Nanodosimetry – on the ''tracks'' of biological radiation effectiveness

Rabus, Hans

doi:10.1016/j.zemedi.2020.01.002

Cited by 10 publications

(13 citation statements)

References 41 publications

(69 reference statements)

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“…A common fundamental cause of biological effects is the productions of double-strand breaks which correlate with the probability to produce ionizations within a volume of 10 base pairs of DNA. [1][2][3][4] The nanodosimetric quantity, which is measured in a DNA-sized volume, is the number of ionizations ν produced by single traversing charged particles of specified radiation quality, which is described by a probability distribution PðνÞ.…”

Section: Introductionmentioning

confidence: 99%

“…The aim of nanodosimetry is to provide physical measurements of a quantity which describes biological effects of ionizing radiation better than conventional absorbed dose measurements. A common fundamental cause of biological effects is the productions of double‐strand breaks which correlate with the probability to produce ionizations within a volume of 10 base pairs of DNA 1–4 . The nanodosimetric quantity, which is measured in a DNA‐sized volume, is the number of ionizations

ν

produced by single traversing charged particles of specified radiation quality, which is described by a probability distribution

P (ν)

.…”

Section: Introductionmentioning

confidence: 99%

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First measurements of ionization cluster‐size distributions with a compact nanodosimeter

Vasi

Schneider

2021

Medical Physics

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A nanodosimeter is a type of detector which measures single ionizations in a small gaseous volume in order to obtain ionization cluster size probability distributions for characterization of radiation types. Working nanodosimeter detectors are usually bulky machines which require a lot of space. In this work, the authors present a compact ceramic nanodosimeter detector and report on first measurements of cluster size distributions of 5 MeV alpha particles. Methods: Single ionization measurements are achieved by applying a weak electric field to collect positive ions in a hole in a ceramic plate. Inside the ceramic plate, due to a strong electric field, the ions are accelerated and produce impact-ionizations. The resulting electron avalanche is detected in a read-out electrode. A Bayesian unfolding algorithm is then applied to the experimentally obtained cluster size distributions to reconstruct the true cluster size distributions. Results: Experimentally obtained cluster size distributions by the compact nanodosimeter detector are presented. The reconstructed cluster size distributions agreed well with Monte Carlo simulated cluster size distributions for small volumes (diameter = 2.5 nm). For larger volumes, discrepancies between the reconstructed cluster size distributions and cluster size distributions from Monte Carlo simulations were observed. Conclusions: For the first time, ionization cluster size probability distributions could be obtained by a small and compact nanodosimeter detector. This signifies the achievement of a critical step toward the wide application of nanodosimetric characterization of radiation types including in clinical environments.

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Section: Introductionmentioning

confidence: 99%

ν

produced by single traversing charged particles of specified radiation quality, which is described by a probability distribution

P (ν)

.…”

Section: Introductionmentioning

confidence: 99%

First measurements of ionization cluster‐size distributions with a compact nanodosimeter

Vasi

Schneider

2021

Medical Physics

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“…Develop multi-scale characterisation of track structure using nanodosemeters with multiscale measurement capabilities and track structure simulation codes ( 19 , 37 , 38 ) .…”

Section: Vision 1: Towards Updated Fundamental Dose Concepts and Quantitiesmentioning

confidence: 99%

Eurados Strategic Research Agenda 2020: Vision for the Dosimetry of Ionising Radiation

Harrison

Ainsbury

Alves

et al. 2021

Radiation Protection Dosimetry

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Since 2012, the European Radiation Dosimetry Group (EURADOS) has developed its Strategic Research Agenda (SRA), which contributes to the identification of future research needs in radiation dosimetry in Europe. Continued scientific developments in this field necessitate regular updates and, consequently, this paper summarises the latest revision of the SRA, with input regarding the state of the art and vision for the future contributed by EURADOS Working Groups and through a stakeholder workshop. Five visions define key issues in dosimetry research that are considered important over at least the next decade. They include scientific objectives and developments in (i) updated fundamental dose concepts and quantities, (ii) improved radiation risk estimates deduced from epidemiological cohorts, (iii) efficient dose assessment for radiological emergencies, (iv) integrated personalised dosimetry in medical applications and (v) improved radiation protection of workers and the public. This SRA will be used as a guideline for future activities of EURADOS Working Groups but can also be used as guidance for research in radiation dosimetry by the wider community. It will also be used as input for a general European research roadmap for radiation protection, following similar previous contributions to the European Joint Programme for the Integration of Radiation Protection Research, under the Horizon 2020 programme (CONCERT). The full version of the SRA is available as a EURADOS report (www.eurados.org).

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“…The derivation of eq. ( 9) did not require presuming the (multi-event) distributions of lethal events and sublethal events to be statistically independent and to be Poisson distributed as was done in previous work ( Besserer and Schneider 2015a, 2015b, Schneider et al 2016, 2020. Both properties follow from the assumption of the Poisson distribution of the number of primary tracks interacting with the cell.…”

Section: Sonwabile Ngcezu and Hans Rabusmentioning

confidence: 99%

“…If the ROI is the CV of Schneider et al ( 2020), W1(0) is the number of BIVs per CV. (Whereas Schneider et al ( 2019, 2020 used the ratio of mean chord length through the CV and BIV diameter for the number of BIV per CV that potentially receive an ionization cluster. )…”

Section: Probability Of Ic Formation In a Biv By Passing Tracksmentioning

confidence: 99%

Investigation into the foundations of the track-event theory of cell survival and the radiation action model based on nanodosimetry

Ngcezu

Rabus

2021

Radiat Environ Biophys

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This work aims at elaborating the basic assumptions behind the “track-event theory” (TET) and its derivate “radiation action model based on nanodosimetry” (RAMN) by clearly distinguishing between effects of tracks at the cellular level and the induction of lesions in subcellular targets. It is demonstrated that the model assumptions of Poisson distribution and statistical independence of the frequency of single and clustered DNA lesions are dispensable for multi-event distributions because they follow from the Poisson distribution of the number of tracks affecting the considered target volume. It is also shown that making these assumptions for the single-event distributions of the number of lethal and sublethal lesions within a cell would lead to an essentially exponential dose dependence of survival for practically relevant values of the absorbed dose. Furthermore, it is elucidated that the model equation used for consideration of repair within the TET is based on the assumption that DNA lesions induced by different tracks are repaired independently. Consequently, the model equation is presumably inconsistent with the model assumptions and requires an additional model parameter. Furthermore, the methodology for deriving model parameters from nanodosimetric properties of particle track structure is critically assessed. Based on data from proton track simulations it is shown that the assumption of statistically independent targets leads to the prediction of negligible frequency of clustered DNA damage. An approach is outlined how track structure could be considered in determining the model parameters, and the implications for TET and RAMN are discussed.

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Nanodosimetry – on the ''tracks'' of biological radiation effectiveness

Cited by 10 publications

References 41 publications

First measurements of ionization cluster‐size distributions with a compact nanodosimeter

First measurements of ionization cluster‐size distributions with a compact nanodosimeter

Eurados Strategic Research Agenda 2020: Vision for the Dosimetry of Ionising Radiation

Investigation into the foundations of the track-event theory of cell survival and the radiation action model based on nanodosimetry

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