Department of Radiation Oncology, Maastricht University Medical Centre, Maastricht, The Netherlands.
Radiother Oncol. 2012 Jul;104(1):67-71. doi: 10.1016/j.radonc.2012.03.005. Epub 2012 Apr 6.
The local site of relapse in non-small cell lung cancer (NSCLC) is primarily located in the high FDG uptake region of the primary tumour prior to treatment. A phase II PET-boost trial (NCT01024829) randomises patients between dose-escalation of the entire primary tumour (arm A) or to the high FDG uptake region inside the primary tumour (>50% SUV(max)) (arm B), whilst giving 66 Gy in 24 fractions to involved lymph nodes. We analysed the planning results of the first 20 patients for which both arms A and B were planned.
Boost dose levels were escalated up to predefined normal tissue constraints with an equal mean lung dose in both arms. This also forces an equal mean PTV dose in both arms, hence testing pure dose-redistribution. Actual delivered treatment plans from the ongoing clinical trial were analysed. Patients were randomised between arms A and B if dose-escalation to the primary tumour in arm A of at least 72 Gy in 24 fractions could be safely planned.
15/20 patients could be escalated to at least 72 Gy. Average prescribed fraction dose was 3.27±0.31 Gy [3.01-4.28 Gy] and 3.63±0.54 Gy [3.20-5.40 Gy] for arms A and B, respectively. Average mean total dose inside the PTV of the primary tumour was comparable: 77.3±7.9 Gy vs. 77.5±10.1 Gy. For the boost region dose levels of on average 86.9±14.9 Gy were reached. No significant dose differences between both arms were observed for the organs at risk. Most frequent observed dose-limiting constraints were the mediastinal structures (13/15 and 14/15 for arms A and B, respectively), and the brachial plexus (3/15 for both arms).
Dose-escalation using an integrated boost could be achieved to the primary tumour or high FDG uptake regions whilst keeping the pre-defined dose constraints.
非小细胞肺癌(NSCLC)局部复发部位主要位于治疗前原发肿瘤高 FDG 摄取区域。一项 II 期 PET 增敏试验(NCT01024829)将患者随机分为两组:一组对整个原发肿瘤进行剂量递增(A 组),另一组对原发肿瘤内高 FDG 摄取区域(>50% SUV(max))进行剂量递增(B 组),同时对受累淋巴结给予 66Gy/24 次。我们分析了前 20 例同时计划 A 组和 B 组的患者的计划结果。
在两组中,均以预设的正常组织限制来递增增敏剂量,使两组的平均肺剂量相等。这也迫使两组的 PTV 平均剂量相等,从而测试纯剂量再分布。分析了正在进行的临床试验中的实际治疗计划。如果 A 组中对原发肿瘤的剂量递增至少达到 72Gy/24 次,可以安全地进行计划,则将患者随机分为 A 组和 B 组。
20 例患者中有 15 例可递增至至少 72Gy。A 组和 B 组的平均处方分割剂量分别为 3.27±0.31Gy[3.01-4.28Gy]和 3.63±0.54Gy[3.20-5.40Gy]。原发肿瘤 PTV 内平均总剂量相似:77.3±7.9Gy 与 77.5±10.1Gy。在增敏区域,平均剂量水平达到 86.9±14.9Gy。在危及器官方面,两组之间没有观察到显著的剂量差异。最常观察到的剂量限制约束是纵隔结构(A 组和 B 组分别为 13/15 和 14/15)和臂丛(两组均为 3/15)。
使用综合增敏可以实现对原发肿瘤或高 FDG 摄取区域的剂量递增,同时保持预定义的剂量限制。
