EPR Dosimetry in Human Fingernails: Investigation of the Origin of the Endogenous Signal and Implications for Estimating Dose from Nail Signals

Human nails have been studied for many years for potential use for dosimetry, based on the EPR signals induced by ionizing radiation, but a fully validated protocol to measure doses retrospectively has not yet been developed. The major problem is that the EPR spectrum of irradiated nails is complex...

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Bibliographic Details
Published in:Applied magnetic resonance 2022, Vol.53 (1), p.319-334
Main Authors: Tkatchenko, Nicolas, Romanyukha, Alexander, Reyes, Ricardo, Swarts, Steven G., Gourier, Didier, Trompier, François
Format: Article
Language:English
Subjects:
Atoms and Molecules in Strong Fields
Chemical properties
Chemical treatment
Dental enamel
Dosimeters
Dosimetry
Harold M. Swartz: On the Occasion of His 85th Birthday
Hypotheses
Ionizing radiation
Laser Matter Interaction
Measurement methods
Organic Chemistry
Original Paper
Oxidation
Physical Chemistry
Physics
Physics and Astronomy
Protocol
Radiation
Radiation effects
Radicals
Solid State Physics
Spectra
Spectroscopy/Spectrometry
Spectrum analysis
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Summary:Human nails have been studied for many years for potential use for dosimetry, based on the EPR signals induced by ionizing radiation, but a fully validated protocol to measure doses retrospectively has not yet been developed. The major problem is that the EPR spectrum of irradiated nails is complex and its radiation-induced signals ( RIS ) overlap with an endogenous signal called the background signal ( BKS ). RIS and BKS have similar spectral parameters. Therefore, detailed characterization of the BKS is required to develop a method for measuring the amount of RIS by removing the signal due to BKS from the total spectrum of irradiated nails. Effects of reducing and oxidizing treatments of fingernail samples on the BKS were studied. Numerical simulations of the observed BKSs were performed. Common features of the EPR spectra in fingernails are discussed. We also found that BK S can be generated in the fingernail clippings by oxidation in ambient air with dioxygen. Results support the hypothesis that BK S is an o-semiquinone radical anion. Comparison of the chemical and spectral properties of the BK S and with the RIS 5 (the stable signal suitable for dose assessment) suggests that both sets of radicals underlying these signals are o-semiquinone radicals. Given the common chemical properties of the BKS and RIS 5 , it is unlikely that chemical treatment methods will provide a way to differentiate these two signals in irradiated nail spectra. Instead, other methods (i.e., dose-additive methods, population-derived BKS means) may be necessary to selectively estimate the content of BKS and RIS 5 in irradiated nail spectra.
ISSN:0937-9347
1613-7507
DOI:10.1007/s00723-021-01458-4