前列腺癌根治性外照射放疗不同计划中，患者摆位和前列腺运动的系统不确定性对靶区剂量影响的比较。

Comparisons of the impact of systematic uncertainties in patient setup and prostate motion on doses to the target among different plans for definitive external-beam radiotherapy for prostate cancer.

作者信息

Zhu Su Yu, Mizowaki Takashi, Norihisa Yoshiki, Takayama Kenji, Nagata Yasushi, Hiraoka Masahiro

机构信息

Department of Radiation Oncology and Image-applied Therapy, Kyoto University, Sakyo, Kyoto, 606-8507, Japan.

出版信息

Int J Clin Oncol. 2008 Feb;13(1):54-61. doi: 10.1007/s10147-007-0724-4. Epub 2008 Feb 29.

DOI:10.1007/s10147-007-0724-4

PMID:18307020

Abstract

BACKGROUND

We aimed to compare the impact of systematic uncertainties in patient setup and prostate motion on three different external-beam radiotherapy protocols for prostate cancer.

METHODS

To simulate possible near-maximum systematic errors, the isocenter position was shifted to eight points with +/-1.65 SD of the integrated uncertainty value along each axis that was expected to include 5%-95% of the total systematic uncertainties in each direction. Five cases were analyzed for the three plans: an old three-dimensional conformal radiotherapy (3D-CRT) protocol (four-field plus dynamic arc), a new 3D-CRT protocol (dynamic arc), and an intensity-modulated radiotherapy (IMRT) protocol, respectively.

RESULTS

The averaged percentage volume covered by more than 95% of the prescription dose (V95) of the clinical target volume (CTV) for the original plans was 100% for all protocols. After simulating the errors, V95 of the CTV for IMRT cases was maintained at 100%. On the other hand, these values for the new and old 3D-CRT protocols were 93.1% and 63.2%, respectively. The values for the percentage prescription dose received by at least 95% volume (D95) of the CTV for the original plans were 100%, 98.4%, and 97.6% for the IMRT, new 3D-CRT, and old 3D-CRT plans, respectively. However, when the effects of the systematic errors were taken into consideration, the net decreases in the D95 values were 0.3%, 4.3%, and 8.1%, respectively.

CONCLUSION

The current IMRT protocol is considered to successfully compensate for systematic uncertainties. In contrast, the multi-leaf collimator (MLC) margins set for the old 3D-CRT protocol were not enough to ensure the actual delivery of the prescription dose to the CTV. Therefore, it is very important to include these issues in the plan design in the interpretation of clinical outcomes.

摘要

背景

我们旨在比较患者摆位和前列腺运动中的系统不确定性对三种不同的前列腺癌体外放射治疗方案的影响。

方法

为模拟可能的接近最大系统误差，将等中心位置沿每个轴移动到具有综合不确定度值的+/-1.65标准差的八个点，预计每个方向上的总系统不确定性的5%-95%包含在其中。对三种计划分析了五个病例：分别为旧的三维适形放疗（3D-CRT）方案（四野加动态弧形）、新的3D-CRT方案（动态弧形）和调强放疗（IMRT）方案。

结果

所有方案的原始计划中临床靶区（CTV）超过95%处方剂量覆盖的平均体积百分比（V95）为100%。模拟误差后，IMRT病例的CTV的V95维持在100%。另一方面，新的和旧的3D-CRT方案的这些值分别为93.1%和63.2%。原始计划中CTV至少95%体积接受的处方剂量百分比（D95）的值，IMRT、新3D-CRT和旧3D-CRT计划分别为100%、98.4%和97.6%。然而，考虑系统误差的影响时，D95值的净下降分别为0.3%、4.3%和8.1%。

结论

当前的IMRT方案被认为成功补偿了系统不确定性。相比之下，为旧的3D-CRT方案设置的多叶准直器（MLC）边缘不足以确保向CTV实际输送处方剂量。因此，在临床结果的解释中，将这些问题纳入计划设计非常重要。

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前列腺癌根治性外照射放疗不同计划中，患者摆位和前列腺运动的系统不确定性对靶区剂量影响的比较。

Comparisons of the impact of systematic uncertainties in patient setup and prostate motion on doses to the target among different plans for definitive external-beam radiotherapy for prostate cancer.

作者信息

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSION

背景

方法

结果

结论

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