Technical note: Optimization functions for re-irradiation treatment planning

Jakob Ödén; Kjell Eriksson; Stina Svensson; John Lilley; Christopher Thompson; Christopher Pagett; Ane Appelt; Louise Murray; Rasmus Bokrantz

doi:10.1002/mp.16815

Technical note: Optimization functions for re-irradiation treatment planning

Med Phys. 2024 Jan;51(1):476-484. doi: 10.1002/mp.16815. Epub 2023 Nov 3.

Authors

Affiliations

¹ RaySeach Laboratories AB, Stockholm, Sweden.
² Department of Medical Physics, Leeds Cancer Centre, St. James' University Hospital, Leeds, UK.
³ Leeds Institute of Medical Research at St James's, University of Leeds, Leeds, UK.
⁴ Department of Clinical Oncology, Leeds Cancer Centre, St. James' University Hospital, Leeds, UK.

PMID: 37921262
DOI: 10.1002/mp.16815

Abstract

Background: Although re-irradiation is increasingly used in clinical practice, almost no dedicated planning software exists.

Purpose: Standard dose-based optimization functions were adjusted for re-irradiation planning using accumulated equivalent dose in 2-Gy fractions (EQD2) with rigid or deformable dose mapping, tissue-specific α/β, treatment-specific recovery coefficients, and voxelwise adjusted EQD2 penalization levels based on the estimated previously delivered EQD2 (EQD2_deliv ).

Methods: To demonstrate proof-of-concept, 35 Gy in 5 fractions was planned to a fictitious spherical relapse planning target volume (PTV) in three separate locations following previous prostate treatment on a virtual human phantom. The PTV locations represented one repeated irradiation scenario and two re-irradiation scenarios. For each scenario, three re-planning strategies with identical PTV dose-functions but various organ at risk (OAR) EQD2-functions was used: 1) reRT_regular : Regular functions with fixed EQD2 penalization levels larger than EQD2_deliv for all OAR voxels. 2) reRT_reduce : As reRT_regular , but with lower fixed EQD2 penalization levels aiming to reduce OAR EQD2. 3) reRT_voxelwise : As reRT_regular and reRT_reduce , but with voxelwise adjusted EQD2 penalization levels based on EQD2_deliv . PTV near-minimum and near-maximum dose (D_98% /D_2% ), homogeneity index (HI), conformity index (CI) and accumulated OAR EQD2 (α/β = 3 Gy) were evaluated.

Results: For the repeated irradiation scenario, all strategies resulted in similar dose distributions. For the re-irradiation scenarios, reRT_reduce and reRT_voxelwise reduced accumulated average and near-maximum EQD2 by ˜1-10 Gy for all relevant OARs compared to reRT_regular . The reduced OAR doses for reRT_reduce came at the cost of distorted dose distributions with D_98% = 92.3%, HI = 12.0%, CI = 73.7% and normal tissue hot spots ≥150% for the most complex scenario, while reRT_regular (D_98% = 98.1%, HI = 3.2%, CI = 94.2%) and reRT_voxelwise (D_98% = 96.9%, HI = 6.1%, CI = 93.7%) fulfilled PTV coverage without hot spots.

Conclusions: The proposed re-irradiation-specific EQD2-based optimization functions introduce novel planning possibilities with flexible options to guide the trade-off between target coverage and OAR sparing with voxelwise adapted penalization levels based on EQD2_deliv .

Keywords: equivalent dose; optimization functions; re-irradiation.

MeSH terms

Humans
Male
Organs at Risk / radiation effects
Radiotherapy Dosage
Radiotherapy Planning, Computer-Assisted / methods
Radiotherapy, Intensity-Modulated* / methods
Re-Irradiation*

Abstract

MeSH terms

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