Quantifying Proton Fields for Midline Brain Tumors: A Benefit/Cost Analysis of Planning Objectives

dc.contributor.authorEstabrook, Neil C.
dc.contributor.authorHoene, Ted A.
dc.contributor.authorCarlin, Paul S.
dc.contributor.authorMcDonald, Mark W.
dc.contributor.departmentRadiation Oncology, School of Medicineen_US
dc.date.accessioned2020-01-08T18:46:49Z
dc.date.available2020-01-08T18:46:49Z
dc.date.issued2016
dc.description.abstractPurpose: We sought to quantify the optimum number of beams by using a midline sagittal arrangement for midline brain tumors when considering the competing demands of a high degree of target conformation and maximizing reduction of nontarget brain dose. The volume of nontarget brain tissue receiving between 5 and 20 Gy (V5-V20) was selected to measure "low-dose bath" to normal brain. Materials and Methods: An exploratory model was developed with 6 midline brain targets created by using spheres of 1-, 3-, and 5-cm diameters located in superficial and deep locations. For each, five 3-dimensional proton treatment plans with uniform beam scanning were generated by using 1 to 5 fields. Dose-volume histograms were analyzed to calculate conformation number and V5-V20. A benefit/cost analysis was performed to determine the marginal gain in conformation number and the marginal cost of V5-V20 for the addition of each field and hypothesize the optimum number of treatment fields. We tested our hypothesis by re-planning 10 actual patient tumors with the same technique to compare the averages of these 50 plans to our model. Results: Our model and validation cohort demonstrated the largest marginal benefit in target conformation and the lowest marginal cost in normal brain V5-V20 with the addition of a second proton field. The addition of a third field resulted in a relative marginal benefit in target conformation of just 3.9% but a relative marginal cost in V5-V20 of 78.7%. Normal brain absolute V5-V20 increased in a nearly linear fashion with each additional field. Conclusions: When treating midline brain lesions with 3-dimensional proton therapy in an array of midline sagittal beams, our model suggests the most appropriate number of fields is 2. There was little marginal benefit in target conformation and increasing cost of normal brain dose when increasing the number of fields beyond this.en_US
dc.identifier.citationEstabrook, N. C., Hoene, T. A., Carlin, P. S., & McDonald, M. W. (2016). Quantifying Proton Fields for Midline Brain Tumors: A Benefit/Cost Analysis of Planning Objectives. International journal of particle therapy, 3(1), 13–20. doi:10.14338/IJPT-15-00039.1en_US
dc.identifier.urihttps://hdl.handle.net/1805/21784
dc.language.isoen_USen_US
dc.publisherThe Particle Therapy Cooperative Groupen_US
dc.relation.isversionof10.14338/IJPT-15-00039.1en_US
dc.relation.journalInternational Journal of Particle Therapyen_US
dc.rightsPublisher Policyen_US
dc.sourcePMCen_US
dc.subjectProtonsen_US
dc.subjectCentral nervous systemen_US
dc.subjectBrainen_US
dc.subjectDosimetryen_US
dc.titleQuantifying Proton Fields for Midline Brain Tumors: A Benefit/Cost Analysis of Planning Objectivesen_US
dc.typeArticleen_US
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