Held Mareike, Cremers Florian, Sneed Penny K, Braunstein Steve, Fogh Shannon E, Nakamura Jean, Barani Igor, Perez-Andujar Angelica, Pouliot Jean, Morin Olivier
University of California San Francisco.
J Appl Clin Med Phys. 2016 Mar 8;17(2):279-290. doi: 10.1120/jacmp.v17i2.6040.
A clinical workflow was developed for urgent palliative radiotherapy treatments that integrates patient simulation, planning, quality assurance, and treatment in one 30-minute session. This has been successfully tested and implemented clinically on a linac with MV CBCT capabilities. To make this approach available to all clin-ics equipped with common imaging systems, dose calculation accuracy based on treatment sites was assessed for other imaging units. We evaluated the feasibility of palliative treatment planning using on-board imaging with respect to image quality and technical challenges. The purpose was to test multiple systems using their commercial setup, disregarding any additional in-house development. kV CT, kV CBCT, MV CBCT, and MV CT images of water and anthropomorphic phantoms were acquired on five different imaging units (Philips MX8000 CT Scanner, and Varian TrueBeam, Elekta VersaHD, Siemens Artiste, and Accuray Tomotherapy linacs). Image quality (noise, contrast, uniformity, spatial resolution) was evaluated and compared across all machines. Using individual image value to density calibrations, dose calculation accuracies for simple treatment plans were assessed for the same phantom images. Finally, image artifacts on clinical patient images were evaluated and compared among the machines. Image contrast to visualize bony anatomy was sufficient on all machines. Despite a high noise level and low contrast, MV CT images provided the most accurate treatment plans relative to kV CT-based planning. Spatial resolution was poorest for MV CBCT, but did not limit the visualization of small anatomical structures. A comparison of treatment plans showed that monitor units calculated based on a prescription point were within 5% difference relative to kV CT-based plans for all machines and all studied treatment sites (brain, neck, and pelvis). Local dose differences > 5% were found near the phantom edges. The gamma index for 3%/3 mm criteria was ≥ 95% in most cases. Best dose calculation results were obtained when the treatment isocenter was near the image isocenter for all machines. A large field of view and immediate image export to the treatment planning system were essential for a smooth workflow and were not provided on all devices. Based on this phantom study, image quality of the studied kV CBCT, MV CBCT, and MV CT on-board imaging devices was sufficient for treatment planning in all tested cases. Treatment plans provided dose calculation accuracies within an acceptable range for simple, urgently planned palliative treatments. However, dose calculation accuracy was compromised towards the edges of an image. Feasibility for clinical implementation should be assessed separately and may be complicated by machine specific features. Image artifacts in patient images and the effect on dose calculation accuracy should be assessed in a separate, machine-specific study.
我们开发了一种用于紧急姑息性放射治疗的临床工作流程,该流程在一个30分钟的时段内整合了患者模拟、计划制定、质量保证和治疗。这已在具有MV CBCT功能的直线加速器上成功进行了临床测试和实施。为了使所有配备普通成像系统的诊所都能采用这种方法,我们评估了其他成像设备基于治疗部位的剂量计算准确性。我们评估了使用机载成像进行姑息治疗计划的可行性,包括图像质量和技术挑战。目的是使用其商业设置测试多个系统,不考虑任何额外的内部开发。在五个不同的成像设备(飞利浦MX8000 CT扫描仪以及瓦里安TrueBeam、医科达VersaHD、西门子Artiste和安科锐螺旋断层放射治疗直线加速器)上获取了水模体和人体模体的kV CT、kV CBCT、MV CBCT和MV CT图像。对所有机器的图像质量(噪声、对比度、均匀性、空间分辨率)进行了评估和比较。使用单个图像值到密度校准,对相同模体图像的简单治疗计划的剂量计算准确性进行了评估。最后,对临床患者图像上的图像伪影进行了评估并在各机器之间进行了比较。所有机器上用于可视化骨解剖结构的图像对比度都足够。尽管MV CT图像噪声水平高且对比度低,但相对于基于kV CT的计划,它提供了最准确的治疗计划。MV CBCT的空间分辨率最差,但并不限制小解剖结构的可视化。治疗计划的比较表明,基于处方点计算的监测单位与基于kV CT的计划相比,在所有机器和所有研究的治疗部位(脑、颈部和骨盆)的差异在5%以内。在模体边缘附近发现局部剂量差异>5%。在大多数情况下,3%/3mm标准的伽马指数≥95%。当治疗等中心靠近所有机器的图像等中心时,可获得最佳剂量计算结果。大视野和立即将图像导出到治疗计划系统对于顺畅的工作流程至关重要,但并非所有设备都具备。基于此模体研究,在所研究的kV CBCT、MV CBCT和MV CT机载成像设备的图像质量在所有测试情况下足以用于治疗计划。对于简单的、紧急计划的姑息治疗,治疗计划提供的剂量计算准确性在可接受范围内。然而,图像边缘的剂量计算准确性会受到影响。临床实施的可行性应单独评估,并且可能因机器的特定功能而变得复杂。患者图像中的图像伪影及其对剂量计算准确性的影响应在单独的、针对特定机器的研究中进行评估。
