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Scientific Reports volume 13, Article number: 413 (2023)
258
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Natural radioactivity in irrigation drains was measured by gamma spectrometry, and the resulting dose rates received by aquatic organisms were estimated. Irrigation water and sediment samples were collected from 5 irrigation drains located in Qena governorate, south of Egypt. The average activity concentrations (Bq L−1) of 226Ra, 232Th, and 40 K in irrigation water were 0.76 ± 0.06, 0.27 ± 0.02, and 8.14 ± 0.71, while in sediment (Bq kg−1) were 24.46 ± 1.84, 20.72 ± 1.45, and 453.00 ± 28.14, respectively. The total dose rate per aquatic organism ranged from 1.94 × 10–04 µGy h−1 in Mollusc to 7.15 × 10–04 µGy h−1 in phytoplankton. These values are far from the international recommended limit 400 µGy h−1 for chronic exposure to aquatic organisms, and the dose rate screening value of 10 µGy h−1 suggested by ERICA tool. Based on these results, it is unlikely that harmful effects will appear on the considered aquatic organisms due to exposure to natural radioactivity in the studied environment.
The primordial radionuclides uranium, thorium, and potassium-40 are widely distributed in our environment and represent the main source of background radiation to which all living organisms are exposed. Exposure to background radiation is an ongoing and inescapable feature of life on earth. The United Nations Scientific Committee on the Effects of Atomic Radiation (UNSCEAR) reported that uranium, thorium, and potassium in soil contribute 25%, 40% and 35% of the dose received by humans1. The environmental behavior of these radionuclides depends to a large extent on the characteristics of the ecosystem, so understanding the behavior, mobility, and potential hazard of natural radionuclides is very important for decision-making to protect the environment.
Exposure of non-human organisms to high levels of radiation leads to the emergence of biological responses to them. Therefore, estimating the absorbed dose of those organisms is considered necessary to assess the potential effects of radiation exposure and the harmful risks that it entails in addition to its importance for setting environmental protection criteria. Many international organizations such as European Commission (EC), International Atomic Energy Agency (IAEA), International Commission on Radiological Protection (ICRP), UNSCEAR, and United States Department of Energy (US-DOE) are concerned with protecting the environment from the harmful effects of ionizing radiation and are working on setting criteria for the protection of the environment, some of which are directed to protect non-human species2.
Dose limits for various terrestrial and aquatic plants and animals are based on monitoring disease and mortality rates. ICRP believes that if humans are protected (not exceeding the dose limit of 1 mSv y−1), the non-human species will also be adequately protected3. IAEA and UNSCEAR have proposed a value of 1 mGy d−1 as dose rate limit to protect non-human species4,5. The dose limits set by the US-DOE are 1 mGy d−1 for terrestrial animals and 10 mGy d−1 for terrestrial plants and aquatic animals6.
Despite the possibility of estimating the doses to which humans are exposed from natural background radiation, the matter for non-human species is different due to the different composition and behavior of these organisms. Therefore, estimating the effects of radiation on these species is very difficult, as it is impossible to take into account all the animals and plants that are located in a particular geographical area. To overcome this, a group of organisms representing the ecosystem is selected, called reference organisms, for which models are built to help in calculating dose rates for them.
In Egypt, various studies dealing with radiological risk due to naturally occurring radionuclides in terrestrial and aquatic ecosystems focus on the exposure to humans, while exposure to non-human biota is not covered. Only study conducted by Tawfik et al. aimed to predicate radiological exposure levels of marine biota on the Mediterranean coast was found in literature7. Therefore, the current study aims to evaluate the natural radioactivity levels in sediments and water of irrigation drains located in Qena region, southern Egypt, which is directly affected by the fertilizers used for agricultural purposes that represent a source of freshwater pollution. In addition to calculating the external and internal dose rates for some aquatic reference organisms (Phytoplankton, Molluscs, and Crustaceans) depending on the measured activity in the environmental medium (sediments and water). This study will be the first effort to estimate the dose rates to aquatic organisms in the freshwater ecosystem in Egypt.
