Scientific Reports (Mar 2021)

A focused very high energy electron beam for fractionated stereotactic radiotherapy

  • Kristoffer Svendsen,
  • Diego Guénot,
  • Jonas Björklund Svensson,
  • Kristoffer Petersson,
  • Anders Persson,
  • Olle Lundh

DOI
https://doi.org/10.1038/s41598-021-85451-8
Journal volume & issue
Vol. 11, no. 1
pp. 1 – 8

Abstract

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Abstract An electron beam of very high energy (50–250 MeV) can potentially produce a more favourable radiotherapy dose distribution compared to a state-of-the-art photon based radiotherapy technique. To produce an electron beam of sufficiently high energy to allow for a long penetration depth (several cm), very large accelerating structures are needed when using conventional radio-frequency technology, which may not be possible due to economical or spatial constraints. In this paper, we show transport and focusing of laser wakefield accelerated electron beams with a maximum energy of 160 MeV using electromagnetic quadrupole magnets in a point-to-point imaging configuration, yielding a spatial uncertainty of less than 0.1 mm, a total charge variation below $$1 \%$$ 1 % and a focal spot of $$2.3 \times 2.6\;{\text {mm}}^2$$ 2.3 × 2.6 mm 2 . The electron beam was focused to control the depth dose distribution and to improve the dose conformality inside a phantom of cast acrylic slabs and radiochromic film. The phantom was irradiated from 36 different angles to obtain a dose distribution mimicking a stereotactic radiotherapy treatment, with a peak fractional dose of 2.72 Gy and a total maximum dose of 65 Gy. This was achieved with realistic constraints, including 23 cm of propagation through air before any dose deposition in the phantom.