<scp>AAPM TG</scp>158: Measurement and calculation of doses outside the treated volume from external‐beam radiation therapy

Kry, Stephen F; Bednarz, Bryan; Howell, Rebecca M.; Dauer, Lawrence T.; Followill, David S; Klein, Eric E.; Paganetti, Harald; Wang, Brian; Wuu, Cheng-Shie; Xu, X. George

doi:10.1002/mp.12462

Cited by 242 publications

(319 citation statements)

References 329 publications

(872 reference statements)

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“…Therefore IC’s over-response in the out-of-field region is negligible, which is also consistent with the literature (Kry et al , 2017). To quantify K OBOF and K IBOF for all PMRT techniques, we transferred PMRT treatment plans from the anthropomorphic phantom to a water phantom in Pinnacle TPS and performed out-of-field dose measurements with TLDs and an IC in solid water phantoms.…”

Section: Methodssupporting

confidence: 92%

Measurement and modeling of out-of-field doses from various advanced post-mastectomy radiotherapy techniques

Yoon¹,

Heins²,

Zhao³

et al. 2017

Phys. Med. Biol.

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More and more advanced radiotherapy techniques have been adopted for post-mastectomy radiotherapies (PMRT). Patient dose reconstruction is challenging for these advanced techniques because they increase the low out-of-field dose area while the accuracy of out-of-field dose calculations by current commercial treatment planning systems (TPSs) is poor. We aim to measure and model the out-of-field radiation doses from various advanced PMRT techniques. PMRT treatment plans for an anthropomorphic phantom were generated, including volumetric modulated arc therapy (VMAT) with standard and flattening-filter-free (FFF) photon beams, mixed beam therapy, 4-field intensity modulated radiation therapy (IMRT), and Tomotherapy. We measured doses in the phantom where the TPS calculated doses were lower than 5% of the prescription dose using thermoluminescent dosimeters (TLD). The TLD measurements were corrected by two additional energy correction factors, namely out-of-beam out-of-field (OBOF) correction factor KOBOF and in-beam out-of-field (IBOF) correction factor KIBOF, which were determined by separate measurements using an ion chamber and TLD. A simple analytical model was developed to predict out-of-field dose as a function of distance from the field edge for each PMRT technique. The root mean square discrepancies between measured and calculated out-of-field doses were within 0.66 cGy/Gy for all techniques. The IBOF doses were highly scattered and should be evaluated case by case. One can easily combine the measured out-of-field dose here with the in-field dose calculated by the local TPS to reconstruct organ doses for a specific PMRT patient if the same treatment apparatus and technique were used.

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Section: Methodssupporting

confidence: 92%

Measurement and modeling of out-of-field doses from various advanced post-mastectomy radiotherapy techniques

Yoon¹,

Heins²,

Zhao³

et al. 2017

Phys. Med. Biol.

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“…The TrueBeam plans had an isocenter placed as far cranially as possible to maximize the separation between the treatment head and the fetus9; additionally, couch kicks were avoided to maximize separation between the treatment head and the fetus and to avoid beam divergence toward the fetus. Beam energy was limited to 6 MV to reduce scatter, head leakage, and neutron contamination, and the flattening filter‐free beam was investigated to assess head leakage reductions from the removal of the flattening filter from the beamline 5, 10. The TrueBeam plans used minimal monitor units (MU) by avoiding highly modulated IMRT or volumetric modulated arc therapy (VMAT), minimizing the number of fields, and using SnS rather than sliding‐window technique for IMRT beams.…”

Section: Methodsmentioning

confidence: 99%

“…It may be possible to achieve a clinically acceptable plan while substantially reducing peripheral dose by modifying these standard treatment planning strategies. Numerous reports have detailed planning strategies to reduce peripheral dose 4, 5, 6, 7, 8, 9, 10. While IMRT is a common choice for intracranial treatments, IMRT often results in higher peripheral dose than 2D‐ or 3D‐conformal treatment techniques 5, 10…”