Freshwater and sediment samples were collected from 5 irrigation drains (EL-Shikah, EL- Tramsa, EL-Mahrosa, EL-Aslia, and EL-Rawy) located in the geographical area of Qena city, the capital of Qena Governorate, 600 km south of Cairo, (Figs. 1 and 2). 3 sites inside each drain were randomly selected as sampling site; one of these sites represents the outlet of the drain into the Nile River. In addition, one site facing each drain in the main stream of the Nile River was selected to collect freshwater only, thus the total number of samples are 20 freshwater and 15 sediment samples.
Location map of the area under study (ArcGIS software 10.8.1; ArcGIS Online).
Irrigation drain under study.
Polyethylene Marinelli beakers with a capacity of 1.4 L are used as collection and measuring containers. The beakers were washed with dilute hydrochloric acid and distilled water before use, filled to brim, and then pressed the tight lid to eliminate the internal air. Drops of HNO3 were added to the samples to prevent the adhesive of radionuclides with bottle walls8.
Sediment samples were collected by Ekman grab sediment sampler. The collected samples were dried using electrical oven at a temperature of 105℃ for 24 h, then sieved through 200 mesh size. The dried samples were filled in hermetical sealed 500 ml polyethylene beakers. The prepared water and sediment samples were stored for 4 weeks to reach a secular equilibrium of radium and thorium with their progenies9.
Gamma-ray spectrometer consisting of ″3 × 3″ NaI (Tl) detector enclosed in 5 cm thick cylindrical lead shield to reduce the background radiation and connected with 1024 multichannel analyzer was used. The spectrometer was calibrated for energy using 60Co and 137Cs standard point sources, and calibrated for efficiency using a multi-nuclides standard solution which covers a wide range of energy10. The spectrum was accumulated from each sample over 24 h and analyzed by Maestro software. The background was measured under the same condition of sample measurement.226Ra was determined using 214Bi and 214Pb gamma-lines at 609 keV and 352 keV, respectively, while 232Th from gamma-lines of 228Ac (911 keV) and 212Pb (238 keV). 40K was determined from its single gamma-line at 1460 keV. The activity concentration was calculated using the following formula (Eq. 1)11.
where A is the activity concentration (Bq kg−1) or (Bq l−1), Cn is the net counts under a given peak area, T the sample counting time, (varepsilon) is the detection efficiency at measured energy, P is the emission probability and V is the sample volume in liter, M is the sample mass in kilogram. Minimum detectable activity (MDA) was estimated according to Currie definition using Eq. 212 and the MDA values were 0.031, 0.035 and 1.94 Bq L−1 for 226Ra, 232Th, and 40K, respectively.
where B is the background counts under a given peak area,T,ɛ, P, and V are defined above.
The external and internal absorbed dose rate for aquatic organisms (Phytoplankton, Mollusca, and Crustacean) in the studied irrigation drains was calculated based on the measured activity concentrations of 226Ra, 232Th, and 40K in environmental media (water and sediment) and using dose conversion coefficients of a given radionuclide for the reference organisms according to the method outlined by Brown et al. described below13,14.
where sediment conc. is the sediment activity concentration of a given radionuclide in Bq kg−1,water conc. is the water activity concentration of a given radionuclide in Bq m−3, CF is distribution coefficient factors for given radionuclide in freshwater sediment in m3 kg−1, DPUC is the dose rate per unit concentration coefficients (fresh weight) in μGy h−1 per Bq kg−1 weighted for radiation type (alpha = 10, low energy beta = 3, and high energy beta and gamma = 1), solids fraction of wet sediment (0.4), fsed organism is the time fraction spends by organism in sediment, fsedsur organism is the time fraction spends by organism at the sediment/water interface, fwater organism is the time fraction spends by organism in the water column. All parameters used in calculation are taken from Pröhl (2003)15 and Vives i Battle et al. (2004)16. The total dose is then calculated by summating the external and internal doses.
