准确估计 106Ru 贴片中眼部内的剂量分布。

Accurate estimation of dose distributions inside an eye irradiated with 106Ru plaques.

机构信息

NCTeam, Strahlenklinik, Universitätsklinikum Essen, Hufelandstr. 55, 45122, Essen, Germany.

出版信息

Strahlenther Onkol. 2013 Jan;189(1):68-73. doi: 10.1007/s00066-012-0245-6. Epub 2012 Nov 18.

DOI:10.1007/s00066-012-0245-6

PMID:23161122

Abstract

BACKGROUND

Irradiation of intraocular tumors requires dedicated techniques, such as brachytherapy with (106)Ru plaques. The currently available treatment planning system relies on the assumption that the eye is a homogeneous water sphere and on simplified radiation transport physics. However, accurate dose distributions and their assessment demand better models for both the eye and the physics.

METHODS

The Monte Carlo code PENELOPE, conveniently adapted to simulate the beta decay of (106)Ru over (106)Rh into (106)Pd, was used to simulate radiation transport based on a computerized tomography scan of a patient's eye. A detailed geometrical description of two plaques (models CCA and CCB) from the manufacturer BEBIG was embedded in the computerized tomography scan.

RESULTS

The simulations were firstly validated by comparison with experimental results in a water phantom. Dose maps were computed for three plaque locations on the eyeball. From these maps, isodose curves and cumulative dose-volume histograms in the eye and for the structures at risk were assessed. For example, it was observed that a 4-mm anterior displacement with respect to a posterior placement of a CCA plaque for treating a posterior tumor would reduce from 40 to 0% the volume of the optic disc receiving more than 80 Gy. Such a small difference in anatomical position leads to a change in the dose that is crucial for side effects, especially with respect to visual acuity. The radiation oncologist has to bring these large changes in absorbed dose in the structures at risk to the attention of the surgeon, especially when the plaque has to be positioned close to relevant tissues.

CONCLUSION

The detailed geometry of an eye plaque in computerized and segmented tomography of a realistic patient phantom was simulated accurately. Dose-volume histograms for relevant anatomical structures of the eye and the orbit were obtained with unprecedented accuracy. This represents an important step toward an optimized brachytherapy treatment of ocular tumors.

摘要

背景

眼内肿瘤的放射治疗需要专门的技术，如（106）Ru 贴剂的近距离放疗。目前可用的治疗计划系统依赖于眼睛是一个均匀的水球的假设，并依赖于简化的辐射输运物理。然而，准确的剂量分布及其评估需要更好的眼睛和物理模型。

方法

蒙特卡罗代码 PENELOPE，方便地适应于模拟（106）Ru 通过（106）Rh 到（106）Pd 的β衰变，被用于基于患者眼部的计算机断层扫描来模拟辐射传输。制造商 BEBIG 的两个贴剂（模型 CCA 和 CCB）的详细几何描述被嵌入到计算机断层扫描中。

结果

模拟结果首先通过与水模中的实验结果进行比较来验证。计算了三个眼球贴剂位置的剂量图。从这些图中，评估了眼睛和危险结构中的等剂量曲线和累积剂量-体积直方图。例如，观察到对于治疗后肿瘤的 CCA 贴剂从前部向后部的 4 毫米的前移位会将视神经盘接收超过 80 Gy 的体积从 40%减少到 0%。解剖位置的如此小的差异会导致剂量的变化，这对于副作用至关重要，特别是对于视力。放射肿瘤学家必须将这些危险结构中吸收剂量的大变化提请外科医生注意，尤其是当贴剂必须靠近相关组织定位时。

结论

准确地模拟了计算机断层扫描和分段断层扫描中真实患者幻影的眼部贴剂的详细几何形状。获得了眼睛和眼眶相关解剖结构的剂量-体积直方图，具有前所未有的准确性。这是实现眼部肿瘤优化近距离放疗的重要一步。

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准确估计 106Ru 贴片中眼部内的剂量分布。

Accurate estimation of dose distributions inside an eye irradiated with 106Ru plaques.

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSION

背景

方法

结果

结论

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