Summary
Lung dose calculations for inhaled radon decay products presented in part I have revealed that mean basal cell doses are significantly dependent on various personal and environmental factors. Whereas these macroscopic dosimetric methods have been applied with great success to radiation protection problems, the interpretation of radiobiological effects, such as lung cancer incidence, needs some refinement of these methods. Energy deposition at the microscopic level as the physical input quantity and radiation carcinogenesis as the biological endpoint are by nature stochastic processes. Therefore, a microdosimetric model was developed taking into consideration the randomness of physical and biological parameters involved. Part II of the paper presents results on specific energy distributions in lung cells, demonstrating that single event density distributions together with the number of cells receiving single hits represent more appropriate parameters than mean radiation doses.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Hofmann W, Daschil F, Pohl E (1979a) Animal lung models for the inhalation of natural radioactive particles and their relevance to man. Proc. 7th Conf. Ges f Aerosolf, pp 26–30
Hofmann W, Steinhäusler F (1979b) Die Mikrodosimetrie der Alphastrahlung des Radon und seiner Zerfallsprodukte zur Erklärung biologischer Strahlenreaktionen auf zellularer Ebene. Z Angew Bäder Klimaheilkd 26: 399–409
Hofmann W, Steinhäusler F, Pohl E, Bernroider G (1980a) Microdosimetric approach for lung dose assessments. Proc 5th Int Congr IRPA, pp 177–180
Hofmann W (1980b) Microdosimetry of inhaled alpha-emitters in the human lung. Proc 7th Symp on Microdosimetry, pp 129–138
Hofmann W (1981; in press) Experimental investigation of the microdistribution of inhaled radon decay products in various tissues by autoradiography with CR-39. Proc 11th Int Conf on Solid State Nuclear Track Detectors
International Commission on Radiological Protection (ICRP), Committee 2 (1979) Limits for intakes of radionuclides by workers. ICRP Publication 30, Part 1. Ann ICRP 2, No. 3/4
Matheron G (1967) Eléments pour une Théorie des Milieux Poreux. Masson, Paris
Neyman J (1939) On a new class of contagious distributions, applicable in entomology and bacteriology. Ann Math Stat 10: 35–57
Simmons JA, Richards SR (1980) Microdosimetry of lung. Porc 7th Symp on Microdosimetry, pp 1433–1439
Walsh PG (1970) Stopping power and range of alpha particles. Health Phys 19: 312–316
Wilson WE (1977) A method for calculating single-event distributions for point source alpha emitters. BNWL-1254
Wilson WE, Paretzke HG (1980) Spatial dependence of frequency distributions in ionization and energy imparted in nanometer volumes by 0.25 to 3 MeV protons. Proc 7th Symp on Microdosimetry, pp 423–434
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Hofmann, W. Cellular lung dosimetry for inhaled radon decay products as a base for radiation-induced lung cancer risk assessment. Radiat Environ Biophys 20, 113–122 (1982). https://doi.org/10.1007/BF01323932
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF01323932