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Abstract

Many scientists and regulators utilize the linear no-threshold (LNT) relationship to estimate the likelihood of carcinogenesis. The LNT model is incorrect and was adopted based upon false pretenses. The use of the model has been corrupted by many to claim that even the smallest ionizing radiation dose may initiate carcinogenesis. This claim has resulted in societal harm.

Keywords

cancer dose response hormesis radiation risk assessment LNT

Introduction

The linear no-threshold (LNT) model is based upon the proportionality of radiation dose and cancer risk. This model is supported by flawed scientific and epidemiological data. For example, the scientific data, based upon γH2AX foci as a marker for DNA double-strand breakage, demonstrate linearity between dose and DNA damage from 1 mGy to 100 Gy. The hypotheses follow: (1) Each double-strand break has an equal probability at inducing transformation irrespective of the number of double-strand breaks simultaneously within the cell and (2) each transformed cell has the same probability of developing into a cancer irrespective of the tissue environment and/or health of the organism.^1,2 However, γH2AX is a nonspecific marker and may result from single-strand breaks.³

From the scientific data, one must conclude that dose and carcinogenic risk is nonlinear if one views the organism in a hierarchical approach. Organisms are made up of systems, systems are made up of tissues, tissues are made up of cells, and cells are made up of their constituents. At each level mechanisms exist to prevent and/or mitigate damage.^4
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Cellular Defenses

Three types of defenses that immediately combat DNA damage have been identified.⁷ (1) Defenses against reactive oxygen species (ROS)—Oxygen metabolism, infection, physical exercise, ionizing radiation, ultraviolet light, chemicals, and others result in ROS. Potential damage is mitigated by scavengers and antioxidant molecules within cells. (2) DNA repair—There are cellular sensor molecules that detect DNA damage which eventually result in cell cycle arrest, DNA repair, and upregulation of defense mechanisms. DNA repair is dependent upon the dose and dose rate. (3) Elimination of damaged cells—Cells are eliminated through apoptotic, mitotic, and senescent cell death.

Adaptive responses

When cells undergo radiogenic or nonradiogenic genotoxic damage, an increase in protective mechanisms are observed in the cells and nearby cells (bystander effects). These defenses include ROS scavengers, damaged cell removal, and DNA repair. The upregulation of these factors can last for hours to months.⁷

Tissue Defenses

The surrounding environment protects and controls cellular proliferation when functional. If the microenvironment is impaired through physical, chemical agents, or disease, the cells are more likely to undergo DNA alterations with subsequent neoplastic transformation. Tissue disorganization also facilitates escape of preneoplastic subclones from microenvironmental barriers. For example, fibrosis increases the risk for cancer of the lung, liver, and skin. Immune mechanisms are also potent regulators in the prevention of cancer. Currently, there are many therapies that modulate the immune system for the treatment of cancer.

Although an imperfect system, life has evolved to protect itself from genotoxic damage. When cellular and/or tissue repair mechanisms are damaged, the risk of cancer increases. Organisms are constantly undergoing genotoxic stresses. Small insults are fairly well addressed and may be beneficial; however, with large insults, the cell, the tissue, the system, and the body are unable to compensate appropriately and the risk of cancer exceeds a threshold above which cancer risk increases.

Too often, epidemiological evidence is used inappropriately to support the LNT model. For example, the atomic bomb data have been frequently used to demonstrate the concept of the LNT model. However, the atomic bomb survivors were exposed to other carcinogenic agents including trauma from nonradioactive insults such as burns, nonradioactive toxins from the explosion, and subsequent fires, which contaminated the food, water, and air.⁸ Environmental stressors unrelated to ionizing radiation increase the risk for carcinogenesis or other adverse health effects. For example, the World Trade Center Disaster on September 11, 2001, released a number of toxins into the environment possibly resulting in an increased risk of certain cancers.⁹ Also, the incidence of all cancers was higher among Israeli Jews who were exposed to the extreme stressors of the Holocaust than among those who were not.¹⁰ These nonradioactive stressors should be considered by those claiming that low doses of radiation are carcinogenic. Furthermore, the stigma associated with the radioactive exposure may have resulted in many atomic bomb survivors who were exposed to higher doses to claim that they were further away from the explosion, resulting in incorrect dose estimates. To further complicate the matter, the estimated doses do not include that from residual radiation thereby underestimating those (including the “not in the city” control population) who were thought to have received, for example, less than 100 mGy.^11-12 Furthermore, the atomic bomb survivors and the “not in the city” controls have a longer life span and reduced cancer mortality relative to unirradiated Japanese.¹² There are many good reviews that provide critiques of the epidemiological studies.^7,13,14

