Scientific Reports (Jan 2022)

A new platform for ultra-high dose rate radiobiological research using the BELLA PW laser proton beamline

  • Jianhui Bin,
  • Lieselotte Obst-Huebl,
  • Jian-Hua Mao,
  • Kei Nakamura,
  • Laura D. Geulig,
  • Hang Chang,
  • Qing Ji,
  • Li He,
  • Jared De Chant,
  • Zachary Kober,
  • Anthony J. Gonsalves,
  • Stepan Bulanov,
  • Susan E. Celniker,
  • Carl B. Schroeder,
  • Cameron G. R. Geddes,
  • Eric Esarey,
  • Blake A. Simmons,
  • Thomas Schenkel,
  • Eleanor A. Blakely,
  • Sven Steinke,
  • Antoine M. Snijders

DOI
https://doi.org/10.1038/s41598-022-05181-3
Journal volume & issue
Vol. 12, no. 1
pp. 1 – 15

Abstract

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Abstract Radiotherapy is the current standard of care for more than 50% of all cancer patients. Improvements in radiotherapy (RT) technology have increased tumor targeting and normal tissue sparing. Radiations at ultra-high dose rates required for FLASH-RT effects have sparked interest in potentially providing additional differential therapeutic benefits. We present a new experimental platform that is the first one to deliver petawatt laser-driven proton pulses of 2 MeV energy at 0.2 Hz repetition rate by means of a compact, tunable active plasma lens beamline to biological samples. Cell monolayers grown over a 10 mm diameter field were exposed to clinically relevant proton doses ranging from 7 to 35 Gy at ultra-high instantaneous dose rates of 107 Gy/s. Dose-dependent cell survival measurements of human normal and tumor cells exposed to LD protons showed significantly higher cell survival of normal-cells compared to tumor-cells for total doses of 7 Gy and higher, which was not observed to the same extent for X-ray reference irradiations at clinical dose rates. These findings provide preliminary evidence that compact LD proton sources enable a new and promising platform for investigating the physical, chemical and biological mechanisms underlying the FLASH effect.