Natural Radioactivity Levels and Radiological Risk Assessment in Locally Grown Maize and Beans from Bungoma County

doi:10.4236/oalib.1112592

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Open Access Library Journal 11 2024

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Natural Radioactivity Levels and Radiological Risk Assessment in Locally Grown Maize and Beans from Bungoma County

DOI: 10.4236/oalib.1112592, PP. 1-18

Stanley C. Tsimbasi,John W. Makokha,Benjamin O. Odumo

Subject Areas: Agricultural Science

Keywords: Radionuclides, Radiological Risk Assessment, Absorbed Dose Rate, Annual Effective Dose, Cereals, Pulses

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Abstract

This study investigated the concentration of ²²⁶Ra, ²³²Th, and ⁴⁰K in maize (Zea mays) and beans (Phaseolus vulgaris), the common cereals and pulses available in Bungoma County. Eighteen representative samples were collected from the study area and analyzed using a Thallium-activated Sodium Iodide NaI (TI) scintillation detector. The average activity concentration of²²⁶Ra, ²³²Th, and ⁴⁰K in maize were found to be 20.9±7.19 Bq/kg, 54±21.15 Bq/kg, and 161±76.84 Bq/kg, while in beans, these values were 18.4±4.03 Bq/kg, 43±15.51 Bq/kg and 195±132.48 Bq/kg respectively. The mean absorbed dose rate were 49±2.45 nGy/h and 43±2.15 nGy/h for maize and beans respectively which were lower than the admissible dose standard of 1500 nGy/h. The average annual effective ingestion dose (AEID) in maize and beans were 1.240 mSv/y and 0. 263 mSv/y respectively. The average AEID values in maize were above the limit of 1mSv/y for the general public, as the International Commission on Radiological Protection (ICRP) recommended. This shows that there is an increased health risk for the whole body of an individual due to the intake of maize with higher AEID. While the AEID in maize suggests an elevated health risk for consumers due to whole-body radiation exposure, the overall radiological risk posed by beans and other consumption in the region remains minimal and within international safety limits hence poses no significant risk to the consumers and the general populace of Bungoma County.

Cite this paper

Tsimbasi, S. C. , Makokha, J. W. and Odumo, B. O. (2024). Natural Radioactivity Levels and Radiological Risk Assessment in Locally Grown Maize and Beans from Bungoma County. Open Access Library Journal, 11, e2592. doi: http://dx.doi.org/10.4236/oalib.1112592.

