Plathow Christian, Schoebinger Max, Fink Christian, Hof Holger, Debus Jürgen, Meinzer Hans-Peter, Kauczor Hans-Ulrich
Department of Radiology, German Cancer Research Center, Heidelberg, Germany.
Radiology. 2006 Aug;240(2):537-45. doi: 10.1148/radiol.2401050727. Epub 2006 Jun 26.
The purpose of this study was to prospectively evaluate the volumes and rotations of pulmonary nodules during respiration by using three-dimensional fast low-angle shot dynamic magnetic resonance (MR) imaging (1.5/0.6 [repetition time msec/echo time msec], 3.8 x 3.8 x 3.8-mm voxel size, imaging time per three-dimensional data set of 1 second). The feasibility of the technique was verified by using 130-, 40-, and 12-cm3 phantoms made of meatballs and in five patients with solitary intrapulmonary tumors (four men, one woman; median age, 60 years) at computed tomography and histologic analysis. All patients provided written informed consent, and the study was institutional review board approved. It was proved that there were no substantial differences among the 21 algorithms used to correct partial volume effects. The most precise algorithm (r > 0.9, P < .01) used to correct partial volume effects--with which mean phantom volumes of 120.8 cm3 +/- 4.1, 36.1 cm3 +/- 3.98, and 13.1 cm3 +/- 1.5 were calculated--yielded a root mean square error of 14%. The MR imaging-derived nodule volume and rotation during respiration could be quantified by using oriented bounding box techniques.
本研究的目的是通过使用三维快速低角度激发动态磁共振(MR)成像(1.5/0.6 [重复时间毫秒/回波时间毫秒],体素大小为3.8×3.8×3.8毫米,每个三维数据集的成像时间为1秒),前瞻性地评估呼吸过程中肺结节的体积和旋转情况。通过使用由肉丸制成的130立方厘米、40立方厘米和12立方厘米的模型,以及对5例孤立性肺内肿瘤患者(4名男性,1名女性;中位年龄60岁)进行计算机断层扫描和组织学分析,验证了该技术的可行性。所有患者均提供了书面知情同意书,该研究获得了机构审查委员会的批准。结果证明,用于校正部分容积效应的21种算法之间没有实质性差异。用于校正部分容积效应的最精确算法(r>0.9,P<.01)——据此计算出模型的平均体积分别为120.8立方厘米±4.1、36.1立方厘米±3.98和13.1立方厘米±1.5——其均方根误差为14%。呼吸过程中由MR成像得出的结节体积和旋转情况可通过使用定向包围盒技术进行量化。
