三束放疗：光子、电子和质子束的同步优化

TriB-RT: Simultaneous optimization of photon, electron and proton beams.

作者信息

Kueng R, Mueller S, Loebner H A, Frei D, Volken W, Aebersold D M, Stampanoni M F M, Fix M K, Manser P

机构信息

Division of Medical Radiation Physics and Department of Radiation Oncology, Inselspital, Bern University Hospital, and University of Bern, Bern, Switzerland.

Institute for Biomedical Engineering, University of Zurich and Swiss Federal Institute of Technology (ETH), Zurich, Switzerland.

出版信息

Phys Med Biol. 2021 Feb 5;66(4):045006. doi: 10.1088/1361-6560/ab936f.

DOI:10.1088/1361-6560/ab936f

PMID:32413883

Abstract

PURPOSE

To develop a novel treatment planning process (TPP) with simultaneous optimization of modulated photon, electron and proton beams for improved treatment plan quality in radiotherapy.

METHODS

A framework for fluence map optimization of Monte Carlo (MC) calculated beamlet dose distributions is developed to generate treatment plans consisting of photon, electron and spot scanning proton fields. Initially, in-house intensity modulated proton therapy (IMPT) plans are compared to proton plans created by a commercial treatment planning system (TPS). A triple beam radiotherapy (TriB-RT) plan is generated for an exemplary academic case and the dose contributions of the three particle types are investigated. To investigate the dosimetric potential, a TriB-RT plan is compared to an in-house IMPT plan for two clinically motivated cases. Benefits of TriB-RT for a fixed proton beam line with a single proton field are investigated.

RESULTS

In-house optimized IMPT are of at least equal or better quality than TPS-generated proton plans, and MC-based optimization shows dosimetric advantages for inhomogeneous situations. Concerning TriB-RT, for the academic case, the resulting plan shows substantial contribution of all particle types. For the clinically motivated case, improved sparing of organs at risk close to the target volume is achieved compared to IMPT (e.g. myelon and brainstem [Formula: see text] -37%) at cost of an increased low dose bath (healthy tissue V +22%). In the scenario of a fixed proton beam line, TriB-RT plans are able to compensate the loss in degrees of freedom to substantially improve plan quality compared to a single field proton plan.

CONCLUSION

A novel TPP which simultaneously optimizes photon, electron and proton beams was successfully developed. TriB-RT shows the potential for improved treatment plan quality and is especially promising for cost-effective single-room proton solutions with a fixed beamline in combination with a conventional linac delivering photon and electron fields.

摘要

目的

开发一种新型治疗计划流程（TPP），同时优化调强光子束、电子束和质子束，以提高放射治疗中的治疗计划质量。

方法

开发了一个用于蒙特卡罗（MC）计算的子野剂量分布通量图优化框架，以生成由光子、电子和点扫描质子野组成的治疗计划。最初，将内部调强质子治疗（IMPT）计划与商业治疗计划系统（TPS）创建的质子计划进行比较。针对一个典型学术病例生成了三束放射治疗（TriB-RT）计划，并研究了三种粒子类型的剂量贡献。为了研究剂量学潜力，将TriB-RT计划与两个临床相关病例的内部IMPT计划进行比较。研究了TriB-RT对于具有单个质子野的固定质子束线的益处。

结果

内部优化的IMPT计划质量至少与TPS生成的质子计划相当或更好，基于MC的优化在不均匀情况下显示出剂量学优势。关于TriB-RT，对于学术病例，所得计划显示所有粒子类型都有显著贡献。对于临床相关病例，与IMPT相比，实现了对靠近靶区的危及器官更好的保护（例如脊髓和脑干[公式：见正文]-37%），代价是低剂量区增加（健康组织V+22%）。在固定质子束线的情况下，与单野质子计划相比，TriB-RT计划能够补偿自由度的损失，从而显著提高计划质量。