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一种安装在质子治疗旋转机架端口上的在线束 PET 系统的开发和临床应用。

The development and clinical use of a beam ON-LINE PET system mounted on a rotating gantry port in proton therapy.

机构信息

Particle Therapy Division, Research Center for Innovative Oncology, National Cancer Center, Kashiwa.

出版信息

Int J Radiat Oncol Biol Phys. 2010 Jan 1;76(1):277-86. doi: 10.1016/j.ijrobp.2009.05.065.

DOI:10.1016/j.ijrobp.2009.05.065
PMID:20005459
Abstract

PURPOSE

To verify the usefulness of our developed beam ON-LINE positron emission tomography (PET) system mounted on a rotating gantry port (BOLPs-RGp) for dose-volume delivery-guided proton therapy (DGPT).

METHODS AND MATERIALS

In the proton treatment room at our facility, a BOLPs-RGp was constructed so that a planar PET apparatus could be mounted with its field of view covering the iso-center of the beam irradiation system. Activity measurements were performed in 48 patients with tumors of the head and neck, liver, lungs, prostate, and brain. The position and intensity of the activity were measured using the BOLPs-RGp during the 200 s immediately after the proton irradiation.

RESULTS

The daily measured activity images acquired by the BOLPs-RGp showed the proton irradiation volume in each patient. Changes in the proton-irradiated volume were indicated by differences between a reference activity image (taken at the first treatment) and the daily activity-images. In the case of head-and-neck treatment, the activity distribution changed in the areas where partial tumor reduction was observed. In the case of liver treatment, it was observed that the washout effect in necrotic tumor cells was slower than in non-necrotic tumor cells.

CONCLUSIONS

The BOLPs-RGp was developed for the DGPT. The accuracy of proton treatment was evaluated by measuring changes of daily measured activity. Information about the positron-emitting nuclei generated during proton irradiation can be used as a basis for ensuring the high accuracy of irradiation in proton treatment.

摘要

目的

验证我们开发的安装在旋转机架端口上的在线正电子发射断层扫描(PET)系统(BOLPs-RGp)在剂量体积输送引导质子治疗(DGPT)中的实用性。

方法和材料

在我们机构的质子治疗室中,构建了一个 BOLPs-RGp,以便可以将平面 PET 仪器安装在其视场覆盖光束照射系统等中心的位置。对 48 例头颈部、肝脏、肺部、前列腺和脑部肿瘤患者进行了活性测量。在质子照射后 200 秒内,使用 BOLPs-RGp 测量了活性的位置和强度。

结果

BOLPs-RGp 获得的每日测量的活性图像显示了每位患者的质子照射体积。通过参考活性图像(第一次治疗时拍摄)与每日活性图像之间的差异,指示质子照射体积的变化。在头颈部治疗中,在观察到部分肿瘤缩小的区域中,活性分布发生了变化。在肝脏治疗中,观察到坏死肿瘤细胞中的洗脱效应比非坏死肿瘤细胞慢。

结论

为 DGPT 开发了 BOLPs-RGp。通过测量每日测量的活性变化来评估质子治疗的准确性。在质子照射过程中产生的正电子发射核的信息可用作确保照射高精度的基础。

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