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Position in proton Bragg curve influences DNA damage complexity and survival in head and neck cancer cells

Journal Article (2025)
Authors

Tim Heemskerk (Erasmus MC)

C.F. Groenendijk (TU Delft - RST/Medical Physics & Technology)

M. Rovituso (HollandPTC)

E van der Wal (HollandPTC)

Wouter van van Burik (HollandPTC)

Konstantinos Chatzipapas (University of Brest/INSERM/LaTIM)

D Lathouwers (TU Delft - RST/Reactor Physics and Nuclear Materials)

Roland Kanaar (Erasmus MC)

Jeremy M.C. Brown (Swinburne University of Technology)

Jeroen Essers (Erasmus MC)

Research Group
RST/Medical Physics & Technology
To reference this document use:
https://doi.org/10.1016/j.ctro.2024.100908
More Info
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Publication Year
2025
Language
English
Research Group
RST/Medical Physics & Technology
Volume number
51
DOI:
https://doi.org/10.1016/j.ctro.2024.100908
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Abstract

Background and purpose:
Understanding the cellular and molecular effect of proton radiation, particularly the increased DNA damage complexity at the distal end of the Bragg curve, is current topic of investigation. This work aims to study in vitro clonogenic survival and DNA damage foci kinetics of a head and neck squamous cell carcinoma cell line at various positions along a double passively scattered Bragg curve. Complementary in silico studies are conducted to gain insights into the link between cell survival variations, experimentally yielded foci and the number and complexity of double strand breaks (DSBs).

Materials and methods:
Proton irradiations are performed at the HollandPTC R&D proton beamline, using a double passively scattered setup. A custom water phantom setup is employed to accurately position the samples within the Bragg curve. FaDu cells are irradiated at the proximal 36 % point of the Bragg peak, (P36), proximal 80 % point of the Bragg peak (P80) and distal 20 % point of the Bragg peak (D20), with dose-averaged mean lineal energies (yD¯) of 1.10 keV/μm, 1.80 keV/μm and 7.25 keV/μm, respectively.

Results:
Clonogenic survival correlates strongly with yD¯, showing similar survival for P36 (D37%=3.0 Gy) and P80 (D37%=2.9 Gy), but decreased survival for D20 (D37% = 1.6 Gy). D20 irradiated samples exhibit increased 53BP1 foci shortly after irradiation, slower resolution of the foci, and larger residual 53BP1 foci after 24 h, indicating unrepaired complex breaks. These experimental observations are supported by the in silico study which demonstrates that irradiation at D20 leads to a 1.7-fold increase in complex DSBs with respect to the total number of strand breaks compared to P36 and P80.

Conclusions:
This combined approach provides valuable insights into the cellular and molecular effect of proton radiation, emphasizing the increased DNA damage complexity at the distal end of the Bragg curve, and has the potential to enhance the efficacy of proton therapy.