Trace metal exposure and health concerns in Bangladeshi rivers: a seasonal comparison of the Buriganga, Shitalakhya, Meghna, Karnaphuli, and Padma rivers' water, sediment, and fish

Document Type : Original Research Paper

Authors

1 Institute of Leather Engineering and Technology, University of Dhaka, Dhaka-1209, Bangladesh

2 Stockholm University, Sweden

3 Unversity of Babes- Bolyai, Romania

4 Southern Illinois University Carbondale, 1230 Lincoln Drive, Carbondale-62901, IL, USA

5 Department of Architecture, Chittagong University of Engineering &Technology, Chittagong-4349, Bangladesh

6 Atomic Energy Centre, Chattogram, Bangladesh Atomic Energy Commission, Chattogram 4209, Bangladesh

Abstract

We determined the levels of nine heavy elements in water, sediment, and the edible tissues of three frequently eaten fish species collected from the five polluted rivers in different divisions of Bangladesh. These samples were randomly taken from five rivers and analyzed by Flame Atomic Absorption Spectroscopy. We found seasonal fluctuations in the hierarchy of mean concentration for different heavy metals in five rivers’ fish, water, and sediments. In the water, the concentrations of Cd, Cr, Cu, Fe, Mn, Pb, Zn, Ni, and Hg ranged from 0.010-0.081, 0.016-5.531, 0.013-2.445, 0.860-22.924, 0.043-1.424, 0.015-0.933, 0.091-1.451, 0.012-2.888, and 0.010-0.032 mg/l where in the sediment the concentrations ranged from 0.1-1.47, 4.21-284.1, 0.12-28.46, 1860-14971.33, 122.1-480.8, 0.84-42.15, 2.14-210.35, 15.3-30.4, and 0.17-10.44 mg/kg. For fishes concentrations ranging from BDL-0.78, 0.04-86.45, 0.01-1.67, 4.19-102, 0.08-0.94, 0.01-0.99, 0.08-9.56, 0.01-4.56, and BDL-0.2 mg/kg were reported for the above metals order respectively. The highest concentration (mean) of Cr and Fe in waters and sediments was 1023 times and 13020.72 % higher than WHO’s standard and Toxicity Reference Values (TRV), respectively. Besides, the bioaccumulation factors (BAF) of the selected elements for the studied fishes were found to be between 0.036-626.25, where the pollution load index (PLI) for the five rivers ranged from 0-0.95 and the concentration factor (CF) found between 0.02-4.03. Estimated daily Intake (EDI) as well as Target hazard quotients (THQs) analyses revealed potential risks for fish consumers, particularly the level of some metals exceeding the WHO/FAO's tolerable limit, which indicates that the rivers' water and fish are dangerous to humankind.