Section: Introductionmentioning

confidence: 99%

“…While prior reports have provided estimates of peripheral dose for various combinations of beam energy and geometry, these reports often apply to a prior generation of treatment delivery system 1, 4, 5, 6, 10, 11, 12, 13, 14. The present manuscript details fetal dose measurements on current‐generation treatment delivery systems and summarizes the anticipated risks to the patient's fetus using published guidance.…”

Section: Introductionmentioning

confidence: 99%

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Radiation treatment planning and delivery strategies for a pregnant brain tumor patient

Labby

Barraclough

Bayliss

et al. 2018

J Applied Clin Med Phys

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The management of a pregnant patient in radiation oncology is an infrequent event requiring careful consideration by both the physician and physicist. The aim of this manuscript was to highlight treatment planning techniques and detail measurements of fetal dose for a pregnant patient recently requiring treatment for a brain cancer. A 27‐year‐old woman was treated during gestational weeks 19–25 for a resected grade 3 astrocytoma to 50.4 Gy in 28 fractions, followed by an additional 9 Gy boost in five fractions. Four potential plans were developed for the patient: a 6 MV 3D‐conformal treatment plan with enhanced dynamic wedges, a 6 MV step‐and‐shoot (SnS) intensity‐modulated radiation therapy (IMRT) plan, an unflattened 6 MV SnS IMRT plan, and an Accuray TomoTherapy HDA helical IMRT treatment plan. All treatment plans used strategies to reduce peripheral dose. Fetal dose was estimated for each treatment plan using available literature references, and measurements were made using thermoluminescent dosimeters (TLDs) and an ionization chamber with an anthropomorphic phantom. TLD measurements from a full‐course radiation delivery ranged from 1.0 to 1.6 cGy for the 3D‐conformal treatment plan, from 1.0 to 1.5 cGy for the 6 MV SnS IMRT plan, from 0.6 to 1.0 cGy for the unflattened 6 MV SnS IMRT plan, and from 1.9 to 2.6 cGy for the TomoTherapy treatment plan. The unflattened 6 MV SnS IMRT treatment plan was selected for treatment for this particular patient, though the fetal doses from all treatment plans were deemed acceptable. The cumulative dose to the patient's unshielded fetus is estimated to be 1.0 cGy at most. The planning technique and distance between the treatment target and fetus both contributed to this relatively low fetal dose. Relevant treatment planning strategies and treatment delivery considerations are discussed to aid radiation oncologists and medical physicists in the management of pregnant patients.

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“…Therefore, definitions and dose goals across trials to the same body site should be standardized as much as possible with the expectation of evolution of care over time. In addition, the protocol should specify any additional limits to doses to organs outside the treatment field 15. A final critical concern is that some systems ignore the volume of an organ outside the dose calculation grid when reporting dose‐volume parameters.…”

Section: Segmentationmentioning

confidence: 99%

Executive summary of AAPM Report Task Group 113: Guidance for the physics aspects of clinical trials

Moran

Molineu

Kruse

et al. 2018

J Applied Clin Med Phys

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The charge of AAPM Task Group 113 is to provide guidance for the physics aspects of clinical trials to minimize variability in planning and dose delivery for external beam trials involving photons and electrons. Several studies have demonstrated the importance of protocol compliance on patient outcome. Minimizing variability for treatments at different centers improves the quality and efficiency of clinical trials. Attention is focused on areas where variability can be minimized through standardization of protocols and processes through all aspects of clinical trials. Recommendations are presented for clinical trial designers, physicists supporting clinical trials at their individual clinics, quality assurance centers, and manufacturers.

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AAPM TG158: Measurement and calculation of doses outside the treated volume from external‐beam radiation therapy

Cited by 242 publications

References 329 publications

Measurement and modeling of out-of-field doses from various advanced post-mastectomy radiotherapy techniques

Measurement and modeling of out-of-field doses from various advanced post-mastectomy radiotherapy techniques

Radiation treatment planning and delivery strategies for a pregnant brain tumor patient

Executive summary of AAPM Report Task Group 113: Guidance for the physics aspects of clinical trials

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