Department of Radiation Oncology, University of California - Los Angeles School of Medicine, 200 Medical Plaza, Los Angeles, California 90095, USA.
Med Phys. 2013 Jul;40(7):071711. doi: 10.1118/1.4808363.
Dose volume histograms (DVHs) are common tools in radiation therapy treatment planning to characterize plan quality. As statistical metrics, DVHs provide a compact summary of the underlying plan at the cost of losing spatial information: the same or similar dose-volume histograms can arise from substantially different spatial dose maps. This is exactly the reason why physicians and physicists scrutinize dose maps even after they satisfy all DVH endpoints numerically. However, up to this point, little has been done to control spatial phenomena, such as the spatial distribution of hot spots, which has significant clinical implications. To this end, the authors propose a novel objective function that enables a more direct tradeoff between target coverage, organ-sparing, and planning target volume (PTV) homogeneity, and presents our findings from four prostate cases, a pancreas case, and a head-and-neck case to illustrate the advantages and general applicability of our method.
In designing the energy minimization objective (E tot (sparse)), the authors utilized the following robust cost functions: (1) an asymmetric linear well function to allow differential penalties for underdose, relaxation of prescription dose, and overdose in the PTV; (2) a two-piece linear function to heavily penalize high dose and mildly penalize low and intermediate dose in organs-at risk (OARs); and (3) a total variation energy, i.e., the L1 norm applied to the first-order approximation of the dose gradient in the PTV. By minimizing a weighted sum of these robust costs, general conformity to dose prescription and dose-gradient prescription is achieved while encouraging prescription violations to follow a Laplace distribution. In contrast, conventional quadratic objectives are associated with a Gaussian distribution of violations, which is less forgiving to large violations of prescription than the Laplace distribution. As a result, the proposed objective E tot (sparse) improves tradeoff between planning goals by "sacrificing" voxels that have already been violated to improve PTV coverage, PTV homogeneity, and/or OAR-sparing. In doing so, overall plan quality is increased since these large violations only arise if a net reduction in E tot (sparse) occurs as a result. For example, large violations to dose prescription in the PTV in E tot (sparse)-optimized plans will naturally localize to voxels in and around PTV-OAR overlaps where OAR-sparing may be increased without compromising target coverage. The authors compared the results of our method and the corresponding clinical plans using analyses of DVH plots, dose maps, and two quantitative metrics that quantify PTV homogeneity and overdose. These metrics do not penalize underdose since Etot (sparse)-optimized plans were planned such that their target coverage was similar or better than that of the clinical plans. Finally, plan deliverability was assessed with the 2D modulation index.
The proposed method was implemented using IBM's CPLEX optimization package (ILOG CPLEX, Sunnyvale, CA) and required 1-4 min to solve with a 12-core Intel i7 processor. In the testing procedure, the authors optimized for several points on the Pareto surface of four 7-field 6MV prostate cases that were optimized for different levels of PTV homogeneity and OAR-sparing. The generated results were compared against each other and the clinical plan by analyzing their DVH plots and dose maps. After developing intuition by planning the four prostate cases, which had relatively few tradeoffs, the authors applied our method to a 7-field 6 MV pancreas case and a 9-field 6MV head-and-neck case to test the potential impact of our method on more challenging cases. The authors found that our formulation: (1) provided excellent flexibility for balancing OAR-sparing with PTV homogeneity; and (2) permitted the dose planner more control over the evolution of the PTV's spatial dose distribution than conventional objective functions. In particular, Etot (sparse)-optimized plans for the pancreas case and head-and-neck case exhibited substantially improved sparing of the spinal cord and parotid glands, respectively, while maintaining or improving sparing for other OARs and markedly improving PTV homogeneity. Plan deliverability for E tot (sparse)-optimized plans was shown to be better than their associated clinical plans, according to the two-dimensional modulation index.
These results suggest that our formulation may be used to improve dose-shaping and OAR-sparing for complicated disease sites, such as the pancreas or head and neck. Furthermore, our objective function and constraints are linear and constitute a linear program, which converges to the global minimum quickly, and can be easily implemented in treatment planning software. Thus, the authors expect fast translation of our method to the clinic where it may have a positive impact on plan quality for challenging disease sites.