Hormesis

Compelling scientific and epidemiological data for hormesis exist.^13

-19 Small insults, whether from radiation or other genotoxic stressors, result in upregulation of protective mechanism at the cell and tissue level. These defenses more than compensate for any potential (or real) damage that the organism incurred from the original insult; thereby decreasing the risk of carcinogenesis from future genotoxic insults.

Conclusion

Data for ionizing radiation induced carcinogenesis support the existence of a hormetic response at low doses with a threshold. The dose from current diagnostic studies (eg, 10 mGy) is well below the threshold. Those who estimate radiation induced cancer risks should consider confounding effects of coexisting nonradiation carcinogenic risks. The fear of carcinogenesis that has been propagated due to those grossly overestimating the cancer risks from low doses of ionizing radiation is unethical and has resulted in medical, economic, and other societal harm.^20

-24 The LNT model should not be applied for cancer risks in the low-dose range. The regulatory bodies including the Nuclear Regulatory Commission should change from an LNT-model based risk assessment to the integrated LNT-Hormesis model as Calabrese describes.²⁵

Footnotes

Declaration of Conflicting Interests

The author(s) declared no potential conflicts of interest with respect to the research, authorship, and/or publication of this article.

Funding

The author(s) received no financial support for the research, authorship, and/or publication of this article.

ORCID iD

Joseph M. Kaminski

References

NCRP. Evaluation of the Linear-Nonthreshold Dose-Response Model for Ionizing Radiation. Bethesda, MD: NCRP, 2001: NCRP Report No. 136.

NCRP. Implications of Recent Epidemiological Studies for the Linear-Nonthreshold Model and Radiation Protection. Bethesda, MD: NCRP, 2018: NCRP Commentary No. 27.

Katsube

Mori

Tsuji

. Most hydrogen peroxide-induced histone H2AX phosphorylation is mediated by ATR and is not dependent on DNA double-strand breaks. J Biochem. 2014; 156(2):85–95.

Feinendegen

Pollycove

Neumann

. Whole-body responses to low-level radiation exposure: new concepts in mammalian radiobiology. Exp Hematol. 2007;35(4 suppl 1):37–46. doi:10.1016/j.exphem.2007.01.011.

Trosko

. Hierarchical and cybernetic nature of biologic systems and their relevance to homeostatic adaptation to low-level exposures to oxidative stress-inducing agents. Environ Health Perspect. 1998;106(suppl 1):331–339. doi:10.1289/ehp.98106s1331.

Ulsh

. Checking the foundation: recent radiobiology and the linear no-threshold theory. Health Phys. 2010;99(6):747–758. doi:10.1097/HP.0b013e3181e32477.

Tubiana

Feinendegen

Yang

Kaminski

. The linear no-threshold relationship is inconsistent with radiation biologic and experimental data. Radiology. 2009;251(1):13–22. doi:10.1148/radiol.2511080671.

Institute of Medicine (US) Steering Committee for the Symposium on the Medical Implications of Nuclear War. Solomon

Marston

, eds. The Medical Implications of Nuclear War. Washington, DC: National Academies Press (US); 1986. Possible Toxic Environments Following a Nuclear War. https://www.ncbi.nlm.nih.gov/books/NBK219160/. Accessed March 16, 2020.

Lieberman-Cribbin

Tuminello

Gillezeau

, et al. The development of a Biobank of cancer tissue samples from World Trade Center responders. J Transl Med. 2018;16(1):280. doi:10.1186/s12967-018-1661-x.

