A novel dose‐based positioning method for CT image‐guided proton therapy

Cheung, J; Park, Peter C.; Court, Laurence Edward; Zhu, Xiaofeng; Kudchadker, Rajat J.; Frank, Steven J.; Dong, Lei

doi:10.1118/1.4801910

Cited by 14 publications

(10 citation statements)

References 33 publications

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“…Moreover, as more experience is gained, the interfractional motion is expected to decrease due to improved immobilization and treatments are expected to become more robust to motion due to improvements in treatment planning and plan adaptations. Lastly, optimizing patient positioning to minimize the dose perturbation can improve target coverage without increasing the setup uncertainty setting [34]. Future work on estimation of stopping power ratios using dual-energy CT can help reduce the range errors found in proton radiography and reduce the required range uncertainty setting [23,35].…”

Section: Discussionmentioning

confidence: 99%

Head and neck IMPT probabilistic dose accumulation: Feasibility of a 2 mm setup uncertainty setting

Wagenaar

Kierkels

Schaaf

et al. 2021

Radiotherapy and Oncology

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Objective: To establish optimal robust optimization uncertainty settings for clinical head and neck cancer (HNC) patients undergoing 3D image-guided pencil beam scanning (PBS) proton therapy. Methods: We analyzed ten consecutive HNC patients treated with 70 and 54.25 Gy RBE to the primary and prophylactic clinical target volumes (CTV) respectively using intensity-modulated proton therapy (IMPT). Clinical plans were generated using robust optimization with 5 mm/3% setup/range uncertainties (RayStation v6.1). Additional plans were created for 4, 3, 2 and 1 mm setup and 3% range uncertainty and for 3 mm setup and 3%, 2% and 1% range uncertainty. Systematic and random error distributions were determined for setup and range uncertainties based on our quality assurance program. From these, 25 treatment scenarios were sampled for each plan, each consisting of a systematic setup and range error and daily random setup errors. Fraction doses were calculated on the weekly verification CT closest to the date of treatment as this was considered representative of the daily patient anatomy. Results: Plans with a 2 mm/3% setup/range uncertainty setting adequately covered the primary and prophylactic CTV (V 95 ! 99% in 98.8% and 90.8% of the treatment scenarios respectively). The average organat-risk dose decreased with 1.1 Gy RBE /mm setup uncertainty reduction and 0.5 Gy RBE /1% range uncertainty reduction. Normal tissue complication probabilities decreased by 2.0%/mm setup uncertainty reduction and by 0.9%/1% range uncertainty reduction. Conclusion: The results of this study indicate that margin reduction below 3 mm/3% is possible but requires a larger cohort to substantiate clinical introduction.

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Section: Discussionmentioning

confidence: 99%

Head and neck IMPT probabilistic dose accumulation: Feasibility of a 2 mm setup uncertainty setting

Wagenaar

Kierkels

Schaaf

et al. 2021

Radiotherapy and Oncology

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“…The standard image guidance for positioning in proton therapy is orthogonal X‐ray42 which has limitations for 3D target positioning. More advanced 3D imaging techniques like in‐room and cone‐beam CT become more and more available and might be beneficial,43, 44, 45 also for direct dose recalculations, dose accumulation and treatment adaptations. Estimations for accumulated doses during the treatment course were not feasible here due to the limitation of having only one control CT available.…”

Section: Discussionmentioning

confidence: 99%

Potential proton and photon dose degradation in advanced head and neck cancer patients by intratherapy changes

Stützer

Jakobi

Bandurska-Luque

et al. 2017

J Applied Clin Med Phys

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PurposeEvaluation of dose degradation by anatomic changes for head‐and‐neck cancer (HNC) intensity‐modulated proton therapy (IMPT) relative to intensity‐modulated photon therapy (IMRT) and identification of potential indicators for IMPT treatment plan adaptation.MethodsFor 31 advanced HNC datasets, IMPT and IMRT plans were recalculated on a computed tomography scan (CT) taken after about 4 weeks of therapy. Dose parameter changes were determined for the organs at risk (OARs) spinal cord, brain stem, parotid glands, brachial plexus, and mandible, for the clinical target volume (CTV) and the healthy tissue outside planning target volume (PTV). Correlation of dose degradation with target volume changes and quality of rigid CT matching was investigated.ResultsRecalculated IMPT dose distributions showed stronger degradation than the IMRT doses. OAR analysis revealed significant changes in parotid median dose (IMPT) and near maximum dose (D 1ml) of spinal cord (IMPT, IMRT) and mandible (IMPT). OAR dose parameters remained lower in IMPT cases. CTV coverage (V 95%) and overdose (V 107%) deteriorated for IMPT plans to (93.4 ± 5.4)% and (10.6 ± 12.5)%, while those for IMRT plans remained acceptable. Recalculated plans showed similarly decreased PTV conformity, but considerable hotspots, also outside the PTV, emerged in IMPT cases. Lower CT matching quality was significantly correlated with loss of PTV conformity (IMPT, IMRT), CTV homogeneity and coverage (IMPT). Target shrinkage correlated with increased dose in brachial plexus (IMRT, IMPT), hotspot generation outside the PTV (IMPT) and lower PTV conformity (IMRT).ConclusionsThe study underlines the necessity of precise positioning and monitoring of anatomy changes, especially in IMPT which might require adaptation more often. Since OAR doses remained typically below constraints, IMPT plan adaptation will be indicated by target dose degradations.

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“…An interesting alternative approach to re‐planning is dose‐guided positioning where treatment plan adaptation is emulated by optimizing the patient positioning to yield an optimal dose distribution in terms of target coverage and organ at risk sparing, potentially reducing the quality assurance workload associated with the creation of a new treatment plan. The necessary data for this procedure are the SPR distribution corresponding to the anatomy of the day as well an updated structure set.…”

Section: Beyond Anatomy‐based Positioningmentioning

confidence: 99%

Current state and future applications of radiological image guidance for particle therapy

Landry

Hua

2018

Medical Physics

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In this review paper, we first give a short overview of radiological image guidance in photon radiotherapy, placing emphasis on the fact that linac based radiotherapy has outpaced particle therapy in the adoption of volumetric image guidance. While cone beam computed tomography (CBCT) has been an established technique in linac treatment rooms for almost two decades, the widespread adoption of volumetric image guidance in particle therapy, whether by means of CBCT or in‐room CT imaging, is recent. This lag may be attributable to the bespoke nature and lower number of particle therapy installations, as well as the differences in geometry between those installations and linac treatment rooms. In addition, for particle therapy the so called shift invariance of the dose distribution rarely applies. An overview of the different volumetric image guidance solutions found at modern particle therapy facilities is provided, covering gantry, nozzle, C‐arm, and couch‐mounted CBCT as well different in‐room CT configurations. A summary of the use of in‐room volumetric imaging data beyond anatomy‐based positioning is also presented as well as the necessary corrections to CBCT images for accurate water equivalent thickness calculation. Finally, the use of non‐ionizing imaging modalities is discussed.

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A novel dose‐based positioning method for CT image‐guided proton therapy

Cited by 14 publications

References 33 publications

Head and neck IMPT probabilistic dose accumulation: Feasibility of a 2 mm setup uncertainty setting

Head and neck IMPT probabilistic dose accumulation: Feasibility of a 2 mm setup uncertainty setting

Potential proton and photon dose degradation in advanced head and neck cancer patients by intratherapy changes

Current state and future applications of radiological image guidance for particle therapy

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