Radon as a Tracer of Lung Changes Induced by Smoking

After smoking, exposure to radon and its progeny is the second leading cause of lung cancer. The probability of inducing lung carcinomas by inhaled radon progeny depends on the deposited radiation dose, and is significantly affected by physiological and morphometric changes induced by smoking. Due t...

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Veröffentlicht in:	Risk analysis 2020-02, Vol.40 (2), p.370-384
Hauptverfasser:	Böhm, Radoslav, Sedlák, Antonín, Bulko, Martin, Holý, Karol
Format:	Artikel
Sprache:	eng
Schlagworte:	Biological effects Cigarette smoke Concurrent processes Epithelium Health risk assessment Induced Inhalation Irritation Lung cancer Lung carcinoma Lungs microdosimetric model Mucus Nonsmokers Obstruction Offspring Progeny Radiation Radiation damage Radiation dosage Radon Respiration Smoking Tobacco smoke
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creator	Böhm, Radoslav Sedlák, Antonín Bulko, Martin Holý, Karol
description	After smoking, exposure to radon and its progeny is the second leading cause of lung cancer. The probability of inducing lung carcinomas by inhaled radon progeny depends on the deposited radiation dose, and is significantly affected by physiological and morphometric changes induced by smoking. Due to irritation of the airways, the inhalation of cigarette smoke leads to the hyperproduction of mucus. Two concurrent processes occur: on one hand, increased production of mucus protects the target cells against radiation damage; on the other hand, in the case of long‐term smokers, a chronic lung obstruction develops, causing an increase in the radiation dose to the lungs. Depending on the duration and intensity of smoking, these processes contribute to the final radiation dose with different weights. The primary objective of this study was to investigate to what extent these smoke‐induced changes can modify the resulting absorbed dose of inhaled radon progeny relative to healthy nonsmokers. Since the bronchial dose depends on the degree of lung tissue damage, we have used this dose as a tool for detecting the effects of smoking on the lung epithelium. In other words, the biological effect of radon served as a tracer of changes induced by smoking.
doi_str_mv	10.1111/risa.13385
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The probability of inducing lung carcinomas by inhaled radon progeny depends on the deposited radiation dose, and is significantly affected by physiological and morphometric changes induced by smoking. Due to irritation of the airways, the inhalation of cigarette smoke leads to the hyperproduction of mucus. Two concurrent processes occur: on one hand, increased production of mucus protects the target cells against radiation damage; on the other hand, in the case of long‐term smokers, a chronic lung obstruction develops, causing an increase in the radiation dose to the lungs. Depending on the duration and intensity of smoking, these processes contribute to the final radiation dose with different weights. The primary objective of this study was to investigate to what extent these smoke‐induced changes can modify the resulting absorbed dose of inhaled radon progeny relative to healthy nonsmokers. Since the bronchial dose depends on the degree of lung tissue damage, we have used this dose as a tool for detecting the effects of smoking on the lung epithelium. 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The probability of inducing lung carcinomas by inhaled radon progeny depends on the deposited radiation dose, and is significantly affected by physiological and morphometric changes induced by smoking. Due to irritation of the airways, the inhalation of cigarette smoke leads to the hyperproduction of mucus. Two concurrent processes occur: on one hand, increased production of mucus protects the target cells against radiation damage; on the other hand, in the case of long‐term smokers, a chronic lung obstruction develops, causing an increase in the radiation dose to the lungs. Depending on the duration and intensity of smoking, these processes contribute to the final radiation dose with different weights. The primary objective of this study was to investigate to what extent these smoke‐induced changes can modify the resulting absorbed dose of inhaled radon progeny relative to healthy nonsmokers. 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source	Wiley Online Library Journals Frontfile Complete; Business Source Complete
subjects	Biological effects Cigarette smoke Concurrent processes Epithelium Health risk assessment Induced Inhalation Irritation Lung cancer Lung carcinoma Lungs microdosimetric model Mucus Nonsmokers Obstruction Offspring Progeny Radiation Radiation damage Radiation dosage Radon Respiration Smoking Tobacco smoke
title	Radon as a Tracer of Lung Changes Induced by Smoking
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