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在肺癌三维适形放疗中,内部靶区体积是在复合大体肿瘤体积基础上加上外放边界确定的。

Internal target volume determined with expansion margins beyond composite gross tumor volume in three-dimensional conformal radiotherapy for lung cancer.

作者信息

Shih Helen A, Jiang Steve B, Aljarrah Khaled M, Doppke Karen P, Choi Noah C

机构信息

Department of Radiation Oncology, Massachusetts General Hospital and Harvard Medical School, Boston, MA, USA.

出版信息

Int J Radiat Oncol Biol Phys. 2004 Oct 1;60(2):613-22. doi: 10.1016/j.ijrobp.2004.05.031.

DOI:10.1016/j.ijrobp.2004.05.031
PMID:15380599
Abstract

PURPOSE

Gross tumor volume (GTV) of lung cancer defined by fast helical CT scan represents an image of moving tumor captured at a point in active respiratory movement. However, the method for defining internal margins beyond GTV to account for its expected physiologic movement and all variations in size and shape during the administration of radiation has not been established. The goal of this study was to determine the internal margins with expansion margins beyond individual GTVs defined with (1) fast scan at shallow free breathing, (2) breath-hold scans at the end of tidal volume inspiration and expiration, and (3) 4-s slow scan to approximate the composite GTV of all scans.

METHODS AND MATERIALS

A series of sequential CT scans were acquired with (1) a fast helical scan at shallow free breathing and (2) breath-hold scans at the end of tidal volume expiration and inspiration for the first 6 patients, and (3) a 4-s slow scan at quiet free breathing, which was added for the latter 7 patients. We fused breath-hold scans and the 4-s slow scan to the fast scan at shallow free breathing to generate the composite GTV. Margins necessary to encompass the composite GTV beyond individual GTVs defined by either fast scan at quiet free breathing, breath-hold scans, or the 4-s slow scan at quiet free breathing were defined as expansion or internal margins and termed the internal target volumes. The centroid of the tumor volume was also used as another reference for tumor movement.

RESULTS

Thirteen patients with 14 tumors were enrolled into the study. Substantial tumor movement was noted by either the extent of internal margins beyond each GTV or the movement of the centroid. Internal margins varied significantly according to the method of CT scanning for determination of GTV. Even for tumors in the same lobe of the lung, a wide range of internal margins and significant variation in the centroid movement in all directions (x, y, and z) were observed. The GTV of a single fast helical scan at free breathing (n = 14) required the largest internal margin (mean, 3.5 mm; maximum, 18 mm; standard deviation [SD], 4.2 mm) to match the composite GTV, compared with those of the 4-s slow scan (mean 2.7 mm, maximum 14 mm, SD 3.5 mm) or combined breath-hold scans (mean 1.1 mm, maximum 9 mm, SD 1.9 mm). Internal margins (expansion margins) required to approximate the composite GTV in 95% of cases were 13 mm, 10 mm, and 5 mm for the GTVs of a single fast scan, 4-s slow scan, and breath-hold scans at the end of tidal volume inspiration and expiration, respectively.

CONCLUSIONS

The internal margins required to account for the internal tumor motion in three-dimensional conformal radiotherapy are substantial. For the use of symmetric and population-based margins to account for internal tumor motion, GTV defined with breath-hold scans at the end of tidal volume inspiration and expiration has a narrower range of internal margins in all directions than that of either a single fast scan or 4-s slow scan.

摘要

目的

通过快速螺旋CT扫描定义的肺癌大体肿瘤体积(GTV)代表了在呼吸运动活跃阶段某一时刻捕捉到的移动肿瘤图像。然而,尚未确立用于定义GTV之外的内部边界以考虑其预期生理运动以及放疗期间大小和形状的所有变化的方法。本研究的目的是确定超出通过以下方式定义的个体GTV的扩展边界的内部边界:(1)浅自由呼吸时的快速扫描,(2)潮气量吸气末和呼气末的屏气扫描,以及(3)4秒慢扫描以近似所有扫描的复合GTV。

方法和材料

对前6例患者进行了一系列连续CT扫描,包括(1)浅自由呼吸时的快速螺旋扫描和(2)潮气量呼气末和吸气末的屏气扫描,对后7例患者增加了(3)安静自由呼吸时的4秒慢扫描。我们将屏气扫描和4秒慢扫描与浅自由呼吸时的快速扫描融合以生成复合GTV。超出通过安静自由呼吸时的快速扫描、屏气扫描或安静自由呼吸时的4秒慢扫描定义的个体GTV以涵盖复合GTV所需的边界被定义为扩展或内部边界,并称为内部靶体积。肿瘤体积的质心也用作肿瘤运动的另一个参考。

结果

13例患者共14个肿瘤纳入本研究。通过每个GTV之外的内部边界范围或质心运动可观察到明显的肿瘤运动。根据用于确定GTV的CT扫描方法,内部边界差异显著。即使对于同一肺叶内的肿瘤,在所有方向(x、y和z)上也观察到内部边界范围广泛且质心运动有显著变化。与4秒慢扫描(平均2.7mm,最大14mm,标准差[SD]3.5mm)或联合屏气扫描(平均1.1mm,最大9mm,SD 1.9mm)相比,自由呼吸时单次快速螺旋扫描的GTV(n = 14)需要最大的内部边界(平均3.5mm,最大18mm,SD 4.2mm)来匹配复合GTV。在95%的病例中,近似复合GTV所需的内部边界(扩展边界)对于单次快速扫描、4秒慢扫描以及潮气量吸气末和呼气末屏气扫描的GTV分别为13mm、10mm和5mm。

结论

在三维适形放疗中考虑内部肿瘤运动所需的内部边界很大。对于使用对称且基于群体的边界来考虑内部肿瘤运动,在潮气量吸气末和呼气末通过屏气扫描定义的GTV在所有方向上的内部边界范围比单次快速扫描或4秒慢扫描的更窄。

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