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Improved Ipsilateral Breast and Chest Wall Sparing With MR-Guided 3-fraction Accelerated Partial Breast Irradiation: A Dosimetric Study Comparing MR-Linac and CT-Linac Plans

PURPOSE: External beam accelerated partial breast irradiation (APBI) is subject to treatment uncertainties that must be accounted for through planning target volume (PTV) margin. We hypothesize that magnetic resonance–guided radiation therapy with reduced PTV margins enabled by real-time cine magnet...

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Detalles Bibliográficos
Autores principales: Musunuru, Hima Bindu, Yadav, Poonam, Olson, Stephanie J., Anderson, Bethany M.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Elsevier 2021
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8233460/
https://www.ncbi.nlm.nih.gov/pubmed/34195491
http://dx.doi.org/10.1016/j.adro.2021.100654
Descripción
Sumario:PURPOSE: External beam accelerated partial breast irradiation (APBI) is subject to treatment uncertainties that must be accounted for through planning target volume (PTV) margin. We hypothesize that magnetic resonance–guided radiation therapy with reduced PTV margins enabled by real-time cine magnetic resonance image (MRI) target monitoring results in better normal tissue sparing compared with computed tomography (CT)-guided radiation therapy with commonly used clinical PTV margins. In this study, we compare the plan quality of ViewRay MRIdian Linac forward planned intensity modulated radiation therapy and TrueBeam volumetric modulated arc therapy for a novel 3-fraction APBI schedule. METHODS AND MATERIALS: Targets and organs at risk (OARs) were segmented for 10 patients with breast cancer according to NSABP B39/RTOG 0413 protocol. A 3 mm margin was used to generate MR PTV(3mm) and CT PTV(3mm) plans, and a 10 mm margin was used for CT PTV(10mm). An APBI schedule delivering 24.6 Gy to the clinical target volume and 23.4 Gy to the PTV in 3 fractions was used. OAR dose constraints were scaled down from existing 5-fraction APBI protocols. Target and OAR dose-volume metrics for the following data sets were analyzed using Wilcoxon matched-pairs signed-rank test: (1) MR PTV(3mm) versus CT PTV(3mm) plans and (2) MR PTV(3mm) versus CT PTV(10mm). RESULTS: Average PTVs were 84.3 ± 51.9 cm(3) and 82.6 ± 55 cm(3) (P = .5) for MR PTV(3mm) and CT PTV(3mm) plans, respectively. PTV V23.4Gy, dose homogeneity index, conformity index (CI), and R50 were similar. There was no meaningful difference in OAR metrics, despite MR PTV(3mm) being larger than the CT PTV(3mm) in 70% of the patients. Average PTVs for MR PTV(3mm) and CT PTV(10mm) plans were 84.3 ± 51.9 cm(3) and 131.7 ± 74.4 cm(3), respectively (P = .002). PTV V23.4Gy was 99% ± 0.9% versus 97.6% ± 1.4% (P = .03) for MR PTV(3mm) and CT PTV(10mm), respectively. Dose homogeneity index, CI, and R50 were similar. MR PTV(3mm) plans had better ipsilateral breast (V12.3Gy, 34.8% ± 12.7% vs 44.4% ± 10.9%, P = .002) and chest wall sparing (V24Gy, 8.5 ± 5.5 cm(3) vs 21.8 ± 14.9 cm(3), P = .004). CONCLUSIONS: MR- and CT-based planning systems produced comparable plans when a 3 mm PTV margin was used for both plans. As expected, MR PTV(3mm) plans produced better ipsilateral breast and chest wall sparing compared with CT PTV(10mm). The clinical relevance of these differences in dosimetric parameters is not known.