Literature DB >> 31655869

A proof of principle experiment for microbeam radiation therapy at the Munich compact light source.

Annique C Dombrowsky1,2, Karin Burger2,3,4, Ann-Kristin Porth2, Marlon Stein1,2, Martin Dierolf3,4, Benedikt Günther4, Klaus Achterhold3,4, Bernhard Gleich4, Annette Feuchtinger5, Stefan Bartzsch1,2, Elke Beyreuther6,7, Stephanie E Combs1,2,8, Franz Pfeiffer3,4,9, Jan J Wilkens2,3, Thomas E Schmid10,11.   

Abstract

Microbeam radiation therapy (MRT), a preclinical form of spatially fractionated radiotherapy, uses an array of microbeams of hard synchrotron X-ray radiation. Recently, compact synchrotron X-ray sources got more attention as they provide essential prerequisites for the translation of MRT into clinics while overcoming the limited access to synchrotron facilities. At the Munich compact light source (MuCLS), one of these novel compact X-ray facilities, a proof of principle experiment was conducted applying MRT to a xenograft tumor mouse model. First, subcutaneous tumors derived from the established squamous carcinoma cell line FaDu were irradiated at a conventional X-ray tube using broadbeam geometry to determine a suitable dose range for the tumor growth delay. For irradiations at the MuCLS, FaDu tumors were irradiated with broadbeam and microbeam irradiation at integral doses of either 3 Gy or 5 Gy and tumor growth delay was measured. Microbeams had a width of 50 µm and a center-to-center distance of 350 µm with peak doses of either 21 Gy or 35 Gy. A dose rate of up to 5 Gy/min was delivered to the tumor. Both doses and modalities delayed the tumor growth compared to a sham-irradiated tumor. The irradiated area and microbeam pattern were verified by staining of the DNA double-strand break marker γH2AX. This study demonstrates for the first time that MRT can be successfully performed in vivo at compact inverse Compton sources.

Entities:  

Keywords:  Growth delay; Inverse Compton X-ray sources; MRT; Microbeam; Tumor; X-rays

Mesh:

Substances:

Year:  2019        PMID: 31655869     DOI: 10.1007/s00411-019-00816-y

Source DB:  PubMed          Journal:  Radiat Environ Biophys        ISSN: 0301-634X            Impact factor:   1.925


  41 in total

1.  Multimodal hard X-ray imaging of a mammography phantom at a compact synchrotron light source.

Authors:  Simone Schleede; Martin Bech; Klaus Achterhold; Guillaume Potdevin; Martin Gifford; Rod Loewen; Cecile Limborg; Ronald Ruth; Franz Pfeiffer
Journal:  J Synchrotron Radiat       Date:  2012-05-10       Impact factor: 2.616

2.  Better Efficacy of Synchrotron Spatially Microfractionated Radiation Therapy Than Uniform Radiation Therapy on Glioma.

Authors:  Audrey Bouchet; Elke Bräuer-Krisch; Yolanda Prezado; Michèle El Atifi; Léonid Rogalev; Céline Le Clec'h; Jean Albert Laissue; Laurent Pelletier; Géraldine Le Duc
Journal:  Int J Radiat Oncol Biol Phys       Date:  2016-04-06       Impact factor: 7.038

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

Authors:  Audrey Bouchet; Benjamin Lemasson; Géraldine Le Duc; Cécile Maisin; Elke Bräuer-Krisch; Erik Albert Siegbahn; Luc Renaud; Enam Khalil; Chantal Rémy; Cathy Poillot; Alberto Bravin; Jean A Laissue; Emmanuel L Barbier; Raphaël Serduc
Journal:  Int J Radiat Oncol Biol Phys       Date:  2010-12-01       Impact factor: 7.038

4.  The effects of ultra-high dose rate proton irradiation on growth delay in the treatment of human tumor xenografts in nude mice.

Authors:  O Zlobinskaya; C Siebenwirth; C Greubel; V Hable; R Hertenberger; N Humble; S Reinhardt; D Michalski; B Röper; G Multhoff; G Dollinger; J J Wilkens; T E Schmid
Journal:  Radiat Res       Date:  2014-02-13       Impact factor: 2.841

5.  Synchrotron microbeam radiation therapy for rat brain tumor palliation-influence of the microbeam width at constant valley dose.

Authors:  Raphaël Serduc; Audrey Bouchet; Elke Bräuer-Krisch; Jean A Laissue; Jenny Spiga; Sukhéna Sarun; Alberto Bravin; Caroline Fonta; Luc Renaud; Jean Boutonnat; Erik Albert Siegbahn; François Estève; Géraldine Le Duc
Journal:  Phys Med Biol       Date:  2009-10-20       Impact factor: 3.609

6.  Treating Brain Tumor with Microbeam Radiation Generated by a Compact Carbon-Nanotube-Based Irradiator: Initial Radiation Efficacy Study.

Authors:  Hong Yuan; Lei Zhang; Jonathan E Frank; Christina R Inscoe; Laurel M Burk; Mike Hadsell; Yueh Z Lee; Jianping Lu; Sha Chang; Otto Zhou
Journal:  Radiat Res       Date:  2015-08-25       Impact factor: 2.841

7.  A first generation compact microbeam radiation therapy system based on carbon nanotube X-ray technology.

Authors:  M Hadsell; J Zhang; P Laganis; F Sprenger; J Shan; L Zhang; L Burk; H Yuan; S Chang; J Lu; O Zhou
Journal:  Appl Phys Lett       Date:  2013-10-30       Impact factor: 3.791

8.  Survival analysis of F98 glioma rat cells following minibeam or broad-beam synchrotron radiation therapy.

Authors:  Silvia Gil; Sukhéna Sarun; Albert Biete; Yolanda Prezado; Manel Sabés
Journal:  Radiat Oncol       Date:  2011-04-13       Impact factor: 3.481

9.  γ-H2AX as a marker for dose deposition in the brain of wistar rats after synchrotron microbeam radiation.

Authors:  Cristian Fernandez-Palomo; Carmel Mothersill; Elke Bräuer-Krisch; Jean Laissue; Colin Seymour; Elisabeth Schültke
Journal:  PLoS One       Date:  2015-03-23       Impact factor: 3.240

10.  An optimized small animal tumour model for experimentation with low energy protons.

Authors:  Elke Beyreuther; Kerstin Brüchner; Mechthild Krause; Margret Schmidt; Rita Szabo; Jörg Pawelke
Journal:  PLoS One       Date:  2017-05-18       Impact factor: 3.240
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  1 in total

1.  The versatile X-ray beamline of the Munich Compact Light Source: design, instrumentation and applications.

Authors:  Benedikt Günther; Regine Gradl; Christoph Jud; Elena Eggl; Juanjuan Huang; Stephanie Kulpe; Klaus Achterhold; Bernhard Gleich; Martin Dierolf; Franz Pfeiffer
Journal:  J Synchrotron Radiat       Date:  2020-07-31       Impact factor: 2.616
  1 in total

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