Biological Systems: Theory and Innovation

Biochemical blood parameters in cattle exposed to radiation

Mykola Lazariev, Liliia Kalachniuk, Alla Klepko
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Abstract

Under contemporary conditions, the study of adaptive processes in living organisms remains highly relevant, particularly in relation to the biochemical blood parameters of cattle kept for extended periods in areas contaminated with radionuclides. This study aimed to determine blood biochemical parameters, analyse characteristic changes, assess their impact on animal health, and evaluate the degree of damage caused by radioactive iodine isotopes. The study examined biochemical parameters – including the activity of amylase, aspartate and alanine aminotransferases (AST and ALT), glutathione peroxidase (GPx), the concentration of lipid hydroperoxides (LHP), the level of ceruloplasmin, and total plasma protein – using standard biochemical methods. The results revealed a wide range of parameter values; however, no significant differences were observed between the groups of cattle exposed to various doses of ionising radiation (1 Gy to the body, 2 Gy to the gastrointestinal tract, and up to 40 Gy to the thyroid gland) resulting from Chornobyl radioactive fallout, including radioactive iodine affecting the thyroid and those kept in relatively uncontaminated areas exposed to only minimal doses of radiation (within a few mGy). Characteristic changes in biochemical parameters and potential alterations in health status were analysed. It was established that under conditions of high-dose thyroid irradiation (40 Gy to the thyroid gland), powerful adaptive mechanisms are activated in the body. These mechanisms counteract the harmful effects of ionising radiation at the organismal level and help preserve important productive traits such as fertility and productivity. These findings may serve as a basis for developing a system of measures aimed at regulating the adaptive responses of organisms exposed to ecopathogenic factors

Keywords

stable iodine (127I); radioactive iodine (131I); radionuclide-contaminated area; thyroid gland; blood; enzymatic activity; biochemical parameters

Suggested citation
Lazariev, M., Kalachniuk, L., & Klepko, A. (2024). Biochemical blood parameters in cattle exposed to radiation. Biological Systems: Theory and Innovation, 15(4), 51-61. https://doi.org/10.31548/biologiya/4.2024.51
References

1. Bartusková, M., Selivanova, A., Malátová I., Hůlka J., Škrkal, J., Rosmus, J., Kapyltsova, A., & Rulík, P. (2023). A comparison of different detection techniques for 137Cs measurements of cattle in vivoRadiation Protection Dosimetry, 199(19), 2373-2382. doi: 10.1093/rpd/ncad252.

2. Bell, M.C. (1985). Radiation effects on livestock: Physiological effects, dose response. Veterinary and human toxicology, 27(3), 200-207.

3. Beresford, N.A. et al., (2000). The transfer of ¹³⁷Cs and ⁹⁰Sr to dairy cattle fed fresh herbage collected 3.5 km from the Chernobyl nuclear power plant. Journal of Environmental Radioactivity, 47(2), 157-170. doi: 10.1016/s0265-931x(99)00037-5.

4. Diyabalanage, S., Dangolla, A., Mallawa, C., Rajapakse, S., & Chandrajith, R. (2020). Bioavailability of selenium (Se) in cattle population in Sri Lanka based on qualitative determination of glutathione peroxidase (GSH-Px) activities. Environmental Geochemistry and Health, 42(2), 617-624. doi: 10.1007/s10653-019-00395-3.

5. Giovanella, L., Avram, A.M., Ovčariček, P.P., & Clerc, J. (2022). Thyroid functional and molecular imaging. Medical Functional Imaging, 51(2), article number 104116. doi: 10.1016/j.lpm.2022.104116.

6. Haque, M., Binte Dayem, S., Tabassum Tasnim, N., Islam, M.R., & Shakil, M.S. (2024). Biological impact of Chornobyl radiation: A review of recent progress. International Journal of Radiation Biology, 100(10), 1405-1415. doi: 10.1080/09553002.2024.2391813.

7. Horikami, D., et al. (2022). The effect of exposure on cattle thyroid after the Fukushima Daiichi nuclear power plant accident. Scientific Reports, 12, article number 21754. doi: 10.1038/s41598-022-25269-0.

8. Hruzieva, T.S., et al. (2020). Biostatistics. Vinnytsia: Nova Knyga.

9. ICRP Publication 153: Radiological Protection in Veterinary Practice. (2023). Annals of the ICRP, 51(4), (9-95). doi: 10.1177/01466453221142702.

10. Kassich, V., Kasianenko, O., Zazharskyi, V., Yatsenko, I., & Klishchova, Zh. (2021). Influence of ionizing radiation on the allergic reactivity of tuberculosis-infected laboratory animals. Scientific Horizons, 24(10), 17-27. https://doi.org/10.48077/scihor.24(10).2021.17-27.

