Stopping‐power ratios for electron beams used in total skin electron therapy

Ding, G

doi:10.1002/mp.15121

Cited by 3 publications

(14 citation statements)

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“…Although for rotational technique similar mean dose coverages at the 1st 5 mm skin are seen, the dose coverages at the 2nd, and the 3rd 5 mm skin are significantly reduced for patient treated at the extended distance 500 cm. This is because the depth, R 50 , in water at which the absorbed dose falls to 50% of its maximum value, decreases approximately 1 mm for each additional 100 cm extended distances 17 . The thickness of the acrylic scatter plate needs to be reduced in order to achieve the same skin depth coverage.…”

Section: Resultsmentioning

confidence: 99%

“…This is because the depth,R 50 ,in water at which the absorbed dose falls to 50% of its maximum value, decreases approximately 1 mm for each additional 100 cm extended distances. 17 The thickness of the acrylic scatter plate needs to be reduced in order to achieve the same skin depth coverage. Therefore, when patients are treated at an extended distance of 700 cm, there is no need to have an acrylic scatter plate in the patient treatment.…”

Section: Resultsmentioning

confidence: 99%

“…The Monte Carlo EGSnrc system 12–14 was used to generate the incident beams, 6 MeV high dose rate total skin electron (HDTSe) beams, from Varian Clinac and TrueBeam accelerators, which are currently used in our institutions for TSET. The EGSnrc 12,13 system has been successfully used to simulate electron beams used in TSET in recent years 11,15–17 …”

Section: Methodsmentioning

confidence: 99%

“…The EGSnrc 12,13 system has been successfully used to simulate electron beams used in TSET in recent years. 11,[15][16][17] The generation of the incident electron beams and the validation of the beam simulation for the 6 MeV HDTSe beam from Varian TrueBeam used in this study have been reported in a previous study. 11 The simu-lated beams were stored in phase-space files for patient dose calculations, and the default EGSnrc 13 simulation parameters were used in this study.…”

Section: Methodsmentioning

confidence: 99%

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Skin dose distributions between Stanford and rotational techniques in total skin electron therapy (TSET)

et al. 2022

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Total skin electron therapy (TSET) has proven to be one of the most effective treatments for advanced-stage cutaneous T-cell lymphoma. Two most used techniques are the Stanford six-field and rotational techniques. This study compares patient skin dose distributions as a function of depth between these two techniques. Methods: The EGSnrc system was used to simulate electron beams and calculate patient dose distributions. The calculations assumed the same patient standing on a platform, and the patient's different postures were ignored for the Stanford technique in the comparison of dose distributions. The skin doses were analyzed as a function of skin depth-dose coverage and evaluated using dosevolume-histograms (DVH). The comparisons were performed in three realistic clinical settings in which dual-field were used for patients treated at extended distances of 316 and 500 cm, and a single field was used at 700 cm. In all cases the realistic patient treatment beam delivery geometry was simulated. Results: Although small dose differences were observed in some local areas, no clinically significant differences were found in the patient 3D dose distributions between the Stanford and rotational techniques. Virtually the same DVH curves between two the techniques were observed for mean dose to skin depth of 0-5, 5-10, and 10-15 mm from the skin surface, respectively. It is found that the skin depth dose coverage is 2 mm shallower for patient treatment at 500 cm compared to at 316 cm due to the additional air attenuation. However, very similar dose coverage and uniformity can be achieved at these two different extended treatment distances by adjusting the thickness of acrylic scatter plate. Adequate thickness of a scattering plate improves the skin dose uniformity. Conclusion: Both the Stanford and rotational techniques deliver very similar skin dose coverage in DVH plots, and only small differences are seen in local areas. It is worth to emphasize that the DVH is a graphical representation of the distribution of dose within a structure, and it does not contain spatial information. Therefore, comparison of entire skin dose using DVH may mask some variations at different locations of the surface area. In addition, the comparison did not consider different patient postures of the Stanford technique. Including the different patient postures in the calculation may affect the result of doses to the limbs. K E Y W O R D S Monte Carlo, patient skin dose distributions, rotational technique, stanford technique, total skin electron therapy 6646

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Skin dose distributions between Stanford and rotational techniques in total skin electron therapy (TSET)

et al. 2022

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“…13,14 There are very limited measured bremsstrahlung data for extended distances greater than 300 cm. Investigation by Chen et al 9 showed that bremsstrahlung dose is only ∼1% even at SSD > 500 cm for a 6 MeV beam from Varian 21EX-S and compared with the data of Das et al 12 The discrepancy was assumed to be caused by different 6 MeV beams generated from a Varian 21 EX-S and Saturne-I machines reported by Das et al 12 The results from recent Monte Carlo studies of 6 MeV beams by Ding et al 15,16 did not find a significant increase in bremsstrahlung doses even at extended distances of up to 700 cm. These results challenge the accuracy of the common belief that the bremsstrahlung dose is up to 5% at an extended distance of 500 cm.…”