10.

Keinan-Boker

Vin-Raviv

Liphshitz

Linn

Barchana

. Cancer incidence in Israeli Jewish survivors of World War II. J Natl Cancer Inst. 2009;101(21):1489–1500.

11.

Sutou

. Rediscovery of an old article reporting that the area around the epicenter in Hiroshima was heavily contaminated with residual radiation, indicating that exposure doses of A-bomb survivors were largely underestimated. J Radiat Res. 2017;58(5):745–754. doi:10.1093/jrr/rrx029.

12.

Sutou

. Low-dose radiation from A-bombs elongated lifespan and reduced cancer mortality relative to un-irradiated individuals [published correction appears in Genes Environ. 2019 Apr 19;41:12]. Genes Environ. 2018;40:26. doi:10.1186/s41021-018-0114-3.

13.

Scott

. A critique of recent epidemiologic studies of cancer mortality among nuclear workers. Dose Response. 2018;16(2):1559325818778702. doi:10.1177/1559325818778702.

14.

Shibamoto

Nakamura

. Overview of biological, epidemiological, and clinical evidence of radiation hormesis. Int J Mol Sci. 2018;19(8):2387. doi:10.3390/ijms19082387.

15.

Calabrese

. Hormesis: path and progression to significance. Int J Mol Sci. 2018;19(10):2871. doi:10.3390/ijms19102871.

16.

Cardarelli

JJ II

Ulsh

. It is time to move beyond the linear no-threshold theory for low-dose radiation protection. Dose Response. 2018;16(3):1559325818779651. doi:10.1177/1559325818779651.

17.

Cuttler

Feinendegen

. Commentary on inhaled (239)PUO2 in Dogs—a prophylaxis against lung cancer? Dose Response. 2015;13(1).pii: dose–response.15–003.Cuttler. doi:10.2203/dose-response.15-003.Cuttler.

18.

Cuttler

Sanders

. Threshold for radon-induced lung cancer from inhaled plutonium data. Dose Response. 2015;13(4):1559325815615102. doi:10.1177/1559325815615102.

19.

Pennington

Siegel

. The Linear no-threshold model of low-dose radiogenic cancer: a failed fiction. Dose Response. 2019;17(1):1559325818824200. doi:10.1177/1559325818824200.

20.

Akabayashi

Hayashi

. Mandatory evacuation of residents during the Fukushima nuclear disaster: an ethical analysis. J Public Health (Oxf). 2012;34(3):348–351. doi:10.1093/pubmed/fdr114.

21.

Hasegawa

Tanigawa

Ohtsuru

. Health effects of radiation and other health problems in the aftermath of nuclear accidents, with an emphasis on Fukushima. Lancet. 2015;386(9992):479–488. doi:10.1016/S0140-6736(15)61106-0.

22.

Murakami

Ono

Tsubokura

. Was the risk from nursing-home evacuation after the Fukushima accident higher than the radiation risk? PLoS One. 2015;10(9):e0137906. doi:10.1371/journal.pone.0137906.

23.

Wigg

. Radiation: facts, fallacies and phobias. Australas Radiol. 2007;51(1):21–25. doi:10.1111/j.1440-1673.2006.01650.x.

24.

Yasumura

Goto

Yamazaki

Reich

. Excess mortality among relocated institutionalized elderly after the Fukushima nuclear disaster. Public Health. 2013;127(2):186–188. doi:10.1016/j.puhe.2012.10.019.

25.

Calabrese

. Model uncertainty via the integration of hormesis and LNT as the default in cancer risk assessment. Dose Response. 2015;13(4):1559325815621764. doi:10.1177/1559325815621764.

Replacing LNT: The Integrated LNT-Hormesis Model

Abstract

Keywords

Introduction

Cellular Defenses

Adaptive responses

Tissue Defenses

Hormesis

Conclusion

Footnotes

Declaration of Conflicting Interests

Funding

ORCID iD

References