mp.17363","DOIUrl":null,"url":null,"abstract":"<div>\n \n \n <section>\n \n <h3> Background</h3>\n \n <p>Magnetic resonance (MR) imaging devices have been integrated with medical linear accelerators (linac) in radiation therapy. Both perpendicular linac-MR (LMR-B⊥) and parallel (LMR-B∥) systems exist, where due to the MR's magnetic field dose can be perturbed in the patient. Dose perturbations from the electron return effect (ERE) and electron streaming effects (ESEs) are present in LMR-B⊥ systems, where a dose collimating effect has been observed in LMR-B∥ systems\n.</p>\n </section>\n \n <section>\n \n <h3> Purpose</h3>\n \n <p>To report on an asymmetric dose perturbation which is present at the interface between two different materials during treatment in <i>parallel</i> linac-MR (LMR-B∥) systems. To the best of our knowledge, these asymmetric dose effects, “Lateral Scattered Electron Return Effect” (LS-ERE) have not been previously reported.</p>\n </section>\n \n <section>\n \n <h3> Methods</h3>\n \n <p>BEAMnrc and EGSnrc Monte Carlo (MC) radiation transport codes were used with the EEMF macro to emulate a 6 FFF beam from the 0.5-T Alberta linac-MR (LMR). Simulations were performed at 0.5 and 1.5 T in several different phantom material–interface combinations and field sizes including from modulated MLC-like fields. MC simulations quantified LS-ERE in patient CT datasets for the head, breast, and lung. LS-ERE cancellation techniques were investigated. LS-ERE asymmetries were quantified by subtracting an antiparallel dose from the parallel dose, dividing by two and normalizing to the global 0-T maximum dose. GafChromic film measurements were made in the 0.5-T Alberta LMR-B∥ system using solid water at the water–air interface to validate MC simulations. ERE was simulated for an emulated LMR-B⊥ system and compared to LMR-B∥ dose perturbations.</p>\n </section>\n \n <section>\n \n <h3> Results</h3>\n \n <p>LS-ERE is mostly independent of field size for fields >1 × 1 cm<sup>2</sup>. For 5 × 5-cm<sup>2</sup> fields at 0.5T/1.5T, LS-ERE asymmetries are ≤±6.9%/6.9% at bone–air and ≤±9.0%/7.0% at tissue–air for nonair doses, and ≤±4.1%/5.5% at tissue–lung interfaces. LS-ERE increases as the density gradient increases, where the magnitude and extent of LS-ERE are reduced as field strength increases. For a single 5 × 5-cm<sup>2</sup> field at 0.5T/1.5T, the LS-ERE asymmetry is ≤±10.2%/8.5% at the tissue–air sinus interface for head, ≤±4.2%/5.3% at the spine–lung interface for the lung, and ≤±5.7%/4.9% at the skin–air interface for a breast tangent plan at 0.5T/1.5T. POP fields mostly remove LS-ERE asymmetries, with magnetic field reversal during treatment being the most effective method. Skin dose was investigated and compared to 0-T treatments for 0.5T/1.5T LMR-B∥ single field breast and head treatments. Including all dosimetric magnetic field perturbations, a 21%/24% and 22%/22% increase in skin dose to head and breast, respectively, was observed, of which LS-ERE is responsible for approximately 30% of the total. Measured LS-ERE asymmetries and dose enhancements at the water–air interface using GafChromic film were in excellent agreement with MC simulations. ERE in 1.5-T LMR-B⊥ systems are on average 5.5 times larger than total dose perturbations at 0.5 T in LMR-B∥ systems.</p>\n </section>\n \n <section>\n \n <h3> Conclusion</h3>\n \n <p>LS-ERE is present at the interface between materials and awareness of LS-ERE is crucial for proper TPS evaluation for LMR-B∥ treatments, especially in areas where large tissue density gradients exist.</p>\n </section>\n </div>","PeriodicalId":18384,"journal":{"name":"Medical physics","volume":"51 11","pages":"8506-8523"},"PeriodicalIF":3.2000,"publicationDate":"2024-08-17","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1002/mp.17363","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Medical physics","FirstCategoryId":"3","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1002/mp.17363","RegionNum":2,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING","Score":null,"Total":0}

