Physicochemical Activities of Blood Biomarkers Due to Ingestible Radon-222 in Drinking Water and Its Associated Health Consequences
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Physicochemical Activities of Blood Biomarkers Due to Ingestible Radon-222 in Drinking Water and Its Associated Health Consequences

Authors: I. M. Yusuff, A. M. Arogunjo, S. B. Ibikunle, O. M. Oni, P. O. Osho

Abstract:

Generally, water contamination is a serious health concern, affecting millions of people worldwide every year. Among the water contaminants, radon is a radioactive contaminant understudied and under-regulated. It produces many adverse health effects, including cancer. It is a natural gas that cannot be seen, tasted, or smelled. It develops from the radioactive decay of radium found in the rock of soil and has been considered a health hazard due to its radioactivity in nature. To examine its effects and physicochemical characteristics on the blood biomarkers due to its ingestion in drinking water, its concentrations were monitored and measured in treated and untreated water using Electronic Radon Active Detector (RAD7), while human blood samples were collected using the required laboratory tools. The blood samples were collected and examined physicochemically using semi-automated chemistry analyzer to evaluate the chemistry parameters of the blood. Statistically, results obtained were analyzed using T-test of variables at 95% confidence interval. The outcome of results revealed 112.03 Bq/m3, 561.67 Bq/m3 and 2,753.00 Bq/m3 of radon-222 concentrations in the three water samples used respectively. Demographically, chemistry parameters biomarkers of the blood determined displayed some levels of variations due to radon-222 contaminants ingested from untreated water. Also, analyzed results of blood revealed the associations between the physicochemical parameters of the blood biomarkers and volunteers’ health consequences. The consequences observed were more severed with group B volunteers than group A, due to high level of radon contaminants in borehole water consumed by group B than in well water consumed by group A. The percentages of elevated and depressed biomarkers observed differ from initial reference values and, were the dysfunction indicators. They are directly or indirectly associated to human’s state of health. Most significant biomarkers affected were; HCO3, Cl, K, Cr and Na, they are relevant biomarkers in medicine to determine human’s state of health at any point in time.

Keywords: Radioactive, radon, biomarker, ingestion, dysfunction.

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References:


[1] Alexandre T. M., Marcelo P. and Etienne M. “Physicochemical analysis of blood and urine in the course of acute kidney injury in critically ill patients: a prospective, observational study”. Maciel et al. BMC Anesthesiology 2013, 13:31. http://www.biomedcentral.com/1471-2253/13/31.
[2] Aliso V. “Radon in Water: What You Need to Know”. © 2023 Seychelle. Aliso Viejo, CA Powered by Shopify. https://www.seychelle.com. October 26, 2022.
[3] Biomarkers Definitions Working Group (BDWG) "Biomarkers and surrogate endpoints: preferred definitions and conceptual framework". Clinical Pharmacology and Therapeutics (Review) 2001. 69 (3): 89–95. doi:10.1067/mcp.2001.113989. PMID 11240971. S2CID 288484.
[4] Environmental Protection Agency (EPA) “Basic Information about Radon in Drinking Water”. Last updated on Monday, June 30, 2014
[5] European Commission. The new Euratom. Basic Safety Standards Directive, 2001.
[6] International Commission on Radiological Protection (ICRP) “Occupational intakes of radionuclides: part 3. ICRP Publication”. ICRP 46(3/4). France: ICRP; 2017.
[7] Jian J. “Urine Biomarkers in the Early Stages of Diseases: Current Status and Perspective”. Copyright 2020, Discovery Medicine. November 24, 2022 January 1, 2020.
[8] Lu S., Yan P., Xiaochun W., Gang G., Lina W., Chunnan P., Jianlei R. and Jianxiang L. “Screening for Potential Biomarkers in Peripheral Blood from Miners Exposed to Radon Radiation”. Potential Biomarkers of Radiation Damage. Dose-Response: An International Journal. January-March 2020:1-10. sagepub.com/journals-permissions. DOI: 10.1177/1559325820904600. journals.sagepub.com/home/dos.
[9] Mark K. “Biomarkers: Complete List of Most Common Biomarkers and Blood Tests (and Some Lessons Learned)”. Published on Mark Koester's Blog. https://github.com/markwk/awesome-biomarkers. Feb 21st, 2018
[10] Métivier H., Melo D., Bertholon J. F., Nosske D., Harrison J. D., Phipps A.W., Hendry J. H., Paquet F., Leggett R., Simko M. “Radiation Protection”. Human Alimentary Tract Model – Preface -29 Jun-:5 August 2004.
[11] Nalejska, E. "Prognostic and Predictive Biomarkers". Molecular Oncology and enetics 2014. 18 (3): 273–284. doi:10.1007/s40291-013-0077-9. PMC 4031398. PMID 24385403.
[12] RAD7 Manual. “Electronic Active Radon Detector (RAD7) User Manual”. ©Copyright 2021 DURRIDGE Company Inc. www.durridge.com/support/product-manuals. Revision; 2021-01-07.
[13] Wang, Q. and Raghothama C. "Mutant proteins as cancer-specific biomarkers". Proceedings of the National Academy of Sciences 2010. 108 (6): 2444–2449. doi:10.1073/pnas.1019203108. PMC 3038743. PMID 21248225.
[14] Yang Q. “Principles and Methods of molecular paleontology”. pp96-148. Science Publishing Company, Beijing, China, 2003.
[15] Yusuff I. M., O. M. Oni, A. A. Aremu. “Computational Model for Prediction of Soil-Gas Radon-222 Concentration in Soil-Depths and Soil Grain Size Particles”. International Journal of Chemical and Molecular Engineering. World Academy of Science, Engineering and Technology. Vol: 14, No:5, 2020. ISNI: 0000000091950263.