The average activity concentration of 226Ra, 232Th, and 40K in irrigation water and sediment samples collected from 5 irrigation drains located in Qena governorate, south Egypt are present in Table 1. For irrigation water, the 226Ra activity concentration ranged from 0.60 ± 0.05 Bq L−1 in EL- Rawy drain to 0.92 ± 0.07 Bq L−1 in EL-Tramsa drain with an average value of 0.76 ± 0.06 Bq L−1. 232Th activity was from 0.21 ± 0.02 Bq L−1 in EL-Rawy drain to 0.35 ± 0.03 Bq L−1 in EL-Tramsa drain with an average value of 0.27 ± 0.02 Bq L−1. 40 K activity was from 7.61 ± 0.62 Bq L−1 in EL-Shikah drain to 8.67 ± 0.53 Bq L−1 in EL-Mahrosa drain with an average value of 8.14 ± 0.71 Bq L−1. The results indicate that 226Ra, 232Th, and 40 K activities have a narrow range in the studied irrigation drains, which reflects that the water in these drains comes from the same source, the Nile River. In all studied drains 226Ra concentrations are higher than 232Th, which may be due to the effect of the fertilizers used for agriculture purposes and the high solubility of radium17. 40K concentrations are one order of magnitude higher than those of 226Ra and 232Th, which is consistent with potassium being one of the main elements in nature18.
Similar trend was observed in sediment samples, where 226Ra concentrations are higher than 232Th, and 40K concentrations are one order of magnitude higher than both radium and thorium. These results support the fact that sediments act as a sink for the pollutants found in the water column19. 226Ra values ranged from 19.80 ± 1.69 Bq kg−1 in EL- Aslia drain to 30.35 ± 2.10 Bq kg−1 in EL-Tramsa drain with an average value of 24.46 ± 1.84 Bq kg−1. 232Th ranged from 15.95 ± 1.05 Bq kg−1 in EL-Mahrosa drain to 26.05 ± 1.33 Bq kg−1 in EL-Tramsa drain with an average value of 20.72 ± 1.45 Bq kg−1. 40 K was from 371.65 ± 25.10 Bq kg−1 in EL-Shikah to 572.10 ± 30.35 Bq kg−1 in EL-Tramsa drain with an average value of 453.00 ± 28.14 Bq kg−1.
The 226Ra/232Th activity ratios (Table 1) revealed that 226Ra activity is on average 2.73 and 1.20 times higher than 232Th activity in measured irrigation water and sediment samples, respectively. This could be attributed to the contamination from fertilizers discharge and the solubility and geological differences between 226Ra and 232Th.
The spatial distribution of 226Ra, 232Th, and 40 K in irrigation water within each is plotted in Fig. 3 using ArcGIS software. It is clear that the radionuclide concentration varies from one place to another within the drain and from one drain to another, which may be due to several factors such as the type and quantity of fertilizer used in the nearby farmlands, the irrigation periodicity of farmlands, and the level of water body of the drain. The figure also shows a lower activity concentration of the studied radionuclides in the mainstream of the Nile river compared to the drains, which reflects the insignificant effect of irrigation water drainage into the Nile on the levels of radionuclides that could be due to the dilution process caused by the large water body of the Nile compared to the drains.
Spatial distribution of natural radionuclides (Bq L−1) in the irrigation drains under study ((ArcGIS software 10.8.1; ArcGIS Online).
Comparison with previous studies indicated that the activities of 226Ra, 232Th, and 40 K in the current study are higher than those observed for Nasser Lake water (226Ra: 0.0033 Bq L−1) and Nile water from Assiut, Egypt (226Ra:0.20, 232Th:0.08, 40 K:0.69 Bq L−1)20,21. Also, sediment samples have higher activities compared to those obtained for Nasser Lake sediment (226Ra: 22.0, 40 K: 326.20 Bq kg−1) and Nile sediment from Qena, Egypt (226Ra:14.44, 232Th:15.02, 40 K:197.57 Bq kg−1)20,22.
