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2. Non-conventional Ultra-High Dose Rate (FLASH) Microbeam Radiotherapy Provides Superior Normal Tissue Sparing in Rat Lung Compared to Non-conventional Ultra-High Dose Rate (FLASH) Radiotherapy

Author

Wright, Michael D, primary, Romanelli, Pantaleo, additional, Bravin, Alberto, additional, Le Duc, Geraldine, additional, Brauer-Krisch, Elke, additional, Requardt, Herwig, additional, Bartzsch, Stefan, additional, Hlushchuk, Ruslan, additional, Laissue, Jean-Albert, additional, and Djonov, Valentin, additional

Published
2021
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3. Non-conventional Ultra-High Dose Rate (FLASH) Microbeam Radiotherapy Provides Superior Normal Tissue Sparing in Rat Lung Compared to Non-conventional Ultra-High Dose Rate (FLASH) Radiotherapy

Author

Wright, M, Romanelli, P, Bravin, A, Le Duc, G, Brauer-Krisch, E, Requardt, H, Bartzsch, S, Hlushchuk, R, Laissue, J, Djonov, V, Wright, Michael D, Romanelli, Pantaleo, Bravin, Alberto, Le Duc, Geraldine, Brauer-Krisch, Elke, Requardt, Herwig, Bartzsch, Stefan, Hlushchuk, Ruslan, Laissue, Jean-Albert, Djonov, Valentin, Wright, M, Romanelli, P, Bravin, A, Le Duc, G, Brauer-Krisch, E, Requardt, H, Bartzsch, S, Hlushchuk, R, Laissue, J, Djonov, V, Wright, Michael D, Romanelli, Pantaleo, Bravin, Alberto, Le Duc, Geraldine, Brauer-Krisch, Elke, Requardt, Herwig, Bartzsch, Stefan, Hlushchuk, Ruslan, Laissue, Jean-Albert, and Djonov, Valentin

Abstract

Conventional radiotherapy is a widely used non-invasive form of treatment for many types of cancer. However, due to a low threshold in the lung for radiation-induced normal tissue damage, it is of less utility in treating lung cancer. For this reason, surgery is the preferred treatment for lung cancer, which has the detriment of being highly invasive. Non-conventional ultra-high dose rate (FLASH) radiotherapy is currently of great interest in the radiotherapy community due to demonstrations of reduced normal tissue toxicity in lung and other anatomy. This study investigates the effects of FLASH microbeam radiotherapy, which in addition to ultra-high dose rate incorporates a spatial segmentation of the radiation field, on the normal lung tissue of rats. With a focus on fibrotic damage, this work demonstrates that FLASH microbeam radiotherapy provides an order of magnitude increase in normal tissue radio-resistance compared to FLASH radiotherapy. This result suggests FLASH microbeam radiotherapy holds promise for much improved noninvasive control of lung cancer.

Published
2021

4. Feasibility study of online high-spatial-resolution MOSFET dosimetry in static and pulsed X-ray radiation fields

Author

Rosenfeld, Anatoly B., Lerch, Michael L.F., Kron, Thomas, Brauer-Krisch, Elke, Bravin, Alberto, Holmes-Siedle, Andrew, and Allen, Barry J.

Subjects
Metal oxide semiconductor field effect transistors -- Research, Radiation dosimetry -- Research, X-rays -- Research, Business, Electronics, Electronics and electrical industries
Abstract

Improvements have been made in the measurement of dose profiles in several types of X-ray beams. These include 120-kVp X-ray beams from an orthovoltage X-ray machine, 6-MV Bremsstrahlung from a medical LINAC in conformal mode and the 50-200 keV energy spectrum of microbeams produced at the medical beamline station of the European Synchrotron Radiation Facility. Using a quadruple metal-oxide--semiconductor field-effect transistor (MOSFET) sensor chip in 'edge on' mode together with a newly developed sensor readout system, the feasibility of online scanning of the profiles of quasi-static and pulsed radiation beams was demonstrated. Measurements of synchrotron pulsed microbeams showed that a micrometer-scale spatial resolution was achievable. The use of several MOSFETs on the same chip gave rise to the correction of misalignments of the oxide films of the sensor with respect to the microbeam, ensuring that the excellent spatial resolution of the MOSFET used in 'edge-on' mode was fully utilized.

