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First 500 Fractions Delivered with a Magnetic Resonance-guided Radiotherapy System: Initial Experience

Objectives Improved soft-tissue visualization, afforded by magnetic resonance imaging integrated into a radiation therapy linear accelerator-based radiation delivery system (MR-linac) promises improved image-guidance. The availability of MR-imaging can facilitate on-table adaptive radiation planning...

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Autores principales: Sahin, Bilgehan, Zoto Mustafayev, Teuta, Gungor, Gorkem, Aydin, Gokhan, Yapici, Bulent, Atalar, Banu, Ozyar, Enis
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Cureus 2019
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6977582/
https://www.ncbi.nlm.nih.gov/pubmed/32025388
http://dx.doi.org/10.7759/cureus.6457
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author Sahin, Bilgehan
Zoto Mustafayev, Teuta
Gungor, Gorkem
Aydin, Gokhan
Yapici, Bulent
Atalar, Banu
Ozyar, Enis
author_facet Sahin, Bilgehan
Zoto Mustafayev, Teuta
Gungor, Gorkem
Aydin, Gokhan
Yapici, Bulent
Atalar, Banu
Ozyar, Enis
author_sort Sahin, Bilgehan
collection PubMed
description Objectives Improved soft-tissue visualization, afforded by magnetic resonance imaging integrated into a radiation therapy linear accelerator-based radiation delivery system (MR-linac) promises improved image-guidance. The availability of MR-imaging can facilitate on-table adaptive radiation planning and enable real-time intra-fraction imaging with beam gating without additional exposure to radiation. However, the novel use of magnetic resonance-guided radiation therapy (MRgRT) in the field of radiation oncology also potentially poses challenges for routine clinical implementation. Herein the early experience of a single institution, implementing the first MRgRT system in the country is reported. We aim to describe the workflow and to characterize the clinical utility and feasibility of routine use of an MR-linac system. Methods The ViewRay MRIdian MR-linac system consists of a split-magnet 0.35 T MR-imaging scanner with a double focused multi-leaf collimator (MLC) equipped 6MV linear accelerator. Unique to the system are the control console integrated on-table adaptive radiation therapy (oART) planning capabilities as well as automated beam gating based on real-time intra-fraction MR imaging. From the first day of clinical implementation, oART was performed according to physicians’ discretion when medically indicated. All fractions were delivered under real-time imaging with soft tissue-based automated beam gating with individualized gating boundary settings. Patients actively assisted in breath-hold beam gating with the help of custom designed prismatic glasses allowing sight of a computer monitor mounted on the back wall just behind the MRI system bore. Patient demographics and treatment experience, indications for MRgRT including diagnosis and disease site, radiation dose prescribed and fractionation scheme, utilization of oART, respiratory gating settings, as well as duration of each treatment phase were analyzed. Results Between September 2018 and May 2019, 72 patients with 84 tumor sites were treated with MRgRT in 500 total fractions. Median patient age was 66 years (range: 28-83 years). Among 84 tumor sites, the most frequently treated regions were upper abdominal and pelvic (n = 36, 43% and n = 29, 34%, respectively). The most common diagnosis was prostate cancer, with 14 patients treated. In 69 patients (93.2%) oART was used at least once during a treatment course. Twenty-nine targets (43.1%) with significant breathing-related motion were treated in breath-hold with patient visual feedback. Median prescribed dose was 36.25 Gy (range: 24-70 Gy) in median five fractions (range: 3-28 fractions). A gating boundary of 3 mm around a gating region of interest (gROI) was most commonly used (range: 3-5 mm) with 95% of the gROI (range: 93-97%) required to be within the gating boundary for the beam to automatically engage. Mean total treatment time was 47 min (range: 21-125 min) and mean beam-on time was 16.7 min (range: 6-62 min). Conclusions MRgRT afforded by an MR-linac system has been successfully implemented into routine clinical use at our institution as the first system of its kind in Turkey. While the overall number of patients treated and fractions delivered is still limited, we have demonstrated the feasibility of both on-table adaptive radiation therapy as well as automated real-time beam gating on a daily basis in acceptable time schedules.
