Fredriksson Albin
Optimization and Systems Theory, Department of Mathematics, KTH Royal Institute of Technology, SE-100 44 Stockholm, Sweden.
Med Phys. 2012 Aug;39(8):5169-81. doi: 10.1118/1.4737113.
To characterize a class of optimization formulations used to handle systematic and random errors in radiation therapy, and to study the differences between the methods within this class.
The class of robust methods that can be formulated as minimax stochastic programs is studied. This class generalizes many previously used methods, ranging between optimization of the expected and the worst case objective value. The robust methods are used to plan intensity-modulated proton therapy (IMPT) treatments for a case subject to systematic setup and range errors, random setup errors with and without uncertain probability distribution, and combinations thereof. As reference, plans resulting from a conventional method that uses a margin to account for errors are shown.
For all types of errors, target coverage robustness increased with the conservativeness of the method. For systematic errors, best case organ at risk (OAR) doses increased and worst case doses decreased with the conservativeness. Accounting for random errors of fixed probability distribution resulted in heterogeneous dose. The heterogeneities were reduced when uncertainty in the probability distribution was accounted for. Doing so, the OAR doses decreased with the conservativeness. All robust methods studied resulted in more robust target coverage and lower OAR doses than the conventional method.
Accounting for uncertainties is essential to ensure plan quality in complex radiation therapy such as IMPT. The utilization of more information than conventional in the optimization can lead to robust target coverage and low OAR doses. Increased target coverage robustness can be achieved by more conservative methods.
描述一类用于处理放射治疗中系统误差和随机误差的优化公式,并研究该类方法之间的差异。
研究了可表述为极小极大随机规划的稳健方法类。该类方法概括了许多先前使用的方法,范围涵盖预期目标值和最坏情况目标值的优化。稳健方法用于为一个受系统设置和射程误差、有无不确定概率分布的随机设置误差及其组合影响的病例制定调强质子治疗(IMPT)计划。作为参考,展示了使用余量来考虑误差的传统方法所产生的计划。
对于所有类型的误差,靶区覆盖的稳健性随方法的保守程度增加而提高。对于系统误差,随着保守程度的增加,最佳情况下危及器官(OAR)剂量增加,最坏情况下剂量降低。考虑固定概率分布的随机误差会导致剂量不均匀。当考虑概率分布的不确定性时,不均匀性会降低。这样做时,OAR剂量随保守程度降低。与传统方法相比,所研究的所有稳健方法都能实现更稳健的靶区覆盖和更低的OAR剂量。
在如IMPT这样的复杂放射治疗中,考虑不确定性对于确保计划质量至关重要。在优化过程中利用比传统方法更多的信息可实现稳健的靶区覆盖和低OAR剂量。更保守的方法可提高靶区覆盖的稳健性。
