Medical physics aspects of the synchrotron radiation therapies: Microbeam radiation therapy (MRT) and synchrotron stereotactic radiotherapy (SSRT)

Bräuer-Krisch, Elke; Adam, Jean-François; Alagöz, E.; Bartzsch, Stefan; Crosbie, Jack; Wagter, Carlos De; Dipuglia, Andrew; Donzelli, Mattia; Doran, Simon J.; Fournier, Pauline; Kalef-Ezra, J.; Kock, Angela; Lerch, Michael L. F; McErlean, Ciara M.; Oelfke, Uwe; Olko, P.; Petasecca, Marco; Povoli, Marco; Rosenfeld, Anatoly B.; Siegbahn, Albert; Sporea, Dan; Stugu, B.

doi:10.1016/j.ejmp.2015.04.016

Cited by 89 publications

(79 citation statements)

References 79 publications

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“…With the presented setup, dose rates of up to 300 mGy/s were reached at a beam width of 50 μ m and a beam‐to‐beam spacing of 400 μ m. Beam‐to‐beam spacing and beam width correspond to the specifications envisaged for future clinical trials at the European Synchrotron (ESRF) in Grenoble 27 . Dose rates for MRT at the European Synchrotron reach between 8 and 16 kGy/s 25 and are orders of magnitude higher than at an x‐ray tube. However, the synchrotron beam at the ESRF has a maximum height of just 520 μ m. Therefore the target has to be scanned through the beam to produce higher fields, while the x‐ray tube produced microbeam field can be applied statically.…”

Section: Discussionmentioning

confidence: 89%

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A preclinical microbeam facility with a conventional x‐ray tube

et al. 2016

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Purpose:Microbeam radiation therapy is an innovative treatment approach in radiation therapy that uses arrays of a few tens of micrometer wide and a few hundreds of micrometer spaced planar x‐ray beams as treatment fields. In preclinical studies these fields efficiently eradicated tumors while normal tissue could effectively be spared. However, development and clinical application of microbeam radiation therapy is impeded by a lack of suitable small scale sources. Until now, only large synchrotrons provide appropriate beam properties for the production of microbeams.Methods:In this work, a conventional x‐ray tube with a small focal spot and a specially designed collimator are used to produce microbeams for preclinical research. The applicability of the developed source is demonstrated in a pilot in vitro experiment. The properties of the produced radiation field are characterized by radiochromic film dosimetry.Results:50 μm wide and 400 μm spaced microbeams were produced in a 20 × 20 mm2 sized microbeam field. The peak to valley dose ratio ranged from 15.5 to 30, which is comparable to values obtained at synchrotrons. A dose rate of up to 300 mGy/s was achieved in the microbeam peaks. Analysis of DNA double strand repair and cell cycle distribution after in vitro exposures of pancreatic cancer cells (Panc1) at the x‐ray tube and the European Synchrotron leads to similar results. In particular, a reduced G2 cell cycle arrest is observed in cells in the microbeam peak region.Conclusions:At its current stage, the source is restricted to in vitro applications. However, moderate modifications of the setup may soon allow in vivo research in mice and rats.

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Section: Discussionmentioning

confidence: 89%

“…The exposure was chosen such that peak doses are at 80 Gy. Technical details of MRT exposures at the ESRF can, for example, be found in Bräuer‐Krisch et al 25 …”

Section: Methodsmentioning

confidence: 99%

A preclinical microbeam facility with a conventional x‐ray tube

et al. 2016

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“…MRT involves the application of an array of spatially fractionated microbeams sourced from third generation synchrotrons, with beam widths ranging from 25 to 75 µm, and a pitch of 200-400 µm [2][3][4][5][6][7][8][9][10][11][12][13][14][15].…”

Section: Introductionmentioning

confidence: 99%

“…Microbeam peak doses of between 500-1000 Gy can be delivered safely due to the wellknown dose volume effect [5][6][7][8].…”

Section: Introductionmentioning

confidence: 99%

“…Small PVDRs indicate that the valley dose between adjacent microbeams, is large in relation to the peak dose. When made comparable to the large peak doses, this indicates better tumour coverage [7,8]. Conversely, a large PVDR and small valley dose may be more accommodating for tissue recovery, allowing normal tissue to be spared through the dose-volume effect [5][6][7][8].…”

Section: Introductionmentioning

confidence: 99%

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Optimizing dose enhancement with Ta 2 O 5 nanoparticles for synchrotron microbeam activated radiation therapy

et al. 2016

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Microbeam Radiation Therapy (MRT) exploits tumour selectivity and normal tissue sparing with spatially fractionated kilovoltage X-ray microbeams through the dose volume effect. Experimental measurements with Ta 2 O 5 nanoparticles (NPs) in 9L gliosarcoma treated with MRT at the Australian Synchrotron, increased the treatment efficiency. Ta 2 O 5 NPs were observed to form shells around cell nuclei which may be the reason for their efficiency in MRT. In this article, our experimental observation of NP shell formation is the basis of a Geant4 radiation transport study to characterise dose enhancement by Ta 2 O 5 NPs in MRT. Our study showed that NP shells enhance the physical dose depending microbeam energy and their location relative to a single microbeam. For monochromatic microbeam energies below ∼70 keV, NP shells show highly localised dose enhancement due to the short range of associated secondary electrons. Low microbeam energies indicate better targeted treatment by allowing higher microbeam doses to be administered to tumours and better exploit the spatial fractionation related selectivity observed with MRT. For microbeam energies above ∼100 keV, NP shells extend the physical dose enhancement due to longer-range secondary electrons. Again, with NPs selectively internalised, the local effectiveness of MRT is expected to increase in the tumour. Dose enhancement produced by the shell aggregate varied more significantly in the cell population, depending on its location, when compared to a homogeneous NP distribution. These combined simulation and experimental data provide first evidence for optimising MRT through the incorporation of newly observed Ta 2 O 5 NP distributions within 9L cancer cells. Disciplines Engineering | Science and Technology Studies Publication DetailsEngels, E., Corde, S., McKinnon, S., Incerti, S., Konstantinov, K., Rozenfeld, A., Tehei, M., . Optimizing dose enhancement with Ta2O5 nanoparticles for synchrotron microbeam activated radiation therapy. Physica Medica: an international journal devoted to the applications of physics to medicine and biology, 32 (12)

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Synchrotron Radiation X‐ray Imaging in Biomedical Research

Wang

Yang

2018

Synchrotron Radiation in Materials Science

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Medical physics aspects of the synchrotron radiation therapies: Microbeam radiation therapy (MRT) and synchrotron stereotactic radiotherapy (SSRT)

Cited by 89 publications

References 79 publications

A preclinical microbeam facility with a conventional x‐ray tube

A preclinical microbeam facility with a conventional x‐ray tube

Optimizing dose enhancement with Ta 2 O 5 nanoparticles for synchrotron microbeam activated radiation therapy

Synchrotron Radiation X‐ray Imaging in Biomedical Research

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