Copenhagen, Denmark
Onsite/Online

ESTRO 2022

Session Item

Applications of ion beam treatment planning
Poster (digital)
Physics
Healthy tissue sparing in proton therapy of lung tumors using statistically sound robust planning
Vlad Badiu, The Netherlands
PO-1506

Abstract

Healthy tissue sparing in proton therapy of lung tumors using statistically sound robust planning
Authors:

Vlad Badiu1, Kevin Souris2, Gregory Buti2, Elena Borderías Villarroel2, Maarten Lambrecht3, Edmond Sterpin1,2

1KU Leuven, Department of Oncology, Laboratory of Experimental Radiotherapy, Leuven, Belgium; 2Université catholique de Louvain, Institut de Recherche Expérimentale et Clinique, Center of Molecular Imaging, Radiotherapy and Oncology (MIRO), Brussels, Belgium; 3Leuven Kanker Instituut, Universitair Ziekenhuis (UZ) Gasthuisberg, Department of Radiotherapy-Oncology, Leuven, Belgium

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Purpose or Objective

Robust planning is essential in proton therapy for ensuring adequate treatment delivery in the presence of uncertainties. For both robust optimization and evaluation, commonly-used techniques can be overly conservative by generating error scenarios from combinations of only maximum error values of each uncertainty source and they lack in providing quantified confidence levels. In this study, we explore whether a clinical benefit can be expected using scenario selection tools with improved statistical foundations, both at the level of robust optimization and evaluation.

Material and Methods

Thirteen lung cancer patients were planned. Two robust optimization methods were used: scenario selection from marginal probabilities (SSMP) based on using maximum setup and range error values and scenario selection from joint probabilities (SSJP) that selects errors on a predefined 90% hypersurface. Two robust evaluation methods were used: conventional evaluation (CE) based on generating error scenarios from combinations of maximum errors of each uncertainty source and statistical evaluation (SE) via the Monte Carlo dose engine MCsquare which considers scenario probabilities. During evaluation we report for the target coverage the D98 (Gy) nominal and worst-case values as well as Dmean (Gy) and V30 (%) for heart and lungs-GTV and D2 (Gy) for spinal cord and esophagus.

Results

Plans optimized using SSJP had, on average, 0.5 Gy lower dose in CTV D98(worst-case) than SSMP-optimized plans. This was expected as the SSJP tool aims at securing robustness at a predefined 90% confidence level with the aim of achieving a level of target robustness situated at the limit of clinical acceptability (i.e., adequate coverage for at least 90% of patients). When evaluated using CE only 76.9% of SSMP patients and 46.2% of SSJP patients passed our clinical threshold. Evaluating with SE, 92.3% of patients passed our clinical threshold in both optimization methods highlighting the impact of evaluating in a statistically consistent manner. Average gains in OAR sparing were recorded when transitioning from SSMP to SSJP in all metrics: esophagus (0.6 Gy D2(nominal), 0.9 Gy D2(worst-case)), spinal cord (3.9 Gy D2(nominal), 4.1 Gy D2(worst-case)) heart (1.1 Gy  Dmean, 1.9% V30), lungs-GTV (1.0 Gy Dmean , 1.9% V30). The reduction of the target margin to the bare minimum is the main drive that enables substantial and consistent OAR sparing.



Conclusion

Establishing a proper robust optimization and evaluation workflow is essential to realize the potential of proton therapy. Optimization using SSJP yielded significant OAR sparing in all recorded metrics with a target robustness within our clinical objectives, provided that a more statistically sound robustness evaluation method was used. This highlights the importance of using both advanced optimization and evaluation tools when we aim at ensuring a quantified level of robustness.