The external, internal, and total absorbed dose rates per aquatic organisms (phytoplankton, mollusc, and crustacean) were calculated according to the procedure outlined above and the average values are present in Table 2. Of the considered aquatic organisms, mollusc received lower doses with values of 1.84 × 10–04 and 9.71 × 10–06 µGy h−1, while phytoplankton received higher doses with values of 7.01 × 10–04 and 1.37 × 10–05 µGy h−1 for external and internal, respectively. Percentage contribution of 226Ra, 232Th, and 40 K to the internal and external doses of the considered aquatic organisms are shown in Figs. 4 and 5. 226Ra is the main contributor to the internal dose of phytoplankton and crustacean, while 40 K is for mollusc. In mollusc and crustacean, 232Th contributes insignificantly to the internal dose, while in phytoplankton the insignificant contribution is from 40 K. The external dose received by the considered organisms mainly comes from 40 K and negligible contribution comes from 232Th and 226Ra (Fig. 5). Total dose rates per organism are 7.15 × 10–04, 1.94 × 10–04, and 5.42 × 10–04 µGy h−1 for phytoplankton, mollusc, and crustacean, respectively. Comparing these values with the value of 400 µGy h−1 recommended by international organizations4,5,6 and the value of 10 µGy h−1 recommended by the ERICA tool23 for chronic exposure to aquatic organisms, below which it is unlikely that harmful effects will appear. The dose rates of considered organisms in the areas under study are less than the level that is likely to cause harm to aquatic organisms. Therefore, the risks to the aquatic organisms in the area under study are minimal.
Percentage contribution of natural radionuclides to the internal dose of aquatic organisms.
Percentage contribution of natural radionuclides to the external dose of aquatic organisms.
In this study, the natural radioactivity levels due to 226Ra, 232Th, and 40K were measured by means of gamma spectrometry in the water and sediments of the 5 irrigation drains located in Qena, southern Egypt. The results showed different natural radioactivity levels from one drain to another. In general, the activity levels of 226Ra were higher than that of 232Th, which reflects the affected of irrigation water by the fertilizers used for agriculture purposes. The activity of 40K was one order of magnitude higher than that of 226Ra and 232Th. By studying the spatial distribution of natural radionuclides of the irrigation water samples in the five drains and their outlets into the Nile river, it was clear that a decrease in the activity level in the Nile mainstream. This may be attributed to the dilution that occurred in the Nile due to the large water body of the Nile compared to drains. Dose rates of aquatic organisms (Phytoplankton, Mollusc, and Crustacean) as a result of exposure to natural radionuclides 226Ra, 232Th, and 40K were calculated, and the results showed that it is unlikely that harmful effects will appear on those organisms due to exposure to the considered radionuclides in the environment under study. This study provides the first basic data on radioactivity levels in the freshwater environment in Egypt and assesses the associated radiological risks to aquatic organisms. Given the importance of this type of study, regular monitoring of the levels of natural and artificial radioactivity in those environments is important for the assessment of radiological risks in order to protect those organisms and the environment in general.
The data used for this study will be available from the corresponding author upon request.
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Open access funding provided by The Science, Technology & Innovation Funding Authority (STDF) in cooperation with The Egyptian Knowledge Bank (EKB).
Physics Department, Faculty of Science, South Valley University, Qena, 83523, Egypt
K. Salahel Din, N. K. Ahmed & A. Abbady
Health Ministry Labs, Qena Branch, Egypt
F. M. Abdallah
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F.M. and A.A collected and prepared the samples for measurements as well as performed the laboratory measurements. F.M., N.K and K.S. performed data analysis. K.S. was writing the draft manuscript. All authors read and approved the final manuscript.
Correspondence to K. Salahel Din.
The authors declare no competing interests.
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Din, K.S., Ahmed, N.K., Abbady, A. et al. Exposure of aquatic organisms to natural radionuclides in irrigation drains, Qena, Egypt. Sci Rep 13, 413 (2023). https://doi.org/10.1038/s41598-023-27594-4
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DOI: https://doi.org/10.1038/s41598-023-27594-4
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