Mechanistic, Modeling, and Dosimetric Radiation Biology

Giuseppe Schettino; Sarah Baatout; Francisco Caramelo; Fabiana Da Pieve; Cristian Fernandez-Palomo; Nina Frederike Jeppesen Edin; Aidan D. Meade; Yann Perrot; Judith Reindl; Carmen Villagrasa

doi:10.1007/978-3-031-18810-7_4

Mechanistic, Modeling, and Dosimetric Radiation Biology

Giuseppe Schettino, Sarah Baatout, Francisco Caramelo, Fabiana Da Pieve, Cristian Fernandez-Palomo, Nina Frederike Jeppesen Edin, Aidan D. Meade, Yann Perrot, Judith Reindl, Carmen Villagrasa

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

Abstract

The ultimate aim of radiobiological research is to establish a quantitative relationship between the radiation dose absorbed by biological samples (being this a cell, a tissue, an organ, or a body) and the effect caused. Therefore, radiobiological investigations need to be supported by accurate and precise dosimetric measurements. A rigorous standardized methodology has been established to assess and quantify the radiation dose absorbed by biological samples and these will be reviewed and discussed in this chapter. Dosimetric concepts at the macro-and microscopic levels are discussed with a focus on key physical quantities, their measurement technologies, and the link to the biological damage and response. This chapter will also include a description of state-of-the-art irradiation facilities (e.g., mini-and micro-beams) used for probing mechanisms underpinning radiobiological responses. Finally, the link between energy deposition events and detectable biological effects (from the molecular to the organism level) is investigated using Monte Carlo simulation codes and macroscopic radiobiological models.

Original language	English
Title of host publication	Radiobiology Textbook
Publisher	Springer International Publishing
Pages	191-236
Number of pages	46
ISBN (Electronic)	9783031188107
ISBN (Print)	9783031188091
DOIs	https://doi.org/10.1007/978-3-031-18810-7_4
Publication status	Published - 1 Jan 2023

Keywords

Dosimetry
Linear quadratic model
Microdosimetry
Mini-and micro-beams
Monte Carlo
Target theory

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978-3-031-18810-7_4Final published version, 4.75 MBLicence: CC BY

Cite this

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abstract = "The ultimate aim of radiobiological research is to establish a quantitative relationship between the radiation dose absorbed by biological samples (being this a cell, a tissue, an organ, or a body) and the effect caused. Therefore, radiobiological investigations need to be supported by accurate and precise dosimetric measurements. A rigorous standardized methodology has been established to assess and quantify the radiation dose absorbed by biological samples and these will be reviewed and discussed in this chapter. Dosimetric concepts at the macro-and microscopic levels are discussed with a focus on key physical quantities, their measurement technologies, and the link to the biological damage and response. This chapter will also include a description of state-of-the-art irradiation facilities (e.g., mini-and micro-beams) used for probing mechanisms underpinning radiobiological responses. Finally, the link between energy deposition events and detectable biological effects (from the molecular to the organism level) is investigated using Monte Carlo simulation codes and macroscopic radiobiological models.",

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author = "Giuseppe Schettino and Sarah Baatout and Francisco Caramelo and \{Da Pieve\}, Fabiana and Cristian Fernandez-Palomo and Edin, \{Nina Frederike Jeppesen\} and Meade, \{Aidan D.\} and Yann Perrot and Judith Reindl and Carmen Villagrasa",

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AU - Schettino, Giuseppe

AU - Baatout, Sarah

AU - Caramelo, Francisco

AU - Da Pieve, Fabiana

AU - Fernandez-Palomo, Cristian

AU - Edin, Nina Frederike Jeppesen

AU - Meade, Aidan D.

AU - Perrot, Yann

AU - Reindl, Judith

AU - Villagrasa, Carmen

N1 - Publisher Copyright: © The Editor(s) (if applicable) and The Author(s) 2023.

PY - 2023/1/1

Y1 - 2023/1/1

N2 - The ultimate aim of radiobiological research is to establish a quantitative relationship between the radiation dose absorbed by biological samples (being this a cell, a tissue, an organ, or a body) and the effect caused. Therefore, radiobiological investigations need to be supported by accurate and precise dosimetric measurements. A rigorous standardized methodology has been established to assess and quantify the radiation dose absorbed by biological samples and these will be reviewed and discussed in this chapter. Dosimetric concepts at the macro-and microscopic levels are discussed with a focus on key physical quantities, their measurement technologies, and the link to the biological damage and response. This chapter will also include a description of state-of-the-art irradiation facilities (e.g., mini-and micro-beams) used for probing mechanisms underpinning radiobiological responses. Finally, the link between energy deposition events and detectable biological effects (from the molecular to the organism level) is investigated using Monte Carlo simulation codes and macroscopic radiobiological models.

AB - The ultimate aim of radiobiological research is to establish a quantitative relationship between the radiation dose absorbed by biological samples (being this a cell, a tissue, an organ, or a body) and the effect caused. Therefore, radiobiological investigations need to be supported by accurate and precise dosimetric measurements. A rigorous standardized methodology has been established to assess and quantify the radiation dose absorbed by biological samples and these will be reviewed and discussed in this chapter. Dosimetric concepts at the macro-and microscopic levels are discussed with a focus on key physical quantities, their measurement technologies, and the link to the biological damage and response. This chapter will also include a description of state-of-the-art irradiation facilities (e.g., mini-and micro-beams) used for probing mechanisms underpinning radiobiological responses. Finally, the link between energy deposition events and detectable biological effects (from the molecular to the organism level) is investigated using Monte Carlo simulation codes and macroscopic radiobiological models.

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KW - Linear quadratic model

KW - Microdosimetry

KW - Mini-and micro-beams

KW - Monte Carlo

KW - Target theory

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EP - 236

BT - Radiobiology Textbook

PB - Springer International Publishing

ER -

Mechanistic, Modeling, and Dosimetric Radiation Biology

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Keywords

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