The Role of Radiation Induced Injury on Lung Cancer (original) (raw)
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Lung Fibrosis and Lung Cancer Incidence in Beagle Dogs that Inhaled 238PuO2 or 239PuO2
Health Physics, 2009
Determination of radiation protection guidelines for persons working with plutonium has been complicated by limited human data on the biological behavior and subsequent health effects from internally deposited plutonium. One solution has been the use of animal models to predict likely health effects in humans. To compare the relationships between plutonium inhalation and lung fibrosis and lung cancer, data from life-span studies of beagle dogs given a single exposure to either plutonium-238 dioxide ( 238 PuO 2 ) or plutonium-239 dioxide ( 239 PuO 2 ) were analyzed. Estimates of the cumulative hazard of lung fibrosis and lung cancer after exposure to either were generated. The hazard of lung fibrosis was not consistent with a linear no-threshold model, although the magnitude of the threshold differed by radionuclide. In dogs given 239 PuO 2 , the best model of lung fibrosis incorporated a linear doseresponse function; a linear-quadratic dose-response function fit the data better in dogs given 238 PuO 2 . At any given cumulative dose, the lung fibrosis hazard was greater for dogs given 238 PuO 2 . In dogs given 238 PuO 2 , with or without covariates, a quadratic dose-response function for lung cancer hazard fit better than a linear no-threshold model. In dogs given 239 PuO 2 , models of lung cancer with the dose-response function as the sole predictor variable were consistent with a linear no-threshold model; however, a quadratic dose-response function with a cell-killing term fit better. These findings have implications for radiation protection because, while lung cancer hazard was dependent on cumulative dose, regardless of isotope, the lung fibrosis hazard depended on both cumulative dose and isotope. Health Phys. 96(4):493-503; 2009
International Journal of Radiation Oncology*Biology*Physics, 2000
Purpose: Recent observations have shown that there are regional variations in radiation response in mouse lung as measured by functional assays. Furthermore, there are both in-field and out-of-field effects in radiationinduced lung damage as observed by DNA assay in rats. The purpose of this work is: (a) to examine mice lethality data following partial volume lung irradiation to assess the possibility of directional or regional effects, (b) to evaluate the correlation between mice lethality data and DNA damage assayed by micronuclei production in rat lung, and (c) to re-interpret mice lethality considering the existence of directional effects in lung cellular response to partial volume irradiation. Methods and Materials: The lethality data for mice, generated at the M. D. Anderson Cancer Center, Houston, and micronuclei yield data for rats obtained at Princess Margaret Hospital, Toronto, were used. A radiobiological model that allows for out-of-field and in-field effects for lung cell damage and lung response was developed. This model is based on the observation of DNA damage in shielded parts of rat lung that was assumed relevant to cell lethality and consequently overall lung response. Results: While the experimental data indicated directional or regional volume effects, the applicability of dose and volume as sole predictors of lung response to radiation was found to be unreliable for lower lung (base) irradiation in mice. This conforms well to rat lung response where micronuclei were observed in shielded apical parts of lung following base irradiation. The radiobiological model, which was specifically developed to account for the lung response outside of primary irradiated volume, provides a good fit to mice lethality data, using parameters inferred from rat micronuclei data. Conclusion: Response to lung irradiation in rodents, in particular, elevated sensitivity to base irradiation, can be interpreted with a hypothesis of in-field and out-of-field effects for cellular response. If the existence of these effects for lung is subsequently proven in humans, it will require the incorporation of geometrical and directional information in normal tissue complication probability calculations for lung. These considerations are ignored in present approaches based only on conventional dose-volume histograms. © 2000 Elsevier Science Inc.
Cancer research, 1982
The role of cellular proliferation in a two-stage model of carcinogenesis in the hamster lung was investigated. Syrian golden hamsters were treated intratracheally with either one instillation of 0.2 microCi of 210Po (Po-0 group), seven weekly instillations of BP (0-BP group), or 0.2 microCi 210Po followed 15 weeks later by either seven instillations of 0.9% NaCl solution (Po-Sal group) or seven instillations of BP (Po-BP group). All BP instillations were 3 mg each of BP:ferric oxide (1:1, w/w) carrier particles). Serial sacrifices were performed for up to 85 weeks. Two hr before sacrifice, each animal was given i.p. injections of 200 microCi of [3H]thymidine. Glycol methacrylate section autoradiographs (1 micrometer) were prepared. Labeling indices in the alveolar region, labeling of terminal bronchiolar cells, and morphological changes were examined. Equal numbers of Po-Sal and Po-BP animals developed lung tumors. No tumors were found in Po-0 or 0-BP animals. Tumor development was...
