PLoS ONE (Jan 2017)

Increased cell survival and cytogenetic integrity by spatial dose redistribution at a compact synchrotron X-ray source.

  • Karin Burger,
  • Katarina Ilicic,
  • Martin Dierolf,
  • Benedikt Günther,
  • Dietrich W M Walsh,
  • Ernst Schmid,
  • Elena Eggl,
  • Klaus Achterhold,
  • Bernhard Gleich,
  • Stephanie E Combs,
  • Michael Molls,
  • Thomas E Schmid,
  • Franz Pfeiffer,
  • Jan J Wilkens

DOI
https://doi.org/10.1371/journal.pone.0186005
Journal volume & issue
Vol. 12, no. 10
p. e0186005

Abstract

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X-ray microbeam radiotherapy can potentially widen the therapeutic window due to a geometrical redistribution of the dose. However, high requirements on photon flux, beam collimation, and system stability restrict its application mainly to large-scale, cost-intensive synchrotron facilities. With a unique laser-based Compact Light Source using inverse Compton scattering, we investigated the translation of this promising radiotherapy technique to a machine of future clinical relevance. We performed in vitro colony-forming assays and chromosome aberration tests in normal tissue cells after microbeam irradiation compared to homogeneous irradiation at the same mean dose using 25 keV X-rays. The microplanar pattern was achieved with a tungsten slit array of 50 μm slit size and a spacing of 350 μm. Applying microbeams significantly increased cell survival for a mean dose above 2 Gy, which indicates fewer normal tissue complications. The observation of significantly less chromosome aberrations suggests a lower risk of second cancer development. Our findings provide valuable insight into the mechanisms of microbeam radiotherapy and prove its applicability at a compact synchrotron, which contributes to its future clinical translation.