Published
2001

6. First experimental measurement of the effect of cardio‐synchronous brain motion on the dose distribution during microbeam radiation therapy.

Author

Duncan, Mitchell, Donzelli, Mattia, Pellicioli, Paolo, Brauer‐Krisch, Elke, Davis, Jeremy A., Lerch, Michael L.F., Rosenfeld, Anatoly B., and Petasecca, Marco

Subjects
RADIOTHERAPY, X-rays, SILICON detectors, MOTION, BRAIN tumors, PHOTON beams
Abstract

Purpose: Microbeam radiation therapy (MRT) is an emerging radiation oncology modality ideal for treating inoperable brain tumors. MRT employs quasi‐parallel beams of low‐energy x rays produced from modern synchrotrons. A tungsten carbide multislit collimator (MSC) spatially fractionates the broad beam into rectangular beams. In this study, the MSC creates beams 50 μm wide ("peaks") separated by a center‐to‐center distance of 400 μm ("valleys"). The peak to valley dose ratio (PVDR) is of critical importance to the efficacy of MRT. The underlying radiobiological advantage of MRT relies on high peak dose for tumor control and low valley dose for healthy tissue sparing. Cardio synchronous brain motion of the order 100–200 μm is comparable to microbeam width and spacing. The motion can have a detrimental effect on the PVDR, full width at half maximum (FWHM) of the microbeams, and ultimately the dose distribution. We present the first experimental measurement of the effect of brain motion on MRT dose distribution. Dosimetry in MRT is difficult due to the high dose rate (up to 15–20 kGy/s) and small field sizes. Methods: A real‐time dosimetry system based on a single silicon strip detector (SSSD) has been developed with spatial resolution ~10 μm. The SSSD was placed in a water‐equivalent phantom and scanned through the microbeam distribution. A monodirectional positioning stage reproduced brain motion during the acquisition. Microbeam profiles were reconstructed from the SSSD and compared with Geant4 simulation and radiochromic HD‐V2 film. Results: The SSSD is able to reconstruct dose profiles within 2 μm compared to film. When brain motion is applied the SSSD shows a two time increase in FWHM of profiles and 50% reduction in PVDR. This is confirmed by Geant4 and film data. Conclusions: Motion‐induced misalignment and distortion of microbeams at treatment delivery will result in a reduced PVDR and increased irradiation of additional healthy tissue compromising the radiobiological effectiveness of MRT. The SSSD was able to reconstruct dose profiles under motion conditions and predict similar effects on FWHM and PVDR as by the simulation. The SSSD is a simple to setup, real‐time detector which can provide time‐resolved high spatial resolution dosimetry of microbeams in MRT. [ABSTRACT FROM AUTHOR]

Published
2020
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9. X-Tream quality assurance in synchrotron X-ray microbeam radiation therapy

Author

Fournier, Pauline, Cornelius, Iwan, Donzelli, Mattia, Requardt, Herwig, Nemoz, Christian, Petasecca, Marco, Brauer-Krisch, Elke, Rosenfeld, Anatoly B, Lerch, Michael L. F, Fournier, Pauline, Cornelius, Iwan, Donzelli, Mattia, Requardt, Herwig, Nemoz, Christian, Petasecca, Marco, Brauer-Krisch, Elke, Rosenfeld, Anatoly B, and Lerch, Michael L. F

