Scanning irradiation device for mice in vivo with pulsed and continuous proton beams

Christoph Greubel; Walter Assmann; Christian Burgdorf; Günther Dollinger; Guanghua Du; Volker Hable; Alexander Hapfelmeier; Ralf Hertenberger; Peter Kneschaurek; Dörte Michalski; Michael Molls; Sabine Reinhardt; Barbara Röper; Stefan Schell; Thomas E. Schmid; Christian Siebenwirth; Tatiana Wenzl; Olga Zlobinskaya; Jan J. Wilkens

doi:10.1007/s00411-011-0365-x

Scanning irradiation device for mice in vivo with pulsed and continuous proton beams

Christoph Greubel, Walter Assmann, Christian Burgdorf, Günther Dollinger, Guanghua Du, Volker Hable, Alexander Hapfelmeier, Ralf Hertenberger, Peter Kneschaurek, Dörte Michalski, Michael Molls, Sabine Reinhardt, Barbara Röper, Stefan Schell, Thomas E. Schmid, Christian Siebenwirth, Tatiana Wenzl, Olga Zlobinskaya, Jan J. Wilkens

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Abstract

A technical set-up for irradiation of subcutaneous tumours in mice with nanosecond-pulsed proton beams or continuous proton beams is described and was successfully used in a first experiment to explore future potential of laser-driven particle beams, which are pulsed due to the acceleration process, for radiation therapy. The chosen concept uses a microbeam approach. By focusing the beam to approximately 100 × 100 μm ², the necessary fluence of 10 ⁹ protons per cm ² to deliver a dose of 20 Gy with one-nanosecond shot in the Bragg peak of 23 MeV protons is achieved. Electrical and mechanical beam scanning combines rapid dose delivery with large scan ranges. Aluminium sheets one millimetre in front of the target are used as beam energy degrader, necessary for adjusting the depth-dose profile. The required procedures for treatment planning and dose verification are presented. In a first experiment, 24 tumours in mice were successfully irradiated with 23 MeV protons and a single dose of 20 Gy in pulsed or continuous mode with dose differences between both modes of 10%. So far, no significant difference in tumour growth delay was observed.

Original language	English
Pages (from-to)	339-344
Number of pages	6
Journal	Radiation and Environmental Biophysics
Volume	50
Issue number	3
DOIs	https://doi.org/10.1007/s00411-011-0365-x
State	Published - Aug 2011

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Greubel, C., Assmann, W., Burgdorf, C., Dollinger, G., Du, G., Hable, V., Hapfelmeier, A., Hertenberger, R., Kneschaurek, P., Michalski, D., Molls, M., Reinhardt, S., Röper, B., Schell, S., Schmid, T. E., Siebenwirth, C., Wenzl, T., Zlobinskaya, O., & Wilkens, J. J. (2011). Scanning irradiation device for mice in vivo with pulsed and continuous proton beams. Radiation and Environmental Biophysics, 50(3), 339-344. https://doi.org/10.1007/s00411-011-0365-x

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title = "Scanning irradiation device for mice in vivo with pulsed and continuous proton beams",

abstract = "A technical set-up for irradiation of subcutaneous tumours in mice with nanosecond-pulsed proton beams or continuous proton beams is described and was successfully used in a first experiment to explore future potential of laser-driven particle beams, which are pulsed due to the acceleration process, for radiation therapy. The chosen concept uses a microbeam approach. By focusing the beam to approximately 100 × 100 μm 2, the necessary fluence of 10 9 protons per cm 2 to deliver a dose of 20 Gy with one-nanosecond shot in the Bragg peak of 23 MeV protons is achieved. Electrical and mechanical beam scanning combines rapid dose delivery with large scan ranges. Aluminium sheets one millimetre in front of the target are used as beam energy degrader, necessary for adjusting the depth-dose profile. The required procedures for treatment planning and dose verification are presented. In a first experiment, 24 tumours in mice were successfully irradiated with 23 MeV protons and a single dose of 20 Gy in pulsed or continuous mode with dose differences between both modes of 10%. So far, no significant difference in tumour growth delay was observed.",

