Tyagi Neelam, Fontenla Sandra, Zelefsky Michael, Chong-Ton Marcia, Ostergren Kyle, Shah Niral, Warner Lizette, Kadbi Mo, Mechalakos Jim, Hunt Margie
Department of Medical Physics, Memorial Sloan Kettering Cancer Center, 1275 York Avenue, New York, NY, 10065, USA.
Department of Radiation Oncology, Memorial Sloan Kettering Cancer Center, 1275 York Avenue, New York, NY, 10065, USA.
Radiat Oncol. 2017 Jul 17;12(1):119. doi: 10.1186/s13014-017-0854-4.
To describe the details and experience of implementing a MR-only workflow in the clinic for simulation and planning of prostate cancer patients.
Forty-eight prostate cancer patients from June 2016 - Dec 2016 receiving external beam radiotherapy were scheduled to undergo MR-only simulation. MR images were acquired for contouring (T2w axial, coronal, sagittal), synthetic-CT generation (3D FFE-based) and fiducial identification (3D bFFE-based). The total acquisition time was 25 min. Syn-CT was generated at the console using commercial software called MRCAT. As part of acceptance testing of the MRCAT package, external laser positioning system QA (< 2 mm) and geometric fidelity QA (< 2 mm within 50 cm LR and 30 cm AP) were performed and baseline values were set. Our current combined CT + MR simulation process was modified to accommodate a MRCAT-based MR-only simulation workflow. An automated step-by-step process using a MIM™ workflow was created for contouring on the MR images. Patient setup for treatment was achieved by matching the MRCAT DRRs with the orthogonal KV radiographs based on either fiducial ROIs or bones. 3-D CBCTs were acquired and compared with the MR/syn-CT to assess the rectum and bladder filling compared to simulation conditions.
Forty-two patients successfully underwent MR-only simulation and met all of our institutional dosimetric objectives that were developed based on a CT + MR-based workflow. The remaining six patients either had a hip prosthesis or their large body size fell outside of the geometric fidelity QA criteria and thus they were not candidates for MR-only simulation. A total time saving of ~15 min was achieved with MR-based simulation as compared to CT + MR-based simulation. An automated and organized MIM workflow made contouring on MR much easier, quicker and more accurate compared with combined CT + MR images because the temporal variations in normal structure was minimal. 2D and 3D treatment setup localization based on bones/fiducials using a MRCAT reference image was successfully achieved for all cases.
MR-only simulation and planning with equivalent or superior target delineation, planning and treatment setup localization accuracy is feasible in a clinical setting. Future work will focus on implementing a robust 3D isotropic acquisition for contouring.
描述在临床中实施仅使用磁共振成像(MR)的工作流程用于前列腺癌患者模拟和计划的细节与经验。
2016年6月至2016年12月期间接受外照射放疗的48例前列腺癌患者计划进行仅MR模拟。采集MR图像用于轮廓勾画(T2加权轴向、冠状、矢状位)、合成CT生成(基于三维快速场回波序列)和基准标记识别(基于三维平衡快速场回波序列)。总采集时间为25分钟。使用名为MRCAT的商业软件在控制台生成合成CT。作为MRCAT软件包验收测试的一部分,进行了外部激光定位系统质量保证(<2毫米)和几何保真度质量保证(在左右50厘米和前后30厘米范围内<2毫米)并设定了基线值。我们当前的CT + MR联合模拟流程进行了修改,以适应基于MRCAT的仅MR模拟工作流程。创建了一个使用MIM™工作流程的自动化分步流程用于在MR图像上进行轮廓勾画。通过将MRCAT数字重建射线图像与基于基准感兴趣区或骨骼的正交千伏射线照片进行匹配来实现治疗的患者摆位。采集三维锥形束CT并与MR/合成CT进行比较,以评估与模拟条件相比直肠和膀胱的充盈情况。
42例患者成功完成了仅MR模拟,并达到了我们基于CT + MR工作流程制定的所有机构剂量学目标。其余6例患者要么有髋关节假体,要么体型过大超出了几何保真度质量保证标准,因此他们不适合仅MR模拟。与基于CT + MR的模拟相比,基于MR的模拟总共节省了约15分钟时间。与CT + MR联合图像相比,自动化且有条理的MIM工作流程使在MR上进行轮廓勾画更容易、更快且更准确,因为正常结构的时间变化最小。对于所有病例,基于骨骼/基准标记使用MRCAT参考图像成功实现了二维和三维治疗摆位定位。
在临床环境中,仅使用MR进行模拟和计划,具有等效或更高的靶区勾画、计划和治疗摆位定位准确性是可行的。未来的工作将集中于实施用于轮廓勾画的稳健三维各向同性采集。
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