引用次数: 0

Abstract

Background

Magnetic resonance (MR) imaging devices have been integrated with medical linear accelerators (linac) in radiation therapy. Both perpendicular linac-MR (LMR-B⊥) and parallel (LMR-B∥) systems exist, where due to the MR's magnetic field dose can be perturbed in the patient. Dose perturbations from the electron return effect (ERE) and electron streaming effects (ESEs) are present in LMR-B⊥ systems, where a dose collimating effect has been observed in LMR-B∥ systems .

Purpose

To report on an asymmetric dose perturbation which is present at the interface between two different materials during treatment in parallel linac-MR (LMR-B∥) systems. To the best of our knowledge, these asymmetric dose effects, “Lateral Scattered Electron Return Effect” (LS-ERE) have not been previously reported.

Methods

BEAMnrc and EGSnrc Monte Carlo (MC) radiation transport codes were used with the EEMF macro to emulate a 6 FFF beam from the 0.5-T Alberta linac-MR (LMR). Simulations were performed at 0.5 and 1.5 T in several different phantom material–interface combinations and field sizes including from modulated MLC-like fields. MC simulations quantified LS-ERE in patient CT datasets for the head, breast, and lung. LS-ERE cancellation techniques were investigated. LS-ERE asymmetries were quantified by subtracting an antiparallel dose from the parallel dose, dividing by two and normalizing to the global 0-T maximum dose. GafChromic film measurements were made in the 0.5-T Alberta LMR-B∥ system using solid water at the water–air interface to validate MC simulations. ERE was simulated for an emulated LMR-B⊥ system and compared to LMR-B∥ dose perturbations.

Results

LS-ERE is mostly independent of field size for fields >1 × 1 cm². For 5 × 5-cm² fields at 0.5T/1.5T, LS-ERE asymmetries are ≤±6.9%/6.9% at bone–air and ≤±9.0%/7.0% at tissue–air for nonair doses, and ≤±4.1%/5.5% at tissue–lung interfaces. LS-ERE increases as the density gradient increases, where the magnitude and extent of LS-ERE are reduced as field strength increases. For a single 5 × 5-cm² field at 0.5T/1.5T, the LS-ERE asymmetry is ≤±10.2%/8.5% at the tissue–air sinus interface for head, ≤±4.2%/5.3% at the spine–lung interface for the lung, and ≤±5.7%/4.9% at the skin–air interface for a breast tangent plan at 0.5T/1.5T. POP fields mostly remove LS-ERE asymmetries, with magnetic field reversal during treatment being the most effective method. Skin dose was investigated and compared to 0-T treatments for 0.5T/1.5T LMR-B∥ single field breast and head treatments. Including all dosimetric magnetic field perturbations, a 21%/24% and 22%/22% increase in skin dose to head and breast, respectively, was observed, of which LS-ERE is responsible for approximately 30% of the total. Measured LS-ERE asymmetries and dose enhancements at the water–air interface using GafChromic film were in excellent agreement with MC simulations. ERE in 1.5-T LMR-B⊥ systems are on average 5.5 times larger than total dose perturbations at 0.5 T in LMR-B∥ systems.

Conclusion

LS-ERE is present at the interface between materials and awareness of LS-ERE is crucial for proper TPS evaluation for LMR-B∥ treatments, especially in areas where large tissue density gradients exist.

