Your search keyword '"Evans MDC"' showing total 8 results

1. Poster - Thur Eve - 31: RapidArc total body photon irradiation: A feasibility study

Author

Evans, MDC, primary, Ruo, R, additional, Seuntjens, J, additional, Freeman, CR, additional, and Parker, W, additional

Published

2012

2. Poster — Thur Eve — 28: Feasibility Study for Open Door Low Energy Treatments Using Maze‐Type Bunkers Designed for Dual Energy Linacs

Author

Evans, MDC, primary, Kildea, J, additional, Beckham, W, additional, Parker, W, additional, and Podgorsak, EB, additional

Published

2010

3. Poster - Thur Eve - 41: Determination of Realistic Workload and Use Factors Using the Varian ARIA Database

Author

Kildea, J, primary, deBlois, F, additional, Parker, W, additional, Podgorsak, EB, additional, and Evans, MDC, additional

Published

2010

4. Evaluation of Dosimetry Formalisms in Intraoperative Radiation Therapy of Glioblastoma.

Author

Ayala Alvarez DS, Watson PGF, Popovic M, Heng VJ, Evans MDC, Panet-Raymond V, and Seuntjens J

Subjects

Female, Humans, Organs at Risk diagnostic imaging, Organs at Risk radiation effects, Radiometry, Radiotherapy Dosage, Retrospective Studies, Breast Neoplasms, Glioblastoma radiotherapy, Glioblastoma surgery

Abstract

Purpose: The intraoperative radiotherapy in newly diagnosed glioblastoma multiforme (INTRAGO) clinical trial assesses survival in patients with glioblastoma treated with intraoperative radiation therapy (IORT) using the INTRABEAM. Treatment planning for INTRABEAM relies on vendor-provided in-water depth dose curves obtained according to the TARGeted Intraoperative radioTherapy (TARGIT) dosimetry protocol. However, recent studies have shown discrepancies between the estimated TARGIT and delivered doses. This work evaluates the effect of the choice of dosimetry formalism on organs at risk (OAR) doses., Methods and Materials: A treatment planning framework for INTRABEAM was developed to retrospectively calculate the IORT dose in 8 INTRAGO patients. These patients received an IORT prescription dose of 20 to 30 Gy in addition to external beam radiation therapy. The IORT dose was obtained using (1) the TARGIT method; (2) the manufacturer's V4.0 method; (3) the C Q method, which uses an ionization chamber Monte Carlo (MC) calculated factor; (4) MC dose-to-water; and (5) MC dose-to-tissue. The IORT dose was converted to 2 Gy fractions equivalent dose., Results: According to the TARGIT method, the OAR dose constraints were respected in all cases. However, the other formalisms estimated a higher mean dose to OARs and revealed 1 case where the constraint for the brain stem was exceeded. The addition of the external beam radiation therapy and TARGIT IORT doses resulted in 10 cases of OARs exceeding the dose constraints. The more accurate MC calculation of dose-to-tissue led to the highest dosimetric differences, with 3, 3, 2, and 2 cases (out of 8) exceeding the dose constraint to the brain stem, optic chiasm, optic nerves, and lenses, respectively. Moreover, the mean cumulative dose to brain stem exceeded its constraint of 66 Gy with the MC dose-to-tissue method, which was not evident with the current INTRAGO clinical practice., Conclusions: The current clinical approach of calculating the IORT dose with the TARGIT method may considerably underestimate doses to nearby OARs. In practice, OAR dose constraints may have been exceeded, as revealed by more accurate methods., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2023

5. Monte Carlo calculation of the TG-43 dosimetry parameters for the INTRABEAM source with spherical applicators.

Author

Ayala Alvarez DS, Watson PGF, Popovic M, Heng VJ, Evans MDC, and Seuntjens J

Subjects

Calibration, Monte Carlo Method, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Brachytherapy, Radiometry

Abstract

Objective: The relative TG-43 dosimetry parameters of the INTRABEAM (Carl Zeiss Meditec AG, Jena, Germany) bare probe were recently reported by Ayala Alvarez et al (2020 Phys. Med. Biol. 65 245041). The current study focuses on the dosimetry characterization of the INTRABEAM source with the eight available spherical applicators according to the TG-43 formalism using Monte Carlo (MC) simulations., Approach: This report includes the calculated dose-rate conversion coefficients that determine the absolute dose rate to water at a reference point of 10 mm from the applicator surface, based on calibration air-kerma rate measurements at 50 cm from the source on its transverse plane. Since the air-kerma rate measurements are not yet provided from a standards laboratory for the INTRABEAM, the values in the present study were calculated with MC. This approach is aligned with other works in the search for standardization of the dosimetry of electronic brachytherapy sources. As a validation of the MC model, depth dose calculations along the source axis were compared with calibration data from the source manufacturer., Main Results: The calculated dose-rate conversion coefficients were 434.0 for the bare probe, and 683.5, 548.3, 449.9, 376.5, 251.0, 225.6, 202.8, and 182.6 for the source with applicators of increasing diameter from 15 to 50 mm, respectively. The radial dose and the 2D anisotropy functions of the TG-43 formalism were also obtained and tabulated in this document., Significance: This work presents the data required by a treatment planning system for the characterization of the INTRABEAM system in the context of intraoperative radiotherapy applications., (© 2021 Institute of Physics and Engineering in Medicine.)

