技术说明:一种为远离等中心的靶区生成病变特异性非均匀旋转边界的方法。
Technical note: A method for generating lesion-specific nonuniform rotational margins for targets remote from isocenter.
机构信息
Department of Radiation Oncology, University of Utah, 1950 Circle of Hope Dr., Salt Lake City, Utah, USA.
出版信息
Med Phys. 2022 Dec;49(12):7438-7446. doi: 10.1002/mp.16013. Epub 2022 Oct 22.
PURPOSE
To present a novel method for generating nonuniform lesion-specific rotational margins for targets remote from isocenter, as encountered in single isocenter multiple metastasis radiotherapy.
METHODS
Target contours are rotated using a large series of 3D rotations, corresponding to a given range of rotational uncertainty, and combined to create a rotational envelope that encompasses potential motion. A set of artificial spherical targets ranging from 0.5 to 2.0 cm in diameter, and residing a distance of 1 - 15 cm from isocenter, is used to generate rotational envelopes assuming uncertainties of 0.5-3.0°. Computing time and number of samples are reported for simulated scenarios. Hausdorff distances (HD) between rotational envelopes and original target structures are calculated to represent the magnitude of uniform expansion required to encompass potential rotation. Volume differences between uniform expansions (based on HD) and rotational envelopes are reported to articulate potential advantages.
RESULTS
Median time to generate rotational envelopes was 60 s (31-974 s). Median required samples was 86 (61-851). Maximum HD for all targets located 10 cm from isocenter was 1.5 mm, 3.0 mm, 5.8 mm, and 8.6 mm assuming 0.5°, 1.0°, 2.0°, and 3.0° of rotational uncertainty, respectively. At 5 cm from isocenter and assuming 0.5° of rotational uncertainty, volumes were decreased by 0.07 cc (60%), 0.24 cc (39%), and 1.08 cc (19%) for 5 mm, 10 mm, and 20 mm targets respectively. At 10 cm from isocenter and 1.0° of uncertainty, volumes decreased by 0.42 cc (58%), 2.0 cc (40%), and 2.5 cc (27%). On average target volumes decreased 45% (SD = 17%) when compared with uniform expansions based on HD.
CONCLUSION
Rotational margins may be generated by sampling a set of 3D rotations. Resulting margins explicitly account for target shape, distance from isocenter, and magnitude of rotational uncertainty, while reducing treated volumes when compared with uniform expansions.
目的
提出一种新的方法,用于为远离等中心的靶区生成非均匀的病变特异性旋转边界,这种方法适用于单等中心多发转移放疗中遇到的情况。
方法
使用一系列 3D 旋转,对应于给定的旋转不确定性范围,对目标轮廓进行旋转,并将其组合起来创建一个旋转包络,以包含潜在的运动。一组人工球形靶标,直径从 0.5 厘米到 2.0 厘米不等,距离等中心 1 厘米到 15 厘米不等,用于生成旋转包络,假设不确定性为 0.5-3.0°。报告了模拟场景的计算时间和样本数量。计算了旋转包络和原始目标结构之间的 Hausdorff 距离(HD),以表示为包含潜在旋转所需的均匀扩展的幅度。报告了基于 HD 的均匀扩展与旋转包络之间的体积差异,以说明潜在的优势。
结果
生成旋转包络的中位数时间为 60 秒(31-974 秒)。中位数所需样本为 86(61-851)。所有位于距等中心 10 厘米的目标的最大 HD 分别为 0.5°、1.0°、2.0°和 3.0°假设旋转不确定性为 0.5°、1.0°、2.0°和 3.0°。在距等中心 5 厘米处,假设旋转不确定性为 0.5°,5 毫米、10 毫米和 20 毫米目标的体积分别减少了 0.07 cc(60%)、0.24 cc(39%)和 1.08 cc(19%)。在距等中心 10 厘米处,不确定性为 1.0°,体积减少了 0.42 cc(58%)、2.0 cc(40%)和 2.5 cc(27%)。与基于 HD 的均匀扩展相比,平均目标体积减少了 45%(标准差=17%)。
结论
可以通过对一组 3D 旋转进行采样来生成旋转边界。生成的边界明确考虑了目标形状、距等中心的距离和旋转不确定性的大小,同时与基于 HD 的均匀扩展相比,减少了治疗体积。
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