References

[1]	Alatise, O.O. and Adebesin, T.C. (2020) Assessment of Radionuclides in Some Nigerian Made Cereals and Tea Products. Journal of Natural Sciences Engineer-ing and Technology, 18, 128-142. https://doi.org/10.51406/jnset.v18i1.2037
[2]	Salih, N. (2018) Determina-tion of Natural Radioactivity and Radiological Hazards of 226Ra, 232Th, and 40K in the Grains Available at Penang Markets, Malaysia, Using High-Purity Germanium Detector. ARO—The Scientific Journal of Koya University, 6, 71-77. https://doi.org/10.14500/aro.10327
[3]	Vila‐Real, C.P.d.M., Pimenta‐Martins, A.S., Kunyanga, C.N., Mbugua, S.K., Katina, K., Maina, N.H., et al. (2022) Nutritional Intake and Food Sources in an Adult Urban Kenyan Popula-tion. Nutrition Bulletin, 47, 423-437. https://doi.org/10.1111/nbu.12582
[4]	Solehah, A.R., Yasir, M.S. and Sa-mat, S.B. (2016). Activity Concentration, Transfer Factors and Resultant Radio-logical Risk of 226Ra, 232Th, and 40K in Soil and Some Vegetables Consumed in Selangor, Malaysia. AIP Conference Proceedings, 1784, Article ID: 040016. https://doi.org/10.1063/1.4966802
[5]	UNSCEAR (2000) United Nations Scientific Committee on the Effects of Atomic Radiation, Sources and Effects of Ionizing Radiation. United Nations Publication. https://doi.org/10.18356/49c437f9-en
[6]	El-Gamal, H., Hussien, M.T. and Saleh, E.E. (2019) Evaluation of Natural Radioactivity Levels in Soil and Various Foodstuffs from Delta Abyan, Yemen. Journal of Radiation Research and Ap-plied Sciences, 12, 226-233. https://doi.org/10.1080/16878507.2019.1646523
[7]	Abbasi, A., Kurnaz, A., Turhan, Ş. and Mirekhtiary, F. (2020) Radiation Hazards and Natural Radi-oactivity Levels in Surface Soil Samples from Dwelling Areas of North Cyprus. Journal of Radioanalytical and Nuclear Chemistry, 324, 203-210. https://doi.org/10.1007/s10967-020-07069-w
[8]	Sultana, A., Siraz, M.M., Pervin, S., Rahman, A.M., Das, S.K. and Yeasmin, S. (2020) Assessment of Ra-dioactivity and Radiological Hazard of Different Food Items Collected from Local Market in Bangladesh. Journal of Bangladesh Academy of Sciences, 43, 141-148. https://doi.org/10.3329/jbas.v43i2.45735
[9]	Olatunji, M.A., Uwatse, O.B., Khandaker, M.U., Amin, Y.M. and Faruq, G. (2014) Radiological Study on Newly Developed Composite Corn Advance Lines in Malaysia. Physica Scripta, 89, Article ID: 125002. https://doi.org/10.1088/0031-8949/89/12/125002
[10]	ICRP (1999) ICRP Publication 82: Protection of the Public in Situations of Pro-longed Radiation Exposure (Vol. 82). Elsevier Health Sciences. https://doi.org/10.1016/s0146-6453(00)00009-9
[11]	Fathabadi, N., Salehi, A.A., Naddafi, K., Kardan, M.R., Yunesian, M., Nodehi, R.N., et al. (2017) Radio-activity Levels in the Mostly Local Foodstuff Consumed by Residents of the High Level Natural Radiation Areas of Ramsar, Iran. Journal of Environmental Radio-activity, 169, 209-213. https://doi.org/10.1016/j.jenvrad.2016.12.011
[12]	Yachiso, G.T., Chaubey, A.K. and Turi, B. (2023) Transfer Factor of Radionuclides from Soil to Cereal Crops around Gold Mining and Evaluation of Corresponding Radiological Hazard Levels Oromia, Ethiopia. International Journal of Environmental Analytical Chemistry, 104, 6947-6963. https://doi.org/10.1080/03067319.2022.2158737
[13]	Lopes, J.M., Garcêz, R.W.D., Filgueiras, R.A., Silva, A.X. and Braz, D. (2018) Committed Effective Dose Due to the Intake of 40K, 226Ra, 228ra and 228Th Contained in Foods Included in the Diet of the Rio de Janeiro City Population, Brazil. Radiation Pro-tection Dosimetry, 181, 149-155. https://doi.org/10.1093/rpd/ncx310
[14]	Bungoma County Government (2021) Annual Development Plan 2021. https://www.bungoma.go.ke/wp-content/uploads/2023/08/ADP-2021.pdf
[15]	Butiki, G.W., Makokha, J.W., Masinde, F.W. and Wanyama, C.K. (2021) Annual Effective Dose from Radon-222 Concentration Levels in Underground Water in Bungoma South Sub-County, Kenya. ITEGAM—Journal of Engineering and Technology for Industrial Applications, 7, 78-82. https://doi.org/10.5935/jetia.v7i28.736
[16]	Wanyama, C.K., Makokha, J.W. and Masinde, F.W. (2020) A Radiological Survey in Tailings: A Case Study of Rosterman Gold Mine, Western Kenya. OALib, 7, e6293. https://doi.org/10.4236/oalib.1106293
[17]	Wanyama, C.K., Masinde, F.W., Makokha, J.W. and Matsitsi, S.M. (2020) Estimation of Radiological Hazards Due to Natural Radionuclides from the Rosterman Gold Mine Tailings, Lurambi, Ka-kamega, Kenya. Radiation Protection Dosimetry, 190, 324-330. https://doi.org/10.1093/rpd/ncaa113
[18]	Wanyama, C.K., Makokha, J.W., Masinde, F.W. and Waswa, M.N. (2020) Natural Radioactivity and External Dose Rates in Tailing Samples from Rosterman Gold Mine, Kakamega County, Kenya. ITEGAM—Journal of Engineering and Technology for Industrial Applica-tions, 6, 73-77. https://doi.org/10.5935/jetia.v6i26.718