Published

2021

6. Monte Carlo calculation of the relative TG-43 dosimetry parameters for the INTRABEAM electronic brachytherapy source.

Author

Ayala Alvarez DS, G F Watson P, Popovic M, Jean Heng V, Evans MDC, and Seuntjens J

Subjects

Anisotropy, Humans, Intraoperative Period, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Uncertainty, Brachytherapy, Monte Carlo Method, Radiometry

Abstract

The INTRABEAM system (Carl Zeiss Meditec AG, Jena, Germany) is an electronic brachytherapy (eBT) device designed for intraoperative radiotherapy applications. To date, the INTRABEAM x-ray source has not been characterized according to the AAPM TG-43 specifications for brachytherapy sources. This restricts its modelling in commercial treatment planning systems (TPSs), with the consequence that the doses to organs at risk are unknown. The aim of this work is to characterize the INTRABEAM source according to the TG-43 brachytherapy dosimetry protocol. The dose distribution in water around the source was determined with Monte Carlo (MC) calculations. For the validation of the MC model, depth dose calculations along the source longitudinal axis were compared with measurements using a soft x-ray ionization chamber (PTW 34013) and two synthetic diamond detectors (microDiamond PTW TN60019). In our results, the measurements in water agreed with the MC model calculations within uncertainties. The use of the microDiamond detector yielded better agreement with MC calculations, within estimated uncertainties, compared to the ionization chamber at points of steeper dose gradients. The radial dose function showed a steep fall-off close to the INTRABEAM source ([Formula: see text]10 mm) with a gradient higher than that of commonly used brachytherapy radionuclides ( 192 Ir, 125 I and 103 Pd), with values of 2.510, 1.645 and 1.232 at 4, 6 and 8 mm, respectively. The radial dose function partially flattens at larger distances with a fall-off comparable to that of the Xoft Axxent® (iCAD, Inc., Nashua, NH) eBT system. The simulated 2D polar anisotropy close to the bare probe walls showed deviations from unity of up to 55% at 10 mm and 155°. This work presents the MC calculated TG-43 parameters for the INTRABEAM, which constitute the necessary data for the characterization of the source as required by a TPS used in clinical dose calculations.

Published

2020

7. RapidBrachyMCTPS: a Monte Carlo-based treatment planning system for brachytherapy applications.

Author

Famulari G, Renaud MA, Poole CM, Evans MDC, Seuntjens J, and Enger SA

Subjects

Humans, Monte Carlo Method, Phantoms, Imaging, Radiotherapy Dosage, Brachytherapy methods, Radiotherapy Planning, Computer-Assisted methods, Software

Abstract

Despite being considered the gold standard for brachytherapy dosimetry, Monte Carlo (MC) has yet to be implemented into a software for brachytherapy treatment planning. The purpose of this work is to present RapidBrachyMCTPS, a novel treatment planning system (TPS) for brachytherapy applications equipped with a graphical user interface (GUI), optimization tools and a Geant4-based MC dose calculation engine, RapidBrachyMC. Brachytherapy sources and applicators were implemented in RapidBrachyMC and made available to the user via a source and applicator library in the GUI. To benchmark RapidBrachyMC, TG-43 parameters were calculated for the microSelectron v2 ( 192 Ir) and SelectSeed ( 125 I) source models and were compared against previously validated MC brachytherapy codes. The performance of RapidBrachyMC was evaluated for a prostate high dose rate case. To assess the accuracy of RapidBrachyMC in a heterogeneous setup, dose distributions with a cylindrical shielded/unshielded applicator were validated against film measurements in a Solid Water TM phantom. TG-43 parameters calculated using RapidBrachyMC generally agreed within 1%-2% of the results obtained in previously published work. For the prostate case, clinical dosimetric indices showed general agreement with Oncentra TPS within 1%. Simulation times were on the order of minutes on a single core to achieve uncertainties below 2% in voxels within the prostate. The calculation time was decreased further using the multithreading features of Geant4. In the comparison between MC-calculated and film-measured dose distributions, at least 95% of points passed the 3%/3 mm gamma index criteria in all but one case. RapidBrachyMCTPS can be used as a post-implant dosimetry toolkit, as well as for MC-based brachytherapy treatment planning. This software is especially well suited for the development of new source and applicator models.

Published

2018

8. Rotational total skin electron irradiation with a linear accelerator.

Author

Reynard EP, Evans MDC, Devic S, Parker W, Freeman CR, Roberge D, and Podgorsak EB

Subjects

Calibration, Computers, Dose-Response Relationship, Radiation, Electrons, Equipment Design, Humans, Ions, Oxides chemistry, Phantoms, Imaging, Semiconductors, Skin pathology, X-Ray Film, Particle Accelerators instrumentation, Radiotherapy methods, Skin radiation effects

Abstract

The rotational total skin electron irradiation (RTSEI) technique at our institution has undergone several developments over the past few years. Replacement of the formerly used linear accelerator has prompted many modifications to the previous technique. With the current technique, the patient is treated with a single large field while standing on a rotating platform, at a source-to-surface distance of 380 cm. The electron field is produced by a Varian 21EX linear accelerator using the commercially available 6 MeV high dose rate total skin electron mode, along with a custom-built flattening filter. Ionization chambers, radiochromic film, and MOSFET (metal oxide semiconductor field effect transistor) detectors have been used to determine the dosimetric properties of this technique. Measurements investigating the stationary beam properties, the effects of full rotation, and the dose distributions to a humanoid phantom are reported. The current treatment technique and dose regimen are also described.

Published

2008