Ashamalla Hani, Rafla Sameer, Parikh Kapila, Mokhtar Bahaa, Goswami Ganesh, Kambam Shravan, Abdel-Dayem Hussain, Guirguis Adel, Ross Pamela, Evola Alex
Department of Radiation Oncology, New York Methodist Hospital, Weill Medical College of Cornell University, Brooklyn, NY 11215, USA.
Int J Radiat Oncol Biol Phys. 2005 Nov 15;63(4):1016-23. doi: 10.1016/j.ijrobp.2005.04.021. Epub 2005 Jun 24.
Positron emission tomography (PET) with the glucose analog [18F]fluro-2-deoxy-D-glucose (FDG) has been accepted as a valuable tool for the staging of lung cancer, but the use of PET/CT in radiation treatment planning is still not yet clearly defined. By the use of (PET/computed tomography (CT) images in treatment planning, we were able to define a new gross treatment volume using anatomic biologic contour (ABC), delineated directly on PET/CT images. We prospectively addressed three issues in this study: (1) How to contour treatment volumes on PET/CT images, (2) Assessment of the degree of correlation between CT-based gross tumor volume/planning target volume (GTV/PTV) (GTV-CT and PTV-CT) and the corresponding PET/CT-based ABC treatment volumes (GTV-ABC and PTV-ABC), (3) Magnitude of interobserver (radiation oncologist planner) variability in the delineation of ABC treatment volumes (using our contouring method).
Nineteen patients with Stages II-IIIB non-small-cell lung cancer were planned for radiation treatments using a fully integrated PET/CT device. Median patient age was 74 years (range: 52-82 years), and median Karnofsky performance status was 70. Thermoplastic or vacuum-molded immobilization devices required for conformal radiation therapy were custom fabricated for the patient before the injection of [18]f-FDG. Integrated, coregistered PET/CT images were obtained and transferred to the radiation planning workstation (Xeleris). While the PET data remained obscured, a CT-based gross tumor volume (GTV-CT) was delineated by two independent observers. The PTV was obtained by adding a 1.5-cm margin around the GTV. The same volumes were recontoured using PET/CT data and termed GTV-ABC and PTV-ABC, correspondingly.
We observed a distinct "halo" around areas of maximal standardized uptake value (SUV). The halo was identified by its distinct color at the periphery of all areas of maximal SUV uptake, independent of PET/CT gain ratio; the halo had an SUV of 2 +/- 0.4 and thickness of 2 mm +/- 0.5 mm. Whereas the center of our contoured treatment volume expressed the maximum SUV level, a steady decline of SUV was noted peripherally until SUV levels of 2 +/- 0.4 were reached at the peripheral edge of our contoured volume, coinciding with the observed halo region. This halo was always included in the contoured GTV-ABC. Because of the contribution of PET/CT to treatment planning, a clinically significant (> or =25%) treatment volume modification was observed between the GTV-CT and GTV-ABC in 10/19 (52%) cases, 5 of which resulted in an increase in GTV-ABC volume vs. GTV-CT. The modification of GTV between CT-based and PET/CT-based treatment planning resulted in an alteration of PTV exceeding 20% in 8 out of 19 patients (42%). Interobserver GTV variability decreased from a mean volume difference of 28.3 cm3 (in CT-based planning) to 9.12 cm3 (in PET/CT-based planning) with a respective decrease in standard deviation (SD) from 20.99 to 6.47. Interobserver PTV variability also decreased from 69.8 cm3 (SD +/- 82.76) in CT-based planning to 23.9 cm3 (SD +/- 15.31) with the use of PET/CT in planning. The concordance in treatment planning between observers was increased by the use of PET/CT; 16 (84%) had < or =10% difference from mean of GTVs using PET/CT compared to 7 cases (37%) using CT alone (p = 0.0035).
Position emission tomography/CT-based radiation treatment planning is a useful tool resulting in modification of GTV in 52% and improvement of interobserver variability up to 84%. The use of PET/CT-based ABC can potentially replace the use of GTV. The anatomic biologic halo can be used for delineation of volumes.
正电子发射断层扫描(PET)联合葡萄糖类似物[18F]氟代-2-脱氧-D-葡萄糖(FDG)已被公认为肺癌分期的重要工具,但PET/CT在放射治疗计划中的应用尚未明确界定。通过在治疗计划中使用PET/计算机断层扫描(CT)图像,我们能够直接在PET/CT图像上利用解剖生物学轮廓(ABC)定义一个新的大体治疗体积。我们在本研究中前瞻性地探讨了三个问题:(1)如何在PET/CT图像上勾画治疗体积;(2)评估基于CT的大体肿瘤体积/计划靶体积(GTV/PTV)(GTV-CT和PTV-CT)与相应的基于PET/CT的ABC治疗体积(GTV-ABC和PTV-ABC)之间的相关性程度;(3)观察者间(放射肿瘤学家计划者)在勾画ABC治疗体积(使用我们的勾画方法)时的变异性大小。
19例II-IIIB期非小细胞肺癌患者计划使用完全集成的PET/CT设备进行放射治疗。患者中位年龄为74岁(范围:52-82岁),中位卡诺夫斯基功能状态为70。在注射[18F] - FDG之前,为患者定制制造适形放射治疗所需的热塑性或真空成型固定装置。获取整合的、配准的PET/CT图像并传输到放射治疗计划工作站(Xeleris)。在PET数据仍被遮挡时,由两名独立观察者勾画基于CT的大体肿瘤体积(GTV-CT)。通过在GTV周围添加1.5 cm的边界获得PTV。使用PET/CT数据重新勾画相同的体积,并相应地称为GTV-ABC和PTV-ABC。
我们在最大标准化摄取值(SUV)区域周围观察到一个明显的“晕圈”。该晕圈通过其在所有最大SUV摄取区域周边的独特颜色得以识别,与PET/CT增益比无关;该晕圈的SUV为2±0.4,厚度为2 mm±0.5 mm。虽然我们勾画的治疗体积中心表示最大SUV水平,但在周边观察到SUV稳步下降,直到在我们勾画体积的周边边缘达到2±0.4的SUV水平,这与观察到的晕圈区域一致。这个晕圈总是包含在勾画的GTV-ABC中。由于PET/CT对治疗计划的贡献,在10/19(52%)的病例中观察到GTV-CT和GTV-ABC之间临床上显著(≥25%)的治疗体积改变,其中5例GTV-ABC体积相对于GTV-CT增加。基于CT和基于PET/CT的治疗计划之间GTV的改变导致19例患者中有8例(42%)PTV的改变超过20%。观察者间GTV变异性从基于CT计划时的平均体积差异28.3 cm3降至基于PET/CT计划时的9.12 cm3,标准差(SD)分别从20.99降至6.47。观察者间PTV变异性也从基于CT计划时的69.8 cm3(SD±82.76)降至使用PET/CT进行计划时的23.9 cm3(SD±15.31)。使用PET/CT增加了观察者之间治疗计划的一致性;与仅使用CT时的7例(37%)相比,16例(84%)使用PET/CT时与GTV平均值的差异≤10%(p = 0.0035)。
基于正电子发射断层扫描/CT的放射治疗计划是一种有用的工具,可使52%的GTV发生改变,并将观察者间变异性提高至84%。基于PET/CT的ABC的使用可能会取代GTV的使用。解剖生物学晕圈可用于勾画体积。