Abstract

Microbeam radiation therapy (MRT) is a novel irradiation technique for brain tumours treatment currently under development at the European Synchrotron Radiation Facility in Grenoble, France. The technique is based on the spatial fractionation of a highly brilliant synchrotron X-ray beam into an array of microbeams using a multi-slit collimator (MSC). After promising pre-clinical results, veterinary trials have recently commenced requiring the need for dedicated quality assurance (QA) procedures. The quality of MRT treatment demands reproducible and precise spatial fractionation of the incoming synchrotron beam. The intensity profile of the microbeams must also be quickly and quantitatively characterized prior to each treatment for comparison with that used for input to the dose-planning calculations. The Centre for Medical Radiation Physics (University of Wollongong, Australia) has developed an X-ray treatment monitoring system (X-Tream) which incorporates a highspatial- resolution silicon strip detector (SSD) specifically designed for MRT. Inair measurements of the horizontal profile of the intrinsic microbeam X-ray field in order to determine the relative intensity of each microbeam are presented, and the alignment of the MSC is also assessed. The results show that the SSD is able to resolve individual microbeams which therefore provides invaluable QA of the horizontal field size and microbeam number and shape. They also demonstrate that the SSD used in the X-Tream system is very sensitive to any small misalignment of the MSC. In order to allow as rapid QA as possible, a fast alignment procedure of the SSD based on X-ray imaging with a low-intensity low-energy beam has been developed and is presented in this publication.

Published
2016

10. Energy spectra considerations for synchrotron radiotherapy trials on the ID17 bio-medical beamline at the European Synchrotron Radiation Facility

Author

Crosbie, Jeffrey C, Fournier, Pauline, Bartzsch, Stefan, Donzelli, Mattia, Cornelius, Iwan, Stevenson, Andrew W, Requardt, Herwig, Brauer-Krisch, Elke, Crosbie, Jeffrey C, Fournier, Pauline, Bartzsch, Stefan, Donzelli, Mattia, Cornelius, Iwan, Stevenson, Andrew W, Requardt, Herwig, and Brauer-Krisch, Elke

Abstract

The aim of this study was to validate the kilovoltage X-ray energy spectrum on the ID17 beamline at the European Synchrotron Radiation Facility (ESRF). The purpose of such validation was to provide an accurate energy spectrum as the input to a computerized treatment planning system, which will be used in synchrotron microbeam radiotherapy trials at the ESRF. Calculated and measured energy spectra on ID17 have been reported previously but recent additions and safety modifications to the beamline for veterinary trials warranted a fresh investigation. The authors used an established methodology to compare X-ray attenuation measurements in copper sheets (referred to as half value layer measurements in the radiotherapy field) with the predictions of a theoretical model. A cylindrical ionization chamber in air was used to record the relative attenuation of the X-ray beam intensity by increasing thicknesses of high-purity copper sheets. The authors measured the half value layers in copper for two beamline configurations, which corresponded to differing spectral conditions. The authors obtained good agreement between the measured and predicted half value layers for the two beamline configurations. The measured first half value layer was 1.754 +/- 0.035 mm Cu and 1.962 +/- 0.039 mm Cu for the two spectral conditions, compared with theoretical predictions of 1.763 +/- 0.039 mm Cu and 1.984 +/- 0.044 mm Cu, respectively. The calculated mean energies for the two conditions were 105 keV and 110 keVand there was not a substantial difference in the calculated percentage depth dose curves in water between the different spectral conditions. The authors observed a difference between their calculated energy spectra and the spectra previously reported by other authors, particularly at energies greater than 100 keV. The validation of the beam spectrum by the copper half value layer measurements means the authors can provide an accurate spectrum as an input to a treatment planning system

Published
2015

11. Silicon strip detector for quality assurance in synchrotron microbeam radiation therapy

Author

Fournier, Pauline, Cornelius, Iwan, Petasecca, Marco, Brauer-Krisch, Elke, Requardt, Herwig, Dipuglia, Andrew, Roberts, N, Hall, Christopher, Stevenson, Andrew W, Rosenfeld, Anatoly B, Fournier, Pauline, Cornelius, Iwan, Petasecca, Marco, Brauer-Krisch, Elke, Requardt, Herwig, Dipuglia, Andrew, Roberts, N, Hall, Christopher, Stevenson, Andrew W, and Rosenfeld, Anatoly B

Abstract

of an oral communication that presented at the 53es Journées Scientifiques de la Société Française de Physique Médicale, 4-6 June 2014, Deauville, France.