Abstract Image

查看原文本刊更多论文

平行直列加速器-MR 治疗过程中组织界面的剂量扰动：侧向散射电子返回效应"（LS-ERE）。

背景：在放射治疗中，磁共振（MR）成像设备已与医用直线加速器（linac）集成。目前存在垂直直线加速器-磁共振（LMR-B⊥）和平行直线加速器-磁共振（LMR-B∥）系统，由于磁共振的磁场，患者体内的剂量会受到干扰。LMR-B⊥系统中存在电子回流效应（ERE）和电子流效应（ESE）引起的剂量扰动，在LMR-B∥系统中观察到了剂量准直效应。目的：报告平行直列加速器-MR（LMR-B∥）系统治疗过程中两种不同材料界面上出现的非对称剂量扰动。据我们所知，这些非对称剂量效应，即 "侧向散射电子返回效应"（LS-ERE），以前从未报道过：方法：使用 BEAMnrc 和 EGSnrc 蒙特卡罗（MC）辐射传输代码和 EEMF 宏来模拟来自 0.5-T Alberta 直列加速器-MR（LMR）的 6 FFF 射束。模拟在 0.5 和 1.5 T 条件下进行，采用了几种不同的模型材料-界面组合和场大小，包括调制 MLC 样场。MC 模拟量化了患者头部、乳房和肺部 CT 数据集中的 LSERE。研究了 LSERE 消除技术。通过从平行剂量中减去反平行剂量、除以二并归一于全局 0-T 最大剂量来量化 LS-ERE 的不对称性。在 0.5-T Alberta LMR-B∥ 系统中使用水气界面上的固态水进行了 GafChromic 膜测量，以验证 MC 模拟。模拟了模拟 LMR-B⊥ 系统的ERE，并与 LMR-B∥ 剂量扰动进行了比较：结果：对于大于 1 × 1 平方厘米的磁场，LS-ERE 与磁场大小基本无关。对于 0.5T/1.5T 下的 5 × 5 平方厘米场，LS-ERE 不对称率在骨-空气处为≤±6.9%/6.9%，在组织-空气处为≤±9.0%/7.0%；在组织-肺界面处为≤±4.1%/5.5%。LS-ERE随着密度梯度的增加而增加，其中LS-ERE的幅度和范围随着场强的增加而减小。对于 0.5T/1.5T 下的单个 5 × 5 平方厘米场，头部组织-空气窦界面的 LS-ERE 不对称度为≤±10.2%/8.5%，肺部脊柱-肺界面的 LS-ERE 不对称度为≤±4.2%/5.3%，而对于 0.5T/1.5T 下的乳房切线平面，皮肤-空气界面的 LS-ERE 不对称度为≤±5.7%/4.9%。POP 磁场可消除大部分 LSERE 不对称，治疗过程中的磁场反转是最有效的方法。对 0.5T/1.5T LMR-B∥ 单磁场乳房和头部治疗的皮肤剂量进行了研究，并与 0-T 治疗进行了比较。包括所有剂量测定磁场扰动在内，观察到头部和乳房的皮肤剂量分别增加了21%/24%和22%/22%，其中LS-ERE约占总剂量的30%。使用 GafChromic 薄膜测量到的 LS-ERE 不对称和水-空气界面的剂量增强与 MC 模拟结果非常吻合。1.5 T LMR-B⊥ 系统中的ERE平均比 0.5 T LMR-B∥ 系统中的总剂量扰动大 5.5 倍：结论：LS-ERE 存在于材料之间的界面，认识到 LS-ERE 对于正确评估 LMR-B∥ 治疗的 TPS 至关重要，尤其是在存在较大组织密度梯度的区域。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Medical physics 医学-核医学

CiteScore

6.80

自引率

15.80%

发文量

660

审稿时长

1.7 months

期刊介绍： Medical Physics publishes original, high impact physics, imaging science, and engineering research that advances patient diagnosis and therapy through contributions in 1) Basic science developments with high potential for clinical translation 2) Clinical applications of cutting edge engineering and physics innovations 3) Broadly applicable and innovative clinical physics developments Medical Physics is a journal of global scope and reach. By publishing in Medical Physics your research will reach an international, multidisciplinary audience including practicing medical physicists as well as physics- and engineering based translational scientists. We work closely with authors of promising articles to improve their quality.