author = "Christoph Greubel and Walter Assmann and Christian Burgdorf and G{\"u}nther Dollinger and Guanghua Du and Volker Hable and Alexander Hapfelmeier and Ralf Hertenberger and Peter Kneschaurek and D{\"o}rte Michalski and Michael Molls and Sabine Reinhardt and Barbara R{\"o}per and Stefan Schell and Schmid, {Thomas E.} and Christian Siebenwirth and Tatiana Wenzl and Olga Zlobinskaya and Wilkens, {Jan J.}",

year = "2011",

month = aug,

doi = "10.1007/s00411-011-0365-x",

language = "English",

volume = "50",

pages = "339--344",

journal = "Radiation and Environmental Biophysics",

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Greubel, C, Assmann, W, Burgdorf, C, Dollinger, G, Du, G, Hable, V, Hapfelmeier, A, Hertenberger, R, Kneschaurek, P, Michalski, D, Molls, M, Reinhardt, S, Röper, B, Schell, S, Schmid, TE, Siebenwirth, C, Wenzl, T, Zlobinskaya, O & Wilkens, JJ 2011, 'Scanning irradiation device for mice in vivo with pulsed and continuous proton beams', Radiation and Environmental Biophysics, vol. 50, no. 3, pp. 339-344. https://doi.org/10.1007/s00411-011-0365-x

TY - JOUR

T1 - Scanning irradiation device for mice in vivo with pulsed and continuous proton beams

AU - Greubel, Christoph

AU - Assmann, Walter

AU - Burgdorf, Christian

AU - Dollinger, Günther

AU - Du, Guanghua

AU - Hable, Volker

AU - Hapfelmeier, Alexander

AU - Hertenberger, Ralf

AU - Kneschaurek, Peter

AU - Michalski, Dörte

AU - Molls, Michael

AU - Reinhardt, Sabine

AU - Röper, Barbara

AU - Schell, Stefan

AU - Schmid, Thomas E.

AU - Siebenwirth, Christian

AU - Wenzl, Tatiana

AU - Zlobinskaya, Olga

AU - Wilkens, Jan J.

PY - 2011/8

Y1 - 2011/8

N2 - A technical set-up for irradiation of subcutaneous tumours in mice with nanosecond-pulsed proton beams or continuous proton beams is described and was successfully used in a first experiment to explore future potential of laser-driven particle beams, which are pulsed due to the acceleration process, for radiation therapy. The chosen concept uses a microbeam approach. By focusing the beam to approximately 100 × 100 μm 2, the necessary fluence of 10 9 protons per cm 2 to deliver a dose of 20 Gy with one-nanosecond shot in the Bragg peak of 23 MeV protons is achieved. Electrical and mechanical beam scanning combines rapid dose delivery with large scan ranges. Aluminium sheets one millimetre in front of the target are used as beam energy degrader, necessary for adjusting the depth-dose profile. The required procedures for treatment planning and dose verification are presented. In a first experiment, 24 tumours in mice were successfully irradiated with 23 MeV protons and a single dose of 20 Gy in pulsed or continuous mode with dose differences between both modes of 10%. So far, no significant difference in tumour growth delay was observed.

AB - A technical set-up for irradiation of subcutaneous tumours in mice with nanosecond-pulsed proton beams or continuous proton beams is described and was successfully used in a first experiment to explore future potential of laser-driven particle beams, which are pulsed due to the acceleration process, for radiation therapy. The chosen concept uses a microbeam approach. By focusing the beam to approximately 100 × 100 μm 2, the necessary fluence of 10 9 protons per cm 2 to deliver a dose of 20 Gy with one-nanosecond shot in the Bragg peak of 23 MeV protons is achieved. Electrical and mechanical beam scanning combines rapid dose delivery with large scan ranges. Aluminium sheets one millimetre in front of the target are used as beam energy degrader, necessary for adjusting the depth-dose profile. The required procedures for treatment planning and dose verification are presented. In a first experiment, 24 tumours in mice were successfully irradiated with 23 MeV protons and a single dose of 20 Gy in pulsed or continuous mode with dose differences between both modes of 10%. So far, no significant difference in tumour growth delay was observed.

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AN - SCOPUS:79961209795

SN - 0301-634X

VL - 50

SP - 339

EP - 344

JO - Radiation and Environmental Biophysics

JF - Radiation and Environmental Biophysics

IS - 3

ER -

Scanning irradiation device for mice in vivo with pulsed and continuous proton beams

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