Published
2014

12. Influence of polarization and a source model for dose calculation in MRT

Author

Bartzsch, Stefan, Lerch, Michael, Petasecca, Marco, Brauer-Krisch, Elke, Oelfke, Uwe, Bartzsch, Stefan, Lerch, Michael, Petasecca, Marco, Brauer-Krisch, Elke, and Oelfke, Uwe

Abstract

Purpose: Microbeam Radiation Therapy (MRT), an alternative preclinical treatment strategy using spatially modulated synchrotron radiation on a micrometer scale, has the great potential to cure malignant tumors (e.g., brain tumors) while having low side effects on normal tissue. Dose measurement and calculation in MRT is challenging because of the spatial accuracy required and the arising high dose differences. Dose calculation with Monte Carlo simulations is time consuming and their accuracy is still a matter of debate. In particular, the influence of photon polarization has been discussed in the literature. Moreover, it is controversial whether a complete knowledge of phase space trajectories, i.e., the simulation of the machine from the wiggler to the collimator, is necessary in order to accurately calculate the dose. Methods: With Monte Carlo simulations in the Geant4 toolkit, the authors investigate the influence of polarization on the dose distribution and the therapeutically important peak to valley dose ratios (PVDRs). Furthermore, the authors analyze in detail phase space information provided byMartínez-Rovira et al. ["Development and commissioning of a Monte Carlo photon model for the forthcoming clinical trials in microbeam radiation therapy," Med. Phys.39(1), 119-131 (2012)] and examine its influence on peak and valley doses. A simple source model is developed using parallel beams and its applicability is shown in a semiadjoint Monte Carlo simulation. Results are compared to measurements and previously published data. Results: Polarization has a significant influence on the scattered dose outside the microbeam field. In the radiation field, however, dose and PVDRs deduced from calculations without polarization and with polarization differ by less than 3%. The authors show that the key consequences from the phase space information for dose calculations are inhomogeneous primary photon flux, partial absorption due to inclined beam incidence outside the fiel

Published
2014

13. Benchmarking and validation of a Geant4-SHADOW Monte Carlo simulation for dose calculations in microbeam radiation therapy

Author

Cornelius, Iwan, Guatelli, Susanna, Fournier, Pauline, Crosbie, Jeffrey C, Sanchez del Rio, Manuel, Brauer-Krisch, Elke, Rosenfeld, Anatoly, Lerch, Michael LF, Cornelius, Iwan, Guatelli, Susanna, Fournier, Pauline, Crosbie, Jeffrey C, Sanchez del Rio, Manuel, Brauer-Krisch, Elke, Rosenfeld, Anatoly, and Lerch, Michael LF

Abstract

Microbeam radiation therapy (MRT) is a synchrotron-based radiotherapy modality that uses high-intensity beams of spatially fractionated radiation to treat tumours. The rapid evolution of MRT towards clinical trials demands accurate treatment planning systems (TPS), as well as independent tools for the verification of TPS calculated dose distributions in order to ensure patient safety and treatment efficacy. Monte Carlo computer simulation represents the most accurate method of dose calculation in patient geometries and is best suited for the purpose of TPS verification. A Monte Carlo model of the ID17 biomedical beamline at the European Synchrotron Radiation Facility has been developed, including recent modifications, using the Geant4 Monte Carlo toolkit interfaced with the SHADOW X-ray optics and ray-tracing libraries. The code was benchmarked by simulating dose profiles in water-equivalent phantoms subject to irradiation by broad-beam (without spatial fractionation) and microbeam (with spatial fractionation) fields, and comparing against those calculated with a previous model of the beamline developed using the PENELOPE code. Validation against additional experimental dose profiles in water-equivalent phantoms subject to broad-beam irradiation was also performed. Good agreement between codes was observed, with the exception of out-of-field doses and toward the field edge for larger field sizes. Microbeam results showed good agreement between both codes and experimental results within uncertainties. Results of the experimental validation showed agreement for different beamline configurations. The asymmetry in the out-of-field dose profiles due to polarization effects was also investigated, yielding important information for the treatment planning process in MRT. This work represents an important step in the development of a Monte Carlo-based independent verification tool for treatment planning in MRT.

