Validation of dosimetric field matching accuracy from proton therapy using a robotic patient positioning system

Farr, J; O’Ryan-Blair, Avril; Jesseph, F.; Hsi, W; Allgower, C.; Mascia, Anthony; Thornton, Allan F.; Schreuder, A. N.

doi:10.1120/jacmp.v11i2.3015

Cited by 9 publications

(9 citation statements)

References 10 publications

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“…Couch translational motion accuracy should be confirmed for the most extreme movements and should have a tolerance of AE1 mm. [113][114][115] The "trueness" of the couch positioning is defined as the motion of an object in a straight line without any deviation from that line. The couch vertical axis trueness should be verified because the couch can be subject to accidental collisions or to malfunction resulting from wear and tear.…”

Section: B2 Couch Rotational Translational and Vertical Axis Acmentioning

confidence: 99%

AAPM task group 224: Comprehensive proton therapy machine quality assurance

et al. 2019

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Purpose: Task Group (TG) 224 was established by the American Association of Physicists in Medicine's Science Council under the Radiation Therapy Committee and Work Group on Particle Beams. The group was charged with developing comprehensive quality assurance (QA) guidelines and recommendations for the three commonly employed proton therapy techniques for beam delivery: scattering, uniform scanning, and pencil beam scanning. This report supplements established QA guidelines for therapy machine performance for other widely used modalities, such as photons and electrons (TG 142, TG 40, TG 24, TG 22, TG 179, and Medical Physics Practice Guideline 2a) and shares their aims of ensuring the safe, accurate, and consistent delivery of radiation therapy dose distributions to patients. Methods: To provide a basis from which machine‐specific QA procedures can be developed, the report first describes the different delivery techniques and highlights the salient components of the related machine hardware. Depending on the particular machine hardware, certain procedures may be more or less important, and each institution should investigate its own situation. Results: In lieu of such investigations, this report identifies common beam parameters that are typically checked, along with the typical frequencies of those checks (daily, weekly, monthly, or annually). The rationale for choosing these checks and their frequencies is briefly described. Short descriptions of suggested tools and procedures for completing some of the periodic QA checks are also presented. Conclusion: Recommended tolerance limits for each of the recommended QA checks are tabulated, and are based on the literature and on consensus data from the clinical proton experience of the task group members. We hope that this and other reports will serve as a reference for clinical physicists wishing either to establish a proton therapy QA program or to evaluate an existing one.

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Section: B2 Couch Rotational Translational and Vertical Axis Acmentioning

confidence: 99%

AAPM task group 224: Comprehensive proton therapy machine quality assurance

et al. 2019

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“…We have previously reported a formal assessment of the accuracy of field matching using our robotic patient positioner and found good agreement between treatment planning calculations and radiographic film and ionization chamber measurements. 34 Most published clinical experiences with proton therapy involved 3D conformal treatment planning in which the desired dosimetry is achieved by manual iterative adjustments in the shape of individual field apertures (blocks) and compensators, or patient-specific devices (PSDs). With uniform scanning, as used in our patients, a uniform dose is delivered across the treatment field with a uniform spread-out Bragg peak (SOBP).…”

Section: Discussionmentioning

confidence: 99%

Technique for comprehensive head and neck irradiation using 3-dimensional conformal proton therapy

2015

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“…Parallel beam scanning systems are considered to be more challenging and more expensive to provide than divergent beam scanning systems. Therefore, the following points need to be considered in relation to the perceived advantage of parallel scanning systems: To some extent, by forcing optimization functions to minimize entrance dose, modulated scanning optimization can also be used to reduce skin dose. Unlike the technical and dosimetric challenges of field matching with scattering systems, robust treatment planning optimization for scanning systems (see “Advanced Treatment Planning” 2018 (in this issue)) provides simple and effective field matching for both parallel and divergent beam geometries. The degree of beam divergence from parallelism also depends on the applied field size (smaller approaches parallelism) and SAD (greater approaches parallelism) for divergent beams. …”

Section: Current State: Beam Transport Systems and Gantriesmentioning

confidence: 99%

“…• Unlike the technical and dosimetric challenges of field matching with scattering systems, 19 robust treatment planning optimization for scanning systems (see "Advanced Treatment Planning" 2018 (in this issue)) provides simple and effective field matching 20 for both parallel and divergent beam geometries.…”

Section: C Scanning Magnet Positionmentioning

confidence: 99%

New horizons in particle therapy systems

Farr¹,

Flanz

Gerbershagen

et al. 2018

Medical Physics

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Particle therapy is rapidly expanding and claiming its position as the treatment modality of choice in teletherapy. However, the rate of expansion continues to be restricted by the size and cost of the associated particle therapy systems and their operation. Additional technical limitations such as dose delivery rate, treatment process efficiency, and achievement of superior dose conformity potentially hinder the complete fulfillment of the promise of particle therapy. These topics are explored in this review considering the current state of particle therapy systems and what improvements are required to overcome the current challenges. Beam production systems (accelerators), beam transport systems including gantries and beam delivery systems are addressed explicitly in these regards.

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Validation of dosimetric field matching accuracy from proton therapy using a robotic patient positioning system

Cited by 9 publications

References 10 publications

AAPM task group 224: Comprehensive proton therapy machine quality assurance

AAPM task group 224: Comprehensive proton therapy machine quality assurance

Technique for comprehensive head and neck irradiation using 3-dimensional conformal proton therapy

New horizons in particle therapy systems

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