Comparison of measured with calculated dose distribution from a 120-MeV electron beam from a laser-plasma accelerator

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Comparison of measured with calculated dose distribution from a 120-MeV electron beam from a laser-plasma accelerator. / Lundh, Olle; Rechatin, C.; Faure, J.; Ben-Ismail, A.; Lim, J.; De Wagter, C.; De Neve, W.; Malka, V.

In: Medical Physics, Vol. 39, No. 6, 2012, p. 3501-3508.

Research output: Contribution to journalArticle

Harvard

Lundh, O, Rechatin, C, Faure, J, Ben-Ismail, A, Lim, J, De Wagter, C, De Neve, W & Malka, V 2012, 'Comparison of measured with calculated dose distribution from a 120-MeV electron beam from a laser-plasma accelerator', Medical Physics, vol. 39, no. 6, pp. 3501-3508. https://doi.org/10.1118/1.4719962

APA

Lundh, O., Rechatin, C., Faure, J., Ben-Ismail, A., Lim, J., De Wagter, C., De Neve, W., & Malka, V. (2012). Comparison of measured with calculated dose distribution from a 120-MeV electron beam from a laser-plasma accelerator. Medical Physics, 39(6), 3501-3508. https://doi.org/10.1118/1.4719962

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Lundh, Olle ; Rechatin, C. ; Faure, J. ; Ben-Ismail, A. ; Lim, J. ; De Wagter, C. ; De Neve, W. ; Malka, V. / Comparison of measured with calculated dose distribution from a 120-MeV electron beam from a laser-plasma accelerator. In: Medical Physics. 2012 ; Vol. 39, No. 6. pp. 3501-3508.

RIS

TY - JOUR

T1 - Comparison of measured with calculated dose distribution from a 120-MeV electron beam from a laser-plasma accelerator

AU - Lundh, Olle

AU - Rechatin, C.

AU - Faure, J.

AU - Ben-Ismail, A.

AU - Lim, J.

AU - De Wagter, C.

AU - De Neve, W.

AU - Malka, V.

PY - 2012

Y1 - 2012

N2 - Purpose: To evaluate the dose distribution of a 120-MeV laser-plasma accelerated electron beam which may be of potential interest for high-energy electron radiation therapy. Methods: In the interaction between an intense laser pulse and a helium gas jet, a well collimated electron beam with very high energy is produced. A secondary laser beam is used to optically control and to tune the electron beam energy and charge. The potential use of this beam for radiation treatment is evaluated experimentally by measurements of dose deposition in a polystyrene phantom. The results are compared to Monte Carlo simulations using the GEANT4 code. Results: It has been shown that the laser-plasma accelerated electron beam can deliver a peak dose of more than 1 Gy at the entrance of the phantom in a single laser shot by direct irradiation, without the use of intermediate magnetic transport or focusing. The dose distribution is peaked on axis, with narrow lateral penumbra. Monte Carlo simulations of electron beam propagation and dose deposition indicate that the propagation of the intense electron beam (with large self-fields) can be described by standard models that exclude collective effects in the response of the material. Conclusions: The measurements show that the high-energy electron beams produced by an optically injected laser-plasma accelerator can deliver high enough dose at penetration depths of interest for electron beam radiotherapy of deep-seated tumors. Many engineering issues must be resolved before laser-accelerated electrons can be used for cancer therapy, but they also represent exciting challenges for future research. (C) 2012 American Association of Physicists in Medicine. [http://dx.doi.org/10.1118/1.47199621

AB - Purpose: To evaluate the dose distribution of a 120-MeV laser-plasma accelerated electron beam which may be of potential interest for high-energy electron radiation therapy. Methods: In the interaction between an intense laser pulse and a helium gas jet, a well collimated electron beam with very high energy is produced. A secondary laser beam is used to optically control and to tune the electron beam energy and charge. The potential use of this beam for radiation treatment is evaluated experimentally by measurements of dose deposition in a polystyrene phantom. The results are compared to Monte Carlo simulations using the GEANT4 code. Results: It has been shown that the laser-plasma accelerated electron beam can deliver a peak dose of more than 1 Gy at the entrance of the phantom in a single laser shot by direct irradiation, without the use of intermediate magnetic transport or focusing. The dose distribution is peaked on axis, with narrow lateral penumbra. Monte Carlo simulations of electron beam propagation and dose deposition indicate that the propagation of the intense electron beam (with large self-fields) can be described by standard models that exclude collective effects in the response of the material. Conclusions: The measurements show that the high-energy electron beams produced by an optically injected laser-plasma accelerator can deliver high enough dose at penetration depths of interest for electron beam radiotherapy of deep-seated tumors. Many engineering issues must be resolved before laser-accelerated electrons can be used for cancer therapy, but they also represent exciting challenges for future research. (C) 2012 American Association of Physicists in Medicine. [http://dx.doi.org/10.1118/1.47199621

KW - laser-plasma accelerator

KW - high energy electron radiotherapy

U2 - 10.1118/1.4719962

DO - 10.1118/1.4719962

M3 - Article

C2 - 22755730

VL - 39

SP - 3501

EP - 3508

JO - Medical Physics

JF - Medical Physics

SN - 0094-2405

IS - 6

ER -