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前列腺癌的点扫描质子束治疗:旋转和平移对准误差的后果的治疗计划技术和分析。

Spot scanning proton beam therapy for prostate cancer: treatment planning technique and analysis of consequences of rotational and translational alignment errors.

机构信息

University of Texas-M.D. Anderson Cancer Center, Houston, USA.

出版信息

Int J Radiat Oncol Biol Phys. 2010 Oct 1;78(2):428-34. doi: 10.1016/j.ijrobp.2009.07.1696. Epub 2010 Jan 25.

DOI:10.1016/j.ijrobp.2009.07.1696
PMID:20100641
Abstract

PURPOSE

Conventional proton therapy with passively scattered beams is used to treat a number of tumor sites, including prostate cancer. Spot scanning proton therapy is a treatment delivery means that improves conformal coverage of the clinical target volume (CTV). Placement of individual spots within a target is dependent on traversed tissue density. Errors in patient alignment perturb dose distributions. Moreover, there is a need for a rational planning approach that can mitigate the dosimetric effect of random alignment errors. We propose a treatment planning approach and then analyze the consequences of various simulated alignment errors on prostate treatments.

METHODS AND MATERIALS

Ten control patients with localized prostate cancer underwent treatment planning for spot scanning proton therapy. After delineation of the clinical target volume, a scanning target volume (STV) was created to guide dose coverage. Errors in patient alignment in two axes (rotational and yaw) as well as translational errors in the anteroposterior direction were then simulated, and dose to the CTV and normal tissues were reanalyzed.

RESULTS

Coverage of the CTV remained high even in the setting of extreme rotational and yaw misalignments. Changes in the rectum and bladder V45 and V70 were similarly minimal, except in the case of translational errors, where, as a result of opposed lateral beam arrangements, much larger dosimetric perturbations were observed.

CONCLUSIONS

The concept of the STV as applied to spot scanning radiation therapy and as presented in this report leads to robust coverage of the CTV even in the setting of extreme patient misalignments.

摘要

目的

传统的被动散射质子治疗用于治疗许多肿瘤部位,包括前列腺癌。点扫描质子治疗是一种改善临床靶区(CTV)适形覆盖的治疗输送方式。靶区内单个点的放置取决于穿透组织的密度。患者对位误差会改变剂量分布。此外,需要有一种合理的规划方法来减轻随机对位误差的剂量学影响。我们提出了一种治疗计划方法,然后分析了各种模拟对位误差对前列腺治疗的影响。

方法和材料

10 名局部前列腺癌患者接受了点扫描质子治疗的计划。在勾画临床靶区后,创建了一个扫描靶区(STV)来指导剂量覆盖。然后模拟了患者在两个轴(旋转和偏航)以及前后方向的平移误差,重新分析了 CTV 和正常组织的剂量。

结果

即使在极端的旋转和偏航错位情况下,CTV 的覆盖仍然很高。直肠和膀胱的 V45 和 V70 的变化也同样很小,除了在平移误差的情况下,由于对侧横向射束的安排,观察到了更大的剂量学扰动。

结论

正如本报告中所提出的,STV 概念应用于点扫描放射治疗,即使在患者对位严重偏差的情况下,也能实现 CTV 的可靠覆盖。

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