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用于基于MRI的肝脏立体定向体部放射治疗治疗计划的合成CT

Synthetic CT for MRI-based liver stereotactic body radiotherapy treatment planning.

作者信息

Bredfeldt Jeremy S, Liu Lianli, Feng Mary, Cao Yue, Balter James M

机构信息

Department of Radiation Oncology, University of Michigan, Ann Arbor, MI 48109, United States of America.

出版信息

Phys Med Biol. 2017 Apr 21;62(8):2922-2934. doi: 10.1088/1361-6560/aa5059. Epub 2017 Mar 17.

DOI:10.1088/1361-6560/aa5059
PMID:28306547
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5495654/
Abstract

A technique for generating MRI-derived synthetic CT volumes (MRCTs) is demonstrated in support of adaptive liver stereotactic body radiation therapy (SBRT). Under IRB approval, 16 subjects with hepatocellular carcinoma were scanned using a single MR pulse sequence (T1 Dixon). Air-containing voxels were identified by intensity thresholding on T1-weighted, water and fat images. The envelope of the anterior vertebral bodies was segmented from the fat image and fuzzy-C-means (FCM) was used to classify each non-air voxel as mid-density, lower-density, bone, or marrow in the abdomen, with only bone and marrow classified within the vertebral body envelope. MRCT volumes were created by integrating the product of the FCM class probability with its assigned class density for each voxel. MRCTs were deformably aligned with corresponding planning CTs and 2-ARC-SBRT-VMAT plans were optimized on MRCTs. Fluence was copied onto the CT density grids, dose recalculated, and compared. The liver, vertebral bodies, kidneys, spleen and cord had median Hounsfield unit differences of less than 60. Median target dose metrics were all within 0.1 Gy with maximum differences less than 0.5 Gy. OAR dose differences were similarly small (median: 0.03 Gy, std:0.26 Gy). Results demonstrate that MRCTs derived from a single abdominal imaging sequence are promising for use in SBRT dose calculation.

摘要

展示了一种用于生成磁共振成像(MRI)衍生的合成CT容积(MRCT)的技术,以支持肝脏立体定向体部放射治疗(SBRT)。在机构审查委员会(IRB)批准下,对16例肝细胞癌患者使用单一MR脉冲序列(T1 Dixon)进行扫描。通过在T1加权、水和脂肪图像上进行强度阈值化来识别含气体素。从前侧椎体的脂肪图像中分割出椎体包膜,并使用模糊C均值(FCM)将腹部每个非气性体素分类为中密度、低密度、骨骼或骨髓,仅在椎体包膜内对骨骼和骨髓进行分类。通过将FCM类别概率与其为每个体素分配的类别密度的乘积进行积分来创建MRCT容积。将MRCT与相应的计划CT进行变形配准,并在MRCT上优化双弧SBRT容积调强放疗(VMAT)计划。将通量复制到CT密度网格上,重新计算剂量并进行比较。肝脏、椎体、肾脏、脾脏和脊髓的Hounsfield单位中位数差异小于60。中位靶区剂量指标均在0.1 Gy以内,最大差异小于0.5 Gy。危及器官(OAR)剂量差异同样较小(中位数:0.03 Gy,标准差:0.26 Gy)。结果表明,从单一腹部成像序列获得的MRCT在SBRT剂量计算中具有应用前景。

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