Bronchoalveolar Lavage Findings of Radiation Induced Lung Damage in Rats
Journal of Radiation Research, 2009
Radiation induced lung damage is a main dose limiting factor when irradiating the thorax. Although Bronchoalveolar lavage (BAL) is a valuable tool for studying the mechanisms in pulmonary disorders, there are only a few studies about the BAL findings of radiation-induced lung damage. We evaluate the BAL findings for the evaluation of radiation-induced lung damage. Sprague-Dawley rats received 20 Gy of radiation to the right lung and control group were sham irradiated. BAL was performed for the right and left lungs separately 3, 7, 14, 28, and 56 days after radiation. The cells in the BAL fluid were counted and the concentrations of protein, NO, and TGF-β in the BAL fluid were measured. Lung tissues were removed after BAL and stained with hematoxylin-eosin (H-E) and trichrome. From 2 weeks, histological findings showed definite lung damage. The protein level and TGF-β in BAL fluid from the irradiated lung peaked at 4 and 8 weeks, respectively, after radiation. Total cell count in BAL fluid from both sides of lungs was increased from 2 weeks and continued to increase at 8 weeks after irradiation. NO in BAL fluid from both sides of lungs peaked at 4 weeks after irradiation. The protein level and TGF-β were increased in BAL fluid from irradiated lungs. However, alveolar cells and NO increased in BAL fluid from both irradiated and non-irradiated lungs. BAL is a valuable tool for the evaluation of radiation induced lung damage.
Genotoxic and Inflammatory Effects of Depleted Uranium Particles Inhaled by Rats
Toxicological Sciences, 2005
Depleted uranium (DU) is a radioactive heavy metal coming from the nuclear industry and used in numerous military applications. Uranium inhalation can lead to the development of fibrosis and neoplasia in the lungs. As little is known concerning the molecular processes leading to these pathological effects, some of the events in terms of genotoxicity and inflammation were investigated in rats exposed to DU by inhalation. Our results show that exposure to DU by inhalation resulted in DNA strand breaks in broncho-alveolar lavage (BAL) cells and in increase of inflammatory cytokine expression and production of hydroperoxides in lung tissue suggesting that the DNA damage was in part a consequence of the inflammatory processes and oxidative stress. The effects seemed to be linked to the doses, were independent of the solubility of uranium compounds and correlating with the type of inhalation. Repeated inhalations seemed to induce an effect of potentiation in BAL cells and also in kidney cells. Comet assay in neutral conditions revealed that DNA damage in BAL cells was composed partly by double strands breaks suggesting that radiation could contribute to DU genotoxic effects in vivo. All these in vivo results contribute to a better understanding of the pathological effect of DU inhalation.
Evaluation of the cytotoxicity and the genotoxicity induced by α radiation in an A549 cell line
Radiation Measurements, 2011
Exposure to radon and its progenies represents one of the greatest risks of ionizing radiation from natural sources. Nowadays, these risks are assessed by the extrapolation of biological effects observed from epidemiological data. In the present study, we made a dose response curve, to evaluate the in vitro response of A549 human lung cells to a-radiation resulting from the decay of a 210 Po source, evaluated by the cytokinesis blocked micronuclei assay. The clonogenic assay was used to measure the survival cell fraction. As expected, the results revealed an increase of cellular damage with increased doses made evident from the increased number of micronuclei (MN) per binucleated cell (BN). Besides this study involving the biological effects induced by direct irradiation, and due to the fact that radiation-induced genomic instability is thought to be an early event in radiation carcinogenesis, we analyzed the genomic instability in early and delayed untargeted effects, by using the medium transfer technique. The obtained results show that unirradiated cells exposed to irradiated medium reveal a higher cellular damage in earlier effects when compared to the delayed effects. The obtained results may provide clues for the biodosimetric determination of radon dose to airway cells at cumulative exposures.
2009
Irradiation experiments conducted on dogs and mice at Argonne National Laboratory, IL between 1952 and 1992 led to creation of archives of paraffin embedded tissues accompanied by extensive datasets with gross pathology and histopathology information. Over the past 40 years these data were investigated computationally, using different statistics approaches. Embedded tissues are used to this day as a source of genomic and mitochondrial DNA for quantitative PCR amplification. Data and paraffin block sections are available upon request-interested researchers should visit the websites http://janus.northwestern.edu/dog\_tissues/introduction.php for dog and http://janus.northwestern.edu/janus2/index.php for mouse archive.
The Effects of Radiation and Dose-Fractionation on Cancer and Non-Tumor Disease Development
International Journal of Environmental Research and Public Health, 2012
The Janus series of radiation experiments, conducted from 1970 to 1992, explored the effects of gamma and neutron radiation on animal lifespan and disease development. Data from these experiments presents an opportunity to conduct a large scale analysis of both tumor and non-tumor disease development. This work was focused on a subset of animals from the Janus series of experiments, comparing acute or fractionated exposures of gamma or neutron radiation on the hazards associated with the development of tumor and non-tumor diseases of the liver, lung, kidney or vascular system. This study also examines how the co-occurrence of non-tumor diseases may affect tumor-associated hazards. While exposure to radiation increases the hazard of dying with tumor and non-tumor diseases, dose fractionation modulates these hazards, which varies across different organ systems. Finally, the effect that concurrent non-cancer diseases have on the hazard of dying with a tumor also differs by organ system. These results highlight the complexity in the effects of radiation on the liver, lung, kidney and vascular system.