11. Koch, F., Otten, W., Sauerwein, H., Reyer, H., & Kuhla, B. (2023). Mild heat stress-induced adaptive immune response in blood mononuclear cells and leukocytes from mesenteric lymph nodes of primiparous lactating Holstein cows.  Journal of Dairy Science, 106(4), 3008-3022. doi: 10.3168/jds.2022-22520.

12. Labunska, I., Levchuk, S., Kashparov, V., Holiaka, D., Yoschenko, L., Santillo, D., Johnston, P. (2021). Current radiological situation in areas of Ukraine contaminated by the Chornobyl accident: Part 2. Strontium-90 transfer to culinary grains and forest woods from soils of Ivankiv district. Environment International, 146, article number 106282. doi: 10.1016/j.envint.2020.106282.

13. Law of Ukraine No. 791a-XII “On the Legal Regime of the Territory that has been Subjected to Radioactive Contamination as a Result of the Chernobyl Disaster”. (1991, February).  Retrieved from https://zakon.rada.gov.ua/laws/show/791%D0%B0-12.

14. Lazarev, M., Klepko, A., & Kalachniuk, L. (2024). Biochemical blood parameters of cattle during long-term detention in a radionuclide-contaminated territory. Kyiv: NULES of Ukraine.

15. Lazarev, M.M., Klepko, & A.V. (2023). Assessment of hematological and immunological blood parameters in cattle with “Iodine” pathology after the Chernobyl accident. Biological Systems: Theory and Innovations, 14(1-2), doi: 10.31548/biologiya14(1-2).2023.008.

16. Liu, T., et al. (2020). Ultrasmall copper-based nanoparticles for reactive oxygen species scavenging and alleviation of inflammation related diseases. Nature Communications, 11(1), article number 2788. doi: 10.1038/s41467-020-16544-7

17. Mushawwir, A., Arifin, J., Darwis, D., Puspitasari, T., Pengerteni, D.S., Nuryanthi, N., & Perman, R. (2020). Liver metabolic activities of Pasundan cattle induced by irradiated chitosan. Biodiversitas Journal of Biological Diversity, 21(12), 5571-5578. doi: 10.13057/biodiv/d211202.

18. Ostapchenko, L.I., Kalachniuk, L.H., Garmanchuk, L.V., Kuchmerovska, T.M., Arnauta, O.V., Arnauta, N.V., & Smirnov, O.O. (2019). Theoretical and methodical funda mentals of the study of metabolic processes in human and animals using blood indicators. Kyiv: NPE Yamchynskyi O.V.

19. Pareniuk, O., & Yasuda, N. (2021). Chornobyl exclusion zone: Current status and challenges. Annals of the ICRP, 50(1), 201-208. doi: 10.1177/01466453211028032.

20. Pegolo, S., Giannuzzi, D., Piccioli-Cappelli, F., Cattaneo, L., Gianesella, M., Ruegg, P.L., Trevisi, E., & Cecchinato, A. (2023). Blood biochemical changes upon subclinical intramammary infection and inflammation in Holstein cattle. Journal of Dairy Science, 106(9), 6539-6550. doi: 10.3168/jds.2022-23155.

21. Razavi, S.M., Yaghoobpour, T., & Nazifi S. (2023) A review on acute phase response in parasitic blood diseases of ruminants. Research in Veterinary Science, 165, article number  105055. doi: 10.1016/j.rvsc.2023.105055.

22. Talerko, M.M., Lev, T.D., Drozdovitch, V.V., & Masiuk, S.V. (2020). Reconstruction of the radioactive contamination of the territory of Ukraine by Iodine-131 during initial period of the Chornobyl accident using the results from numerical model WRF. Problems of Radiation Medicine and Radiobiology, 25(8), 285-299. doi: 10.33145/2304-8336-2020-25-285-299.

23. Vlizlo V.V., et al. (2012). Laboratory research methods in biology, animal husbandry and veterinary medicine. Lviv: SPOLOM.

24. von Zallinger, C., & Tempel, K. (1998). The physiologic response of domestic animals to ionizing radiation: A review. Veterinary Radiology & Ultrasound, 39(6), 495-503. doi: 10.1111/j.1740-8261.1998.tb01639.x.

25. Yang, H., Liu, L., Wang, M., Li, J., Wang, N.S., Du, G., & Chen, J. (2012). Structure-based engineering of methionine residues in the catalytic cores of alkaline amylase from alkalimonas amylolytica for improved oxidative stability. Applied and Environmental Microbiology, 78(21), 7519-7526. doi: 10.1128/AEM.01307-12.