PT  - JOURNAL ARTICLE
AU  - E. Bayart
AU  - A. Flacco
AU  - O. Delmas
AU  - L. Pommarel
AU  - D. Levy
AU  - M. Cavallone
AU  - F. Megnin-Chanet
AU  - E. Deutsch
AU  - V. Malka
TI  - Fast dose fractionation using ultra-short laser accelerated proton pulses can increase cancer cell mortality, which relies on functional PARP1 protein
AID  - 10.1101/571703
DP  - 2019 Jan 01
TA  - bioRxiv
PG  - 571703
4099  - http://biorxiv.org/content/early/2019/03/08/571703.short
4100  - http://biorxiv.org/content/early/2019/03/08/571703.full
AB  - Radiotherapy is a cornerstone of cancer management. The improvement of spatial dose distribution in the tumor volume by minimizing the dose deposited in the healthy tissues have been a major concern during the last decades. Temporal aspects of dose deposition are yet to be investigated. Laser-plasma-based particle accelerators are able to emit pulsed-proton beams at extremely high peak dose rates (~109 Gy/s) during several nanoseconds. The impact of such dose rates on resistant glioblastoma cell lines, SF763 and U87-MG, was compared to conventionally accelerated protons and X-rays. No difference was observed in DNA double-strand breaks generation and cells killing. The variation of the repetition rate of the proton bunches produced an oscillation of the radio-induced cell susceptibility in HCT116 cells, which appeared to be related to the presence of the PARP1 protein and an efficient parylation process. Interestingly, when laser-driven proton bunches were applied at 0.5 Hz, survival of the radioresistant HCT116 p53−/− cells equaled that of its radiosensitive counterpart, HCT116 WT, which was also similar to cells treated with the PARP1 inhibitor Olaparib. Altogether, these results suggest that the application modality of ultrashort bunches of particles could provide a great therapeutic potential in radiotherapy.