Section: Introductionmentioning

confidence: 88%

Technical note: Bremsstrahlung dose in the electron beam at extended distances in total skin electron therapy

2022

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Electron beam from a linear accelerator is commonly used in total skin electron therapy (TSET) at extended distances. Since Das et al (Med Phys 21, p.1733, 1994 reported 5% bremsstrahlung dose for a 6 MeV electron beam at extended distance of 500 cm it has been accepted as common knowledge. However, measurements by Chen et al (Int J. Rad Onc Biol Phys 59 p.872, 2004) and Monte Carlo simulations by Ding et al (Phys. Med. Biol. 66, 075010, 2021) were unable to reproduce such high bremsstrahlung dose. As bremsstrahlung dose contributes to whole-body dose, which could produce bone marrow toxicity with serious complications for the outcome of the TSET, it is important to reevaluate the magnitude of bremsstrahlung dose accurately. Methods: The EGSnrc Monte Carlo system is used to investigate bremsstrahlung doses from 6 MeV high dose rate total skin electron (HDTSe) beams from Varian TrueBeam and Clinac Accelerators. The measurements were carried out at a depth of d max and 5 cm in Solid Water and Acrylic phantoms at extended distances using a parallel-plate chamber and a cylindrical ion chamber. Results: We were able to reproduce previously reported high bremsstrahlung dose at extended distances by using a parallel plate ionization chamber. However, both the measurements made by using a cylindrical chamber and Monte Carlo simulations showed an insignificant bremsstrahlung dose (∼1%) even at SSD = 500 cm. Conclusion:The bremsstrahlung doses of a 6 MeV electron beam are 0.5% to 1% for SSD from 100 to 700 cm, although it increases with the increasing extended distance. The common belief of up to 5% bremsstrahlung dose at large extended distances is incorrect. Previously reported high bremsstrahlung doses might be due to poor signal-to-noise ratio of using a parallel plate chamber for measuring very low dose or particular setup. K E Y W O R D Sbremsstrahlung dose, cylindrical ion chamber, Monte Carlo simulation, parallel plate ion chamber, total skin electron therapy

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Dual-Fields Rotational Total Skin Electron Therapy: Investigation and Implementation

Xu,

Rusu,

Garza

2024

IJMPCERO

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Purpose: To present a protocol of a dual-field rotational (DFR) total skin electron therapy (TSET) and to provide an assessment of clinical implementation, dosimetry properties, and skin dose evaluation. Methods and Materials: The DFR-TSET combined the Stanford 6-field and McGill rotational methods. Dual 6 MeV electron beams in high dose total skin electron mode were used for DFR-TSET on a commercial linac. Beam profiles and dosimetric properties were measured using solid phantoms. The dose rate at expanded sourceto-surface distance (SSD) was a combination of static rate and rotational rate.In vivo dosimetry of patient skin was performed on patients' skin using film, metal oxide semiconductor field-effect transistors (MOSFET), and optically stimulated luminescent dosimeters (OSLD). Results: Dual field rotational total skin electron therapy exhibited good (≤±10%) uniformity in the beam profiles in the vertical direction at an extended SSD of 332 cm with a gantry angulation of ±20˚ deviated from the horizontal direction. In-vivo measurements confirmed acceptable uniformity of the patients' total body surfaces and revealed anatomically self-blocked or shielded areas where under-dosing occurred. Conclusions: The clinical implementation of DFR-TSET effectively utilizes the special mode on a linac. This technique provides short beam-on times, uniform dose distribution, large treatment field, and reduced dose of x-ray contamination to the patients. In-vivo measurements indicate satisfactory delivery and dose uniformity of the prescribed dose. Electron boost fields are recommended at normal SSDs to address underdosed areas.

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Stopping‐power ratios for electron beams used in total skin electron therapy

Cited by 3 publications

References 40 publications

Skin dose distributions between Stanford and rotational techniques in total skin electron therapy (TSET)

Skin dose distributions between Stanford and rotational techniques in total skin electron therapy (TSET)

Technical note: Bremsstrahlung dose in the electron beam at extended distances in total skin electron therapy

Dual-Fields Rotational Total Skin Electron Therapy: Investigation and Implementation

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