The effects of low linear energy transfer (LET) radiation on mammalian cells have been studied at dose-rates as high as 10(9) Gy/sec delivered as a single 3-nanosecond pulse, and no increase in cytotoxicity was shown compared with delivery at a conventional dose-rate. There have been no observations on the effects of radiation delivered at even higher dose-rates on the picosecond time-scale. Here we examined, for the first time, the effects on cultured mouse L5178Y cells and its radiosensitive XRCC4-deficient mutant M10 cells of sub-picosecond X-rays emitted from laser-produced plasmas at the ultrahigh dose-rate of 10(12)-10(13) Gy/sec. No increase in the sensitivity to the X-rays was observed compared with gamma-rays at a conventional dose-rate. The increase in the sensitivity of L5178Y cells by labeling with 5-iododeoxyuridine was smaller than those irradiated with gamma-rays at a conventional dose-rate, while the difference was apparently the reverse in M10 cells. The D10 ratio between L5178Y cells and M10 cells produced by the X-rays at temporally dense ionization was the same as that produced by X(gamma)-rays at the conventional dose-rate, while the ratio is greatly reduced in the case of particle radiation. These results suggest that there is no increase in the cytotoxic effects of X-rays at dose-rates as high as 10(13) Gy/sec, and that the increased cytotoxicity of particle radiation is not attributable to temporally dense ionization. It is discussed that the mechanism for the induction of radiation damage responsible for cytotoxicity may be slightly modified at ultrahigh dose-rates.
Download full-text PDF |
Source |
|---|---|
| http://dx.doi.org/10.1269/jrr.45.509 | DOI Listing |
Publication Analysis
Top Keywords
Similar Publications
Effect of FLASH dose-rate and oxygen concentration in the production of HOin cellular-like media versus water: a Monte Carlo track-structure study.
Phys Med Biol
January 2025
Department of Oncology Radiation, University of California San Francisco, 1600 Divisadero Street, Suite HM006, San Francisco, California, 94143, UNITED STATES.
To study the effect of dose-rate in the time evolution of chemical yields produced in pure water versus a cellular-like environment for FLASH radiotherapy research. A version of TOPAS-nBio with Tau-Leaping algorithm was used to simulate the homogenous chemistry stage of water radiolysis using three chemical models: 1) liquid water model that considered scavenging of eaq-, H● by dissolved oxygen; 2) Michaels & Hunt model that considered scavenging of ●OH, eaq-, and H● by biomolecules existing in cellular environment; 3) Wardman model that considered model 2) and the chemical repair enzyme glutathione (GHS). H2O2 concentrations at conventional and FLASH dose-rates were compared with published measurements.
View Article and Find Full Text PDFMonte Carlo in the mechanistic modelling of the FLASH effect: a review.
Phys Med Biol
January 2025
Physics, The University of Western Australia, 35 Stirling Highway, Mailbag M013, WA 6009, Perth, 6009, AUSTRALIA.
FLASH radiotherapy employs ultra-high dose rates of >40 Gy/s, which may reduce normal tissue complication as compared to conventional dose rate treatments, while still ensuring the same level of tumour control. The potential benefit this can offer to patients has been the cause of great interest within the radiation oncology community, but this has not translated to a direct understanding of the FLASH effect. The oxygen depletion and inter-track interaction hypotheses are currently the leading explanations as to the mechanisms behind FLASH, but these are still not well understood, with many questions remaining about the exact underpinnings of FLASH and the treatment parameters required to optimally induce it.
View Article and Find Full Text PDFDesign and dosimetric characterization of a transportable proton minibeam collimation system.
Front Oncol
December 2024
Institute of Radiation Medicine (IRM), Helmholtz Zentrum München GmbH, German Research Center for Environmental Health, Neuherberg, Germany.
Article Synopsis
- Proton Minibeam Radiation Therapy has been promising in enhancing treatment efficacy compared to traditional radiation, but more research into its biological mechanisms is needed.
- A mechanical collimation setup was developed to produce 250µm minibeams with a 1000µm spacing, with optimization using Monte Carlo simulations conducted at various proton therapy sites.
- Results showed a peak-to-valley dose ratio (PVDR) of 10 in Dresden and 14 in Seattle, with some discrepancies between dosimetry methods that can be addressed with correction factors.
A 2D detector array for relative dosimetry and beam steering for FLASH radiotherapy with electrons.
Med Phys
December 2024
Dosimetry for Radiotherapy, Physikalisch-Technische Bundesanstalt, Braunschweig, 38116, Germany.
Background: FLASH radiotherapy is an emerging treatment modality using ultra-high dose rate beams. Much effort has been made to develop suitable dosimeters for reference dosimetry, yet the spatial beam characteristics must also be characterized to enable computerized treatment planning, as well as quality control and service of a treatment delivery device. In conventional radiation therapy, this is commonly achieved by beam profile scans in a water phantom using a point detector.
View Article and Find Full Text PDFFLASH Radiotherapy: Benefits, Mechanisms, and Obstacles to Its Clinical Application.
Int J Mol Sci
November 2024
Moscow Center for Advanced Studies, Kulakova Str. 20, Moscow 123592, Russia.
Radiotherapy (RT) has been shown to be a cornerstone of both palliative and curative tumor care. RT has generally been reported to be sharply limited by ionizing radiation (IR)-induced toxicity, thereby constraining the control effect of RT on tumor growth. FLASH-RT is the delivery of ultra-high dose rate (UHDR) several orders of magnitude higher than what is presently used in conventional RT (CONV-RT).
View Article and Find Full Text PDFWant AI Summaries of new PubMed Abstracts delivered to your In-box?
Enter search terms and have AI summaries delivered each week - change queries or unsubscribe any time!