剂量体积直方图(DVHs)是放射治疗计划中常用的工具,用于描述计划质量。作为统计指标,DVH 以空间信息为代价提供了计划的紧凑总结:相同或相似的剂量-体积直方图可能来自于实质上不同的空间剂量图。这正是医生和物理学家在满足所有 DVH 终点的数值要求后仍然仔细检查剂量图的原因。然而,到目前为止,几乎没有采取任何措施来控制空间现象,例如热点的空间分布,这具有重要的临床意义。为此,作者提出了一种新的目标函数,该函数可以在目标覆盖、器官保护和计划靶区(PTV)均匀性之间进行更直接的权衡,并通过四个前列腺病例、一个胰腺病例和一个头颈部病例展示了我们的研究结果,以说明我们方法的优势和普遍适用性。
在设计能量最小化目标(E tot (sparse))时,作者利用了以下稳健的代价函数:(1)不对称线性阱函数,允许对 PTV 中的低剂量、放松处方剂量和高剂量进行不同的惩罚;(2)两段线性函数,对 OAR 中的高剂量和低剂量和中剂量进行强烈惩罚,对低剂量和中剂量进行轻度惩罚;(3)全变差能量,即在 PTV 中剂量梯度的一阶近似上应用 L1 范数。通过最小化这些稳健成本的加权和,可以实现一般的剂量处方和剂量梯度处方的一致性,同时鼓励处方违反遵循拉普拉斯分布。相比之下,传统的二次目标与违反的高斯分布相关联,与拉普拉斯分布相比,它对处方的大违反不太宽容。因此,所提出的目标 E tot (sparse) 通过“牺牲”已经违反的体素来改善 PTV 覆盖、PTV 均匀性和/或 OAR 保护,从而改善规划目标之间的权衡。通过这样做,由于只有当 E tot (sparse) 的净减少发生时才会出现这些大违反,因此整体计划质量会提高。例如,在 E tot (sparse) 优化计划中 PTV 中的大剂量违反自然会集中在 PTV-OAR 重叠处的体素中,在不影响靶区覆盖的情况下,可以增加 OAR 保护。作者使用 DVH 图、剂量图和两个量化指标(量化 PTV 均匀性和过量)来比较我们的方法和相应的临床计划的结果,这两个指标不惩罚低剂量,因为 Etot (sparse)-优化的计划被计划成使其目标覆盖与临床计划相似或更好。最后,使用 2D 调制指数评估计划的可交付性。
该方法使用 IBM 的 CPLEX 优化包(ILOG CPLEX,加利福尼亚州森尼韦尔)实现,使用 12 核 Intel i7 处理器需要 1-4 分钟来解决。在测试过程中,作者针对四个 7 野 6MV 前列腺病例的 Pareto 表面的几个点进行了优化,这些病例针对不同水平的 PTV 均匀性和 OAR 保护进行了优化。通过分析其 DVH 图和剂量图,将生成的结果相互比较,并与临床计划进行比较。在对具有相对较少权衡的四个前列腺病例进行规划后,开发出了一些经验,然后作者将我们的方法应用于一个 7 野 6MV 胰腺病例和一个 9 野 6MV 头颈部病例,以测试我们的方法对更具挑战性病例的潜在影响。作者发现,我们的配方:(1)为平衡 OAR 保护与 PTV 均匀性提供了极好的灵活性;(2)允许剂量规划师比传统目标函数更有效地控制 PTV 的空间剂量分布的演变。特别是,胰腺病例和头颈部病例的 Etot (sparse)-优化计划显著改善了脊髓和腮腺的保护,同时保持或改善了其他 OAR 的保护,并显著改善了 PTV 均匀性。根据二维调制指数,E tot (sparse)-优化计划的交付能力被证明优于其相关的临床计划。
这些结果表明,我们的配方可用于改善复杂疾病部位(如胰腺或头颈部)的剂量成型和 OAR 保护。此外,我们的目标函数和约束条件是线性的,构成了一个线性规划,它可以快速收敛到全局最小值,并且可以很容易地在治疗计划软件中实现。因此,我们预计我们的方法将很快转化为临床,它可能对头颈部等具有挑战性的疾病部位的计划质量产生积极影响。
