Research Center for Charged Particle Therapy, National Institute of Radiological Sciences, Chiba, Japan.
Int J Radiat Oncol Biol Phys. 2011 Jun 1;80(2):597-607. doi: 10.1016/j.ijrobp.2010.07.1982. Epub 2010 Oct 23.
We compared four-dimensional (4D) layer-stacking and conventional carbon ion beam distribution in the treatment of lung cancer between ungated and gated respiratory strategies using 4DCT data sets.
Twenty lung patients underwent 4DCT imaging under free-breathing conditions. Using planning target volumes (PTVs) at respective respiratory phases, two types of compensating bolus were designed, a full single respiratory cycle for the ungated strategy and an approximately 30% duty cycle for the exhalation-gated strategy. Beams were delivered to the PTVs for the ungated and gated strategies, PTV(ungated) and PTV(gated), respectively, which were calculated by combining the respective PTV(Tn)s by layer-stacking and conventional irradiation. Carbon ion beam dose distribution was calculated as a function of respiratory phase by applying a compensating bolus to 4DCT. Accumulated dose distributions were calculated by applying deformable registration.
With the ungated strategy, accumulated dose distributions were satisfactorily provided to the PTV, with D95 values for layer-stacking and conventional irradiation of 94.0% and 96.2%, respectively. V20 for the lung and Dmax for the spinal cord were lower with layer-stacking than with conventional irradiation, whereas Dmax for the skin (14.1 GyE) was significantly lower (21.9 GyE). In addition, dose conformation to the GTV/PTV with layer-stacking irradiation was better with the gated than with the ungated strategy.
Gated layer-stacking irradiation allows the delivery of a carbon ion beam to a moving target without significant degradation of dose conformity or the development of hot spots.
我们比较了非门控和门控呼吸策略下使用 4DCT 数据集的 4D 层叠和传统碳离子束分布在肺癌治疗中的差异。
20 例肺癌患者在自由呼吸条件下进行 4DCT 成像。使用各呼吸时相的计划靶区(PTV),设计了两种补偿推注方式,非门控策略采用完整的单个呼吸周期,呼气门控策略采用约 30%的占空比。将门照射到 PTV(非门控)和 PTV(门控),分别为 PTV(ungated)和 PTV(gated),通过层叠和常规照射将各自的 PTV(Tn)组合计算得到。通过对 4DCT 应用补偿推注计算碳离子束剂量分布随呼吸时相的变化。通过应用变形配准计算累积剂量分布。
在非门控策略下,PTV 得到了满意的累积剂量分布,层叠和常规照射的 D95 值分别为 94.0%和 96.2%。与常规照射相比,肺 V20 和脊髓 Dmax 较低,而皮肤 Dmax(14.1GyE)显著较低(21.9GyE)。此外,与非门控策略相比,门控层叠照射对 GTV/PTV 的剂量适形性更好。
门控层叠照射允许在不显著降低剂量适形性或产生热点的情况下将碳离子束递送到移动目标。
