颅内病变行 Cyberknife 治疗的患者的外周剂量。单中心经验。

Peripheral doses in patients undergoing Cyberknife treatment for intracranial lesions. A single centre experience.

机构信息

Department of Medical Physics, School of Medicine, University of Patras, Achaia, Greece.

出版信息

Radiat Oncol. 2011 Nov 14;6:157. doi: 10.1186/1748-717X-6-157.

DOI:10.1186/1748-717X-6-157

PMID:22082279

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3228676/

Abstract

BACKGROUND

Stereotactic radiosurgery/radiotherapy procedures are known to deliver a very high dose per fraction, and thus, the corresponding peripheral dose could be a limiting factor for the long term surviving patients. The aim of this clinical study was to measure the peripheral dose delivered to patients undergoing intracranial Cyberknife treatment, using the MOSFET dosimeters. The influence of the supplemental shielding, the number of monitor units and the collimator size to the peripheral dose were investigated.

METHODS

MOSFET dosimeters were placed in preselected anatomical regions of the patient undergoing Cyberknife treatment, namely the thyroid gland, the nipple, the umbilicus and the pubic symphysis.

RESULTS

The mean peripheral doses before the supplemental shielding was added to the Cyberknife unit were 51.79 cGy, 13.31 cGy and 10.07 cGy while after the shielding upgrade they were 38.40 cGy, 10.94 cGy, and 8.69 cGy, in the thyroid gland, the umbilicus and the pubic symphysis, respectively. The increase of the collimator size corresponds to an increase of the PD and becomes less significant at larger distances, indicating that at these distances the PD is predominate due to the head leakage and collimator scatter.

CONCLUSION

Weighting the effect of the number of monitor units and the collimator size can be effectively used during the optimization procedure in order to choose the most suitable treatment plan that will deliver the maximum dose to the tumor, while being compatible with the dose constraints for the surrounding organs at risk. Attention is required in defining the thyroid gland as a structure of avoidance in the treatment plan especially in patients with benign diseases.

摘要

背景

立体定向放射外科/放疗程序每分次给予的剂量非常高，因此，相应的周边剂量可能是长期存活患者的限制因素。本临床研究的目的是使用 MOSFET 剂量仪测量接受颅内 Cyberknife 治疗的患者的周边剂量。研究了补充屏蔽、监测单位数量和准直器大小对周边剂量的影响。

方法

将 MOSFET 剂量仪放置在接受 Cyberknife 治疗的患者的预选解剖区域，即甲状腺、乳头、脐和耻骨联合。

结果

在向 Cyberknife 设备添加补充屏蔽之前，甲状腺、脐和耻骨联合的平均周边剂量分别为 51.79 cGy、13.31 cGy 和 10.07 cGy，而在屏蔽升级后，它们分别为 38.40 cGy、10.94 cGy 和 8.69 cGy。准直器尺寸的增加对应于 PD 的增加，在较大距离处变得不那么显著，表明在这些距离处，PD 由于头部泄漏和准直器散射而占主导地位。

结论

在优化过程中，可以有效地权衡监测单位数量和准直器大小的影响，以选择最适合的治疗计划，该计划将向肿瘤提供最大剂量，同时与周围危及器官的剂量限制兼容。在定义治疗计划中的甲状腺作为避免结构时需要注意，特别是在患有良性疾病的患者中。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2509/3228676/b9f724655852/1748-717X-6-157-1.jpg

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颅内病变行 Cyberknife 治疗的患者的外周剂量。单中心经验。

Peripheral doses in patients undergoing Cyberknife treatment for intracranial lesions. A single centre experience.

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSION

背景

方法

结果

结论

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