质子治疗小儿患者中靶运动与笔形束扫描的相互作用效应

Interplay Effect of Target Motion and Pencil-Beam Scanning in Proton Therapy for Pediatric Patients.

作者信息

Boria Andrew J, Uh Jinsoo, Pirlepesov Fakhriddin, Stuckey James C, Axente Marian, Gargone Melissa A, Hua Chia-Ho

机构信息

Department of Radiation Oncology, St. Jude Children's Research Hospital, Memphis, TN, USA.

School of Health Sciences, Purdue University, West Lafayette, IN, USA.

出版信息

Int J Part Ther. 2018 Fall;5(2):1-10. doi: 10.14338/IJPT-17-00030.1. Epub 2018 Nov 30.

DOI:10.14338/IJPT-17-00030.1

PMID:30800718

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6383772/

Abstract

PURPOSE

To investigate the effect of interplay between spot-scanning proton beams and respiration-induced tumor motion on internal target volume coverage for pediatric patients.

MATERIALS AND METHODS

Photon treatments for 10 children with representative tumor motions (1-13 mm superior-inferior) were replanned to simulate single-field uniform dose- optimized proton therapy. Static plans were designed by using average computed tomography (CT) data sets created from 4D CT data to obtain nominal dose distributions. The motion interplay effect was simulated by assigning each spot in the static plan delivery sequence to 1 of 10 respiratory-phase CTs, using the actual patient breathing trace and specifications of a synchrotron-based proton system. Dose distributions for individual phases were deformed onto the space of the average CT and summed to produce the accumulated dose distribution, whose dose-volume histogram was compared with the one from the static plan.

RESULTS

Tumor motion had minimal impact on the internal target volume hot spot (D2), which deviated by <3% from the nominal values of the static plans. The cold spot (D98) was also minimally affected, except in 2 patients with diaphragmatic tumor motion exceeding 10 mm. The impact on tumor coverage was more pronounced with respect to the V99 rather than the V95. Decreases of 10% to 49% in the V99 occurred in multiple patients for whom the beam paths traversed the lung-diaphragm interface and were, therefore, more sensitive to respiration-induced changes in the water equivalent path length. Fractionation alone apparently did not mitigate the interplay effect beyond 6 fractions.

CONCLUSION

The interplay effect is not a concern when delivering scanning proton beams to younger pediatric patients with tumors located in the retroperitoneal space and tumor motion of <5 mm. Children and adolescents with diaphragmatic tumor motion exceeding 10 mm require special attention, because significant declines in target coverage and dose homogeneity were seen in simulated treatments of such patients.

摘要

目的

研究点扫描质子束与呼吸诱导的肿瘤运动之间的相互作用对儿科患者内部靶区覆盖的影响。

材料与方法

对10例具有代表性肿瘤运动（上下方向1 - 13毫米）的儿童进行光子治疗重新计划，以模拟单野均匀剂量优化质子治疗。通过使用从4D CT数据创建的平均计算机断层扫描（CT）数据集来设计静态计划，以获得标称剂量分布。利用实际患者呼吸轨迹和基于同步加速器的质子系统的规格，将静态计划照射序列中的每个点分配到10个呼吸期CT中的1个，模拟运动相互作用效应。将各个阶段的剂量分布变形到平均CT的空间上并求和，以产生累积剂量分布，将其剂量体积直方图与静态计划的进行比较。

结果

肿瘤运动对内部靶区热点（D2）的影响最小，其偏离静态计划标称值<3%。冷点（D98）也受到最小影响，除了2例膈肌肿瘤运动超过10毫米的患者。对肿瘤覆盖的影响在V99方面比V95更明显。对于多个束路径穿过肺 - 膈肌界面的患者，V99下降了10%至49%，因此对呼吸诱导的水等效路径长度变化更敏感。仅分割照射显然不能减轻超过6次分割时的相互作用效应。

结论

对于肿瘤位于腹膜后间隙且肿瘤运动<5毫米的年幼儿科患者，在输送扫描质子束时，相互作用效应不是问题。膈肌肿瘤运动超过10毫米的儿童和青少年需要特别关注，因为在此类患者的模拟治疗中观察到靶区覆盖和剂量均匀性显著下降。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/0c2a/6874190/b1d3d64c2c16/i2331-5180-5-2-1-f01.jpg

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质子治疗小儿患者中靶运动与笔形束扫描的相互作用效应

Interplay Effect of Target Motion and Pencil-Beam Scanning in Proton Therapy for Pediatric Patients.

作者信息

机构信息

出版信息

PURPOSE

MATERIALS AND METHODS

RESULTS

CONCLUSION

目的

材料与方法

结果

结论

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