Hofmann Kerstin M, Masood Umar, Pawelke Joerg, Wilkens Jan J
Department of Radiation Oncology, Technische Universität München, Klinikum rechts der Isar, Ismaninger Str. 22, 81675 München, Germany and Physik-Department, Technische Universität München, James-Franck-Str. 1, 85748 Garching, Germany.
OncoRay National Center for Radiation Research in Oncology, Faculty of Medicine and University Hospital Carl Gustav Carus, Technische Universität Dresden, Fetscherstrasse 74, PF 41, 01307 Dresden, Germany.
Med Phys. 2015 Sep;42(9):5120-9. doi: 10.1118/1.4927717.
Laser-driven proton acceleration is suggested as a cost- and space-efficient alternative for future radiation therapy centers, although the properties of these beams are fairly different compared to conventionally accelerated proton beams. The laser-driven proton beam is extremely pulsed containing a very high proton number within ultrashort bunches at low bunch repetition rates of few Hz and the energy spectrum of the protons per bunch is very broad. Moreover, these laser accelerated bunches are subject to shot-to-shot fluctuations. Therefore, the aim of this study was to investigate the feasibility of a compact gantry design for laser-driven proton therapy and to determine limitations to comply with.
Based on a published gantry beam line design which can filter parabolic spectra from an exponentially decaying broad initial spectrum, a treatment planning study was performed on real patient data sets. All potential parabolic spectra were fed into a treatment planning system and numerous spot scanning proton plans were calculated. To investigate limitations in the fluence per bunch, the proton number of the initial spectrum and the beam width at patient entrance were varied. A scenario where only integer shots are delivered as well as an intensity modulation from shot to shot was studied. The resulting plans were evaluated depending on their dosimetric quality and in terms of required treatment time. In addition, the influence of random shot-to-shot fluctuations on the plan quality was analyzed.
The study showed that clinically relevant dose distributions can be produced with the system under investigation even with integer shots. For small target volumes receiving high doses per fraction, the initial proton number per bunch must remain between 1.4 × 10(8) and 8.3 × 10(9) to achieve acceptable delivery times as well as plan qualities. For larger target volumes and standard doses per fraction, the initial proton number is even more restricted to stay between 1.4 × 10(9) and 2.9 × 10(9). The lowest delivery time that could be reached for such a case was 16 min for a 10 Hz system. When modulating the intensity from shot to shot, the delivery time can be reduced to 6 min for this scenario. Since the shot-to-shot fluctuations are of random nature, a compensation effect can be observed, especially for higher laser shot numbers. Therefore, a fluctuation of ± 30% within the proton number does not translate into a dosimetric deviation of the same size. However, for plans with short delivery times these fluctuations cannot cancel out sufficiently, even for ± 10% fluctuations.
Under the analyzed terms, it is feasible to achieve clinically relevant dose distributions with laser-driven proton beams. However, to keep the delivery times of the proton plans comparable to conventional proton plans for typical target volumes, a device is required which can modulate the bunch intensity from shot to shot. From the laser acceleration point of view, the proton number per bunch must be kept under control as well as the reproducibility of the bunches.
激光驱动质子加速被认为是未来放射治疗中心一种经济且节省空间的替代方案,尽管与传统加速质子束相比,这些束流的特性有很大不同。激光驱动质子束是极脉冲式的,在几赫兹的低束团重复率下,超短束团内包含非常高的质子数,且每束质子的能谱非常宽。此外,这些激光加速束团存在逐次射击波动。因此,本研究的目的是探讨紧凑型龙门架设计用于激光驱动质子治疗的可行性,并确定需要遵守的限制条件。
基于已发表的一种龙门架束流线设计(该设计可从指数衰减的宽初始能谱中滤出抛物线能谱),对真实患者数据集进行了治疗计划研究。将所有潜在的抛物线能谱输入治疗计划系统,并计算了大量的点扫描质子计划。为了研究每束注量的限制,改变了初始能谱的质子数和患者入口处光束宽度。研究了仅输送整数次射击的情况以及逐次射击强度调制的情况。根据所得计划的剂量学质量和所需治疗时间对其进行评估。此外,分析了随机逐次射击波动对计划质量的影响。
研究表明,即使使用整数次射击,所研究的系统也能产生临床相关的剂量分布。对于每次分割接受高剂量的小靶区体积,每束初始质子数必须保持在1.4×10⁸至8.3×10⁹之间,以实现可接受的输送时间和计划质量。对于较大的靶区体积和标准分割剂量,初始质子数更严格地限制在1.4×10⁹至2.9×10⁹之间。对于这种情况,10Hz系统能达到的最短输送时间为16分钟。当逐次射击调制强度时,这种情况下输送时间可减少至6分钟。由于逐次射击波动是随机性质的,可观察到一种补偿效应,特别是对于较高的激光射击次数。因此,质子数±30%的波动不会转化为相同大小的剂量学偏差。然而,对于输送时间短的计划,即使±10%的波动,这些波动也不能充分抵消。
在所分析的条件下,用激光驱动质子束实现临床相关剂量分布是可行的。然而,为了使质子计划的输送时间与典型靶区体积的传统质子计划相当,需要一种能够逐次射击调制束团强度的装置。从激光加速的角度来看,每束质子数以及束团的可重复性都必须得到控制。