[19]	Wanyama, C.K., Makokha, J.W. and Masinde, F.W. (2020) Assessment of Natural Radioactivity Levels in Tailings from Lurambi-Rosterman Gold Mine, Kakamega County Ken-ya. Global Scientific Journal, 8, 2456-2468.
[20]	Wanyama, C.K., Makokha, J.W., Masinde, F.W. and Matsitsi, S.M. (2020) Radiological Assessment of the Activity Concentrations of 40K, 232Th, 238U and Exposure Levels in the Ros-terman Gold Mine of Lurambi Area, Western, Kenya. International Journal of Research and Scientific Innovation, 7, 209-212.
[21]	Amana, M.S. (2017) Ra-diation Hazard Index of Common Imported Ceramic Using for Building Materials in Iraq. Australian Journal of Basic and Applied Sciences, 11, 94-102.
[22]	Belivermis, M., Kiliç, O., Çotuk, Y. and Topcuoğlu, S. (2009) The Effects of Physicochemical Properties on Gamma Emitting Natural Radionuclide Levels in the Soil Profile of Istanbul. Environmental Monitoring and Assessment, 163, 15-26. https://doi.org/10.1007/s10661-009-0812-1
[23]	Ahmed, F., Daif, M.M., El-Masry, N.M. and Abo-Elmagd, M. (2010) External and Internal Radiation Exposure of Herbal Plants Used in Egypt. Radiation Effects and De-fects in Solids, 165, 65-71. https://doi.org/10.1080/10420150903428054
[24]	Stewart, F.A., Akleyev, A.V., Hauer-Jensen, M., Hendry, J.H., Kleiman, N.J., MacVittie, T.J., et al. (2012) ICRP PUBLICATION 118: ICRP Statement on Tissue Reactions and Early and Late Effects of Radiation in Normal Tissues and Organs—Threshold Doses for Tissue Reactions in a Radiation Protection Context. Annals of the ICRP, 41, 1-322. https://doi.org/10.1016/j.icrp.2012.02.001
[25]	Rotich, C.K. (2022) Effects of Human Exposure and Associated Risks Due to Natural Radioactivity and Heavy Metals in Bureti, Kericho County, Kenya. Doctoral Dissertation, Ken-yatta University.
[26]	Marques, R., Prudêncio, M.I., Russo, D., Cardoso, G., Dias, M.I., Rodrigues, A.L., et al. (2021) Evaluation of Naturally Occurring Ra-dionuclides (K, Th and U) in Volcanic Soils from Fogo Island, Cape Verde. Jour-nal of Radioanalytical and Nuclear Chemistry, 330, 347-355. https://doi.org/10.1007/s10967-021-07959-7
[27]	Kim, G. and Cho, J. (2022) Radioactive Concentrations in Chemical Fertilizers. Journal of Radiation Protection and Research, 47, 195-203. https://doi.org/10.14407/jrpr.2021.00269
[28]	Angeleska, A., Dimitrieska Stojkovik, E., Hajrulai Musliu, Z., Stojanovska Dimzoska, B., Esmerov, I. and An-gelovska, A. (2022) Assessment of Radiological Hazard for Various Food Com-monly Used in Republic of North Macedonia. Journal of Agriculture and Plant Sciences, 20, 9-14. https://doi.org/10.46763/japs22202009a
[29]	Avwiri, G.O., Ononugbo, C.P. and Olasoji, J.M. (2021) Radionuclide Transfer Factors of Staple Foods and Its Health Risks in Niger Delta Region of Nigeria. International Journal of Innovative Environmental Studies Research, 9, 21-32
[30]	Tawalbeh, A.A., Abumurad, K.M., Samat, S.B. and Yasir, M.S. (2011) A Study of Natural Radionuclide Activities and Radiation Hazard Index in Some Grains Consumed in Jordan. Malaysian Journal of Analytical Sciences, 15, 61-69.
[31]	Banzi, F., Msaki, P. and Mohammed, N. (2017) Assessment of Radioactivity of 226Ra, 232Th and 40K in Soil and Plants for Estimation of Transfer Factors and Effective Dose around Mkuju River Project, Tanzania. Mining of Mineral Deposits, 11, 93-100. https://doi.org/10.15407/mining11.03.093
[32]	Awudu, A.R., Faanu, A., Darko, E.O., Emi-Reynolds, G., Adukpo, O.K., Kpeglo, D.O., et al. (2011) Prelim-inary Studies on 226Ra, 228Ra, 228Th and 40K Concentrations in Foodstuffs Consumed by Inhabitants of Accra Metropolitan Area, Ghana. Journal of Radio-analytical and Nuclear Chemistry, 291, 635-641. https://doi.org/10.1007/s10967-011-1444-9
[33]	Alharbi, A. and El-Taher, A. (2013) A Study on Transfer Factors of Radionuclides from Soil to Plant. Life Science Journal, 10, 532-539.
[34]	Wanjala, E.M. (2016) Assessment of Hu-man Exposure to Natural Source of Radiation on the Soil in Tongaren Constitu-ency of Bungoma County, Kenya. Master’s Thesis, Kenyatta Universi-ty.
[35]	Mohebian, M. and Pourimani, R. (2020) Specific Activity and Radiation Hazard of Radionuclides in Wheat and Bean Produced near Shazand, Iran. Ira-nian Journal of Medical Physics, 17, 394-400.
[36]	Rilwan, U., Jafar, M., Musa, M., Idris, M.M. and Waida, J. (2022) Transfer of Natural Radionuclides from Soil to Plants in Nasarawa, Nasarawa State, Nigeria. Journal of Radiation and Nucle-ar Applications: An International Journal, 7, 81-86. https://doi.org/10.18576/jrna/070209
[37]	Muhammad, A.N., Ismail, A.F. and Garba, N.N. (2024) Natural Radioactivity in Food Crops and Soil and Esti-mation of the Concomitant Dose from Tin Mining Areas in Nigeria. Journal of Taibah University for Science, 18, Article ID: 2366507. https://doi.org/10.1080/16583655.2024.2366507

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