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Infrared microspectroscopy to elucidate the underlying biomolecular mechanisms of FLASH radiotherapy.

Authors :
Martínez-Rovira, Immaculada
Montay-Gruel, Pierre
Petit, Benoît
Leavitt, Ron J.
González-Vegas, Roberto
Froidevaux, Pascal
Juchaux, Marjorie
Prezado, Yolanda
Yousef, Ibraheem
Vozenin, Marie-Catherine
Source :
Radiotherapy & Oncology. Jul2024, Vol. 196, pN.PAG-N.PAG. 1p.
Publication Year :
2024

Abstract

FLASH-radiotherapy (FLASH-RT) is an emerging modality that uses ultra-high dose rates of radiation to enable curative doses to the tumor while preserving normal tissue. The biological studies showed the potential of FLASH-RT to revolutionize radiotherapy cancer treatments. However, the complex biological basis of FLASH-RT is not fully known yet. Within this context, our aim is to get deeper insights into the biomolecular mechanisms underlying FLASH-RT through Fourier Transform Infrared Microspectroscopy (FTIRM). C57Bl/6J female mice were whole brain irradiated at 10 Gy with the eRT6-Oriatron system. 10 Gy FLASH-RT was delivered in 1 pulse of 1. 8 μ s and conventional irradiations at 0.1 Gy/s. Brains were sampled and prepared for analysis 24 h post-RT. FTIRM was performed at the MIRAS beamline of ALBA Synchrotron. Infrared raster scanning maps of the whole mice brain sections were collected for each sample condition. Hyperspectral imaging and Principal Component Analysis (PCA) were performed in several regions of the brain. PCA results evidenced a clear separation between conventional and FLASH irradiations in the 1800–950 cm−1 region, with a significant overlap between FLASH and Control groups. An analysis of the loading plots revealed that most of the variance accounting for the separation between groups was associated to modifications in the protein backbone (Amide I). This protein degradation and/or conformational rearrangement was concomitant with nucleic acid fragmentation/condensation. Cluster separation between FLASH and conventional groups was also present in the 3000–2800 cm−1 region, being correlated with changes in the methylene and methyl group concentrations and in the lipid chain length. Specific vibrational features were detected as a function of the brain region. This work provided new insights into the biomolecular effects involved in FLASH-RT through FTIRM. Our results showed that beyond nucleic acid investigations, one should take into account other dose-rate responsive molecules such as proteins, as they might be key to understand FLASH effect. • This study explores the capabilities of FTIRM to investigate FLASH-RT • FTIRM allowed to rebuild the action of FLASH-RT on normal brain at 24 h • FLASH-RT induces differences in protein signature compared to conventional dose-rates • FLASH-RT induces reduced nucleic acid damage compared to conventional irradiations • Dose-rate responsive molecules such as proteins might be key to understand FLASH-RT [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
01678140
Volume :
196
Database :
Academic Search Index
Journal :
Radiotherapy & Oncology
Publication Type :
Academic Journal
Accession number :
177758849
Full Text :
https://doi.org/10.1016/j.radonc.2024.110238