Published
2014

14. Preferential effect of synchrotron microbeam radiation therapy on intracerebral 9L gliosarcoma vascular networks

Author

Bouchet, A, Lemasson, B, Le Duc, G, Maisin, C, Brauer-Krisch, E, Siegbahn Erik, A, Renaud, L, Khalil, E, Remy, C, Poillot, C, Bravin, A, Laissue Jean, A, Barbier Emmanuel, L, Serduc, R, Bouchet Audrey, Lemasson Benjamin, Le Duc Geraldine, Maisin Cecile, Brauer-Krisch Elke, Siegbahn Erik Albert, Renaud Luc, Khalil Enam, Remy Chantal, Poillot Cathy, Bravin A, Laissue Jean A., Barbier Emmanuel L., Serduc Raphael, Bouchet, A, Lemasson, B, Le Duc, G, Maisin, C, Brauer-Krisch, E, Siegbahn Erik, A, Renaud, L, Khalil, E, Remy, C, Poillot, C, Bravin, A, Laissue Jean, A, Barbier Emmanuel, L, Serduc, R, Bouchet Audrey, Lemasson Benjamin, Le Duc Geraldine, Maisin Cecile, Brauer-Krisch Elke, Siegbahn Erik Albert, Renaud Luc, Khalil Enam, Remy Chantal, Poillot Cathy, Bravin A, Laissue Jean A., Barbier Emmanuel L., and Serduc Raphael

Abstract

Purpose: Synchrotron microbeam radiation therapy (MRT) relies on spatial fractionation of the incident photon beam into parallel micron-wide beams. Our aim was to analyze the effects of MRT on normal brain and 9L gliosarcoma tissues, particularly on blood vessels. Methods and Materials: Responses to MRT (two arrays, one lateral, one anteroposterior (2 × 400 Gy), intersecting orthogonally in the tumor region) were studied during 6 weeks using MRI, immunohistochemistry, and vascular endothelial growth factor Western blot. Results: MRT increased the median survival time of irradiated rats (×3.25), significantly increased blood vessel permeability, and inhibited tumor growth; a cytotoxic effect on 9L cells was detected 5 days after irradiation. Significant decreases in tumoral blood volume fraction and vessel diameter were measured from 8 days after irradiation, due to loss of endothelial cells in tumors as detected by immunochemistry. Edema was observed in the normal brain exposed to both crossfired arrays about 6 weeks after irradiation. This edema was associated with changes in blood vessel morphology and an overexpression of vascular endothelial growth factor. Conversely, vascular parameters and vessel morphology in brain regions exposed to one of the two arrays were not damaged, and there was no loss of vascular endothelia. Conclusions: We show for the first time that preferential damage of MRT to tumor vessels versus preservation of radioresistant normal brain vessels contributes to the efficient palliation of 9L gliosarcomas in rats. Molecular pathways of repair mechanisms in normal and tumoral vascular networks after MRT may be essential for the improvement of such differential effects on the vasculature.

Published
2010

16. Radiation Therapy Using Synchrotron Radiation: Preclinical Studies Toward Clinical Trials.

Author

Adam, Jean-Francois, Balosso, Jacques, Bobyk, Laure, Charvet, Anne-Marie, Deman, Pierre, Edouard, Magali, Elleaume, Helene, Esteve, Francois, Bas, Jean-Francois Le, Rousseau, Julia, Serduc, Raphaël, Vautrin, Mathias, Chabrol, Tanguy, Depaulis, Antoine, Pouyatos, Benoit, Baruchel, Jose, Berkvens, Paul, Berruyer, Gilles, Bouchet, Audrey, and Brauer-Krisch, Elke

Subjects
RADIOTHERAPY, SYNCHROTRON radiation, DIAGNOSTIC imaging, MEDICAL imaging systems, TUMOR treatment, CLINICAL trials, MEDICAL research
Abstract

After decades of intensive research, high-grade gliomas are still resistant to therapies, including surgery, chemotherapy, and radiotherapy or a combination thereof. The most important advance in the treatment of these tumors has been the introduction of a new chemotherapy drug called temozolomide, in combination with external beam photon irradiation [1]. One of the goals of the association of the CHU/UJF/INSERM and ESRF teams has been to develop research on synchrotron radiotherapy up to clinics. [ABSTRACT FROM AUTHOR]

Published
2011
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