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spelling pubmed-69775822020-02-05 First 500 Fractions Delivered with a Magnetic Resonance-guided Radiotherapy System: Initial Experience Sahin, Bilgehan Zoto Mustafayev, Teuta Gungor, Gorkem Aydin, Gokhan Yapici, Bulent Atalar, Banu Ozyar, Enis Cureus Radiation Oncology Objectives Improved soft-tissue visualization, afforded by magnetic resonance imaging integrated into a radiation therapy linear accelerator-based radiation delivery system (MR-linac) promises improved image-guidance. The availability of MR-imaging can facilitate on-table adaptive radiation planning and enable real-time intra-fraction imaging with beam gating without additional exposure to radiation. However, the novel use of magnetic resonance-guided radiation therapy (MRgRT) in the field of radiation oncology also potentially poses challenges for routine clinical implementation. Herein the early experience of a single institution, implementing the first MRgRT system in the country is reported. We aim to describe the workflow and to characterize the clinical utility and feasibility of routine use of an MR-linac system. Methods The ViewRay MRIdian MR-linac system consists of a split-magnet 0.35 T MR-imaging scanner with a double focused multi-leaf collimator (MLC) equipped 6MV linear accelerator. Unique to the system are the control console integrated on-table adaptive radiation therapy (oART) planning capabilities as well as automated beam gating based on real-time intra-fraction MR imaging. From the first day of clinical implementation, oART was performed according to physicians’ discretion when medically indicated. All fractions were delivered under real-time imaging with soft tissue-based automated beam gating with individualized gating boundary settings. Patients actively assisted in breath-hold beam gating with the help of custom designed prismatic glasses allowing sight of a computer monitor mounted on the back wall just behind the MRI system bore. Patient demographics and treatment experience, indications for MRgRT including diagnosis and disease site, radiation dose prescribed and fractionation scheme, utilization of oART, respiratory gating settings, as well as duration of each treatment phase were analyzed. Results Between September 2018 and May 2019, 72 patients with 84 tumor sites were treated with MRgRT in 500 total fractions. Median patient age was 66 years (range: 28-83 years). Among 84 tumor sites, the most frequently treated regions were upper abdominal and pelvic (n = 36, 43% and n = 29, 34%, respectively). The most common diagnosis was prostate cancer, with 14 patients treated. In 69 patients (93.2%) oART was used at least once during a treatment course. Twenty-nine targets (43.1%) with significant breathing-related motion were treated in breath-hold with patient visual feedback. Median prescribed dose was 36.25 Gy (range: 24-70 Gy) in median five fractions (range: 3-28 fractions). A gating boundary of 3 mm around a gating region of interest (gROI) was most commonly used (range: 3-5 mm) with 95% of the gROI (range: 93-97%) required to be within the gating boundary for the beam to automatically engage. Mean total treatment time was 47 min (range: 21-125 min) and mean beam-on time was 16.7 min (range: 6-62 min). Conclusions MRgRT afforded by an MR-linac system has been successfully implemented into routine clinical use at our institution as the first system of its kind in Turkey. While the overall number of patients treated and fractions delivered is still limited, we have demonstrated the feasibility of both on-table adaptive radiation therapy as well as automated real-time beam gating on a daily basis in acceptable time schedules. Cureus 2019-12-24 /pmc/articles/PMC6977582/ /pubmed/32025388 http://dx.doi.org/10.7759/cureus.6457 Text en Copyright © 2019, Sahin et al. http://creativecommons.org/licenses/by/3.0/ This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
spellingShingle Radiation Oncology
Sahin, Bilgehan
Zoto Mustafayev, Teuta
Gungor, Gorkem
Aydin, Gokhan
Yapici, Bulent
Atalar, Banu
Ozyar, Enis
First 500 Fractions Delivered with a Magnetic Resonance-guided Radiotherapy System: Initial Experience
title First 500 Fractions Delivered with a Magnetic Resonance-guided Radiotherapy System: Initial Experience
title_full First 500 Fractions Delivered with a Magnetic Resonance-guided Radiotherapy System: Initial Experience
title_fullStr First 500 Fractions Delivered with a Magnetic Resonance-guided Radiotherapy System: Initial Experience
title_full_unstemmed First 500 Fractions Delivered with a Magnetic Resonance-guided Radiotherapy System: Initial Experience
title_short First 500 Fractions Delivered with a Magnetic Resonance-guided Radiotherapy System: Initial Experience
title_sort first 500 fractions delivered with a magnetic resonance-guided radiotherapy system: initial experience
topic Radiation Oncology
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6977582/
https://www.ncbi.nlm.nih.gov/pubmed/32025388
http://dx.doi.org/10.7759/cureus.6457
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