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Manifestation of radiation effects in cold environment: data review and modeling

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Abstract

The peculiarities of radiation response in animals at low environmental temperatures are analyzed in the context of radiation safety of the Arctic/Northern wildlife. The paper includes a data review on radiation effects in cold environments based on international and Russian publications since 1948, which forms a supplement to the EPIC and FREDERICA data collections. In homoiothermic and heterothermic animals, imbalances in thermoregulation caused by ionizing radiation are discussed, which increase energy loss of animals, and decrease their fitness to the Arctic/Northern climate. In poikilothermic animals, both radiation damage and recovery are temperature dependant, their rates being slow in the cold environment. At low temperatures, radiation damage of biological tissues is conserved in hidden form; when the temperature of poikilothermic animal rises to a normal level, radiation injury is developed rapidly similar to acute dose response. Additionally, a mathematical model is described, demonstrating the combined effects of chronic radiation exposures and seasonal temperature variations on a fish population. Computer simulations show that at the same level of irradiation, the overall radiation damage to Arctic/Northern poikilothermic fish is higher than that to the fish from warm climate. Considering the peculiarities of radiation effects in the cold climate, the Arctic/Northern fauna might be expected to be more vulnerable to chronic radiation stress compared to temperate fauna. In the case of acute radiation exposure during winter periods, hibernation of heterothermic and cooling of poikilothermic animals may provide temporary protection from acute radiation effects.

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Acknowledgments

This work was performed within the framework of the Norwegian Research Council Project “Impact Assessment of elevated levels of natural/technogenic radioactivity on wildlife of the North” (INTRANOR), leading by the Norwegian Radiation Protection Authority, whose support is gratefully acknowledged.

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  1. Research and Production Association “Typhoon”, 4 Pobedy Str, 249038, Obninsk, Kaluga Region, Russia

    T. G. Sazykina & A. I. Kryshev

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  1. T. G. Sazykina
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  2. A. I. Kryshev
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Correspondence to T. G. Sazykina.

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Sazykina, T.G., Kryshev, A.I. Manifestation of radiation effects in cold environment: data review and modeling. Radiat Environ Biophys 50, 105–114 (2011). https://doi.org/10.1007/s00411-010-0336-7

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