Keywords

Main Subjects


Adolf, L.(1960). “Recommended Dietary Allowances.” Nutrition Reviews, 18(7); 203–5. doi: 10.1111/j.1753-4887.1960.tb01770.x.
Ahamad, M.I., Song, J., Sun, H., Wang, X., Mehmood, M.S., Sajid, M., Su, P., & Khan, A.J. (2020). Contamination level, ecological risk, and source identification of heavy metals in the hyporheic zone of the Weihe River, China. International journal of environmental research and public health, Feb17(3);1070.
Alhashemi, A.H., Sekhavatjou, M.S., Kiabi, B.H., & Karbassi, A.R.(2012). Bioaccumulation of trace elements in water, sediment, and six fish species from a freshwater wetland, Iran. Microchemical Journal, 104; 1-6.
Alhashemi, H., Karbassi, A., Kiabi, H.,Monavari, S.M., & Sekhavatjou, M.S.(2012). Bioaccumulation of trace elements in different tissues of three commonly available fish species regarding their gender, gonadosomatic index, and condition factor in a wetland ecosystem. Environmental Monitoring and Assessment, 184; 1865-1878.
Alhashemi, H., Karbassi, A.S., Hassanzadeh, A.R., Kiabi, B., Monavari, S.M., Nabavi, S.M.B., & Sekhavatjou, M.S.(2011). Bioaccumulation of trace elements in trophic levels of wetland plants and waterfowl birds. Biological trace element research, 142; 500-516.
Baki, M.A., Shojib, M.F., Sehrin, S., Chakraborty, S., Choudhury, T.R., Bristy, M.S., Ahmed, M.K., Yusoff, S.B., & Khan, M.F. (2020) Health risk assessment of heavy metal accumulation in the Buriganga and Turag River systems for Puntius ticto, Heteropneustes fossilis, and Channa punctatus. Environmental geochemistry and health, Feb42; 531-43.
BDWS, (Bangladesh Dringking Water Standards). (1997). “The Environment Conservation Rules, 1997.” Bangladesh Department of Environment, Ministry of Environment and Forest, Government of the People’s Republic of Bangladesh; 179–227.
Bhuiyan, M.A.H. Dampare, S.B. Islam, M.A. Suzuki, S. (2015). Source apportionment and pollution evaluation of heavy metals in water and sediments of Buriganga River, Bangladesh, using multivariate analysis and pollution evaluation indices, Environmental Monitoring Assessment, 187(2015); 222-236
Bhuyan, M.S., Bakar, M.A., Akhtar, A., Hossain, M.B., & Islam, M.S.(2017). Analysis of water quality of the Meghna River using multivariate analyses and RPI. Journal of the Asiatic Society of Bangladesh, Science. Jun 20; 43(1); 23-35.
Braulik, G., Atkore, V., Khan, M.S., & Malla, S. (2021). Review of Scientific Knowledge of the Ganges river dolphin. WWF, commissioned by the World Bank. 
Cenci, R.M., & Martin, J.M. (2004). Contamination and fate of heavy metals in Mekong River Delta. Science of the total Environment. Oct 1; 332 (1-3); 167-82.
Duncan, A.E., de Vries, N., & Nyarko, K.B. (2018). Assessment of heavy metal pollution in the sediments of the River Pra and its tributaries. Water, Air, & Soil Pollution. Aug; 229;1-0.
Duruibe, O.J., Ogwuegbu, M.O.C., & Egwurugwu, J.N. (2007). “Heavy Metal Pollution and Human Biotoxic Effects.” International Journal of Physical Sciences, 2(5);112–18. Ekeanyanwu, C.R., Ogbuiny,i C.A., & Etienajirhevwe, O.F. (2010).Heavy metals distribution in fish tissues, bottom sediments and water from Okumeshi River in Delta State, Nigeria. Ethiopian Journal of Environmental Studies and Management. 2010; 3(3).
Facetti, J., Dekov, V.M., & Van,Grieken. R. (1998). Heavy metals in sediments from the Paraguay River: a preliminary study. Science of the total environment. 1998 Jan 8; 209 (1); 79-86.
FAO (1983). “Compilation of Legal Limits for Hazardous Substances in Fish and Fishery Product.” Library 746;104.
Gupta, A., Rai, D.K., Pandey, R.S., & Sharma, B. (2009). Analysis of some heavy metals in the riverine water, sediments and fish from river Ganges at Allahabad. Environmental monitoring and assessment. 2009 Oct;157; 449-58.
Haque, M.R., Ali, M.M., Ahmed, W., Siddique, M.A., Akbor, M.A., Islam, M.S., & Rahman, M.M. (2023). Assessment of microplastics pollution in aquatic species (fish, crab, and snail), water, and sediment from the Buriganga River, Bangladesh: An ecological risk appraisals. Science of the Total Environment. 2023 Jan 20; 857; 159344.
Heikens, A. (2006). Arsenic contamination of irrigation water, soil and crops in Bangladesh: Risk implications for sustainable agriculture and food safety in Asia. Rap Publication (FAO). 2006.
Hossain, M.N., Rahaman, A., Hasan, M.J., Uddin, M.M., Khatun, N., & Shamsuddin, S.M. (2021). Comparative seasonal assessment of pollution and health risk associated with heavy-metals in water, sediment and fish of Buriganga and Turag River in Dhaka city. Bangladesh SN Applied Science, 3(3); 509
Islam, M.S., Ahmed, M.K., & Habibullah, A.M.M. (2015). Determination of heavy metals in fish and vegetables in Bangladesh and health implications. Human and Ecological Risk Assessment: An International Journal. 2015 May 19; 21(4); 986-1006.
Islam, M.S., Ahmed, M.K., Raknuzzaman, M., Habibullah, A.M.M., & Islam, M.K. (2015). Heavy metal pollution in surface water and sediment: a preliminary assessment of an urban river in a developing country. Ecological indicators. 2015 Jan 1; 48; 282-91.
Islam, M.S., Chowdhury, M.A., Billah, M.M., Tusher, T.R., & Sultana, N. (2012). Investigation of effluent quality discharged from the textile industry of Purbani group, Gazipur, Bangladesh and its management. Bangladesh Journal of Environmental Science. 2012; 23; 123-30.
Islam, M.S., Han, S., Ahmed, M.K., & Masunaga, S. (2014). Assessment of heavy metal contamination in water and sediment of some rivers in Bangladesh. Journal of water and environment technology. 2014; 12 (2); 109-21.
Islam, M.S., Kabir, M.H., Sifat, S.A., Meghla, N.T., & Tusher, T.R. (2014). Status of water quality from the Padma river at Bheramara point of Kushtia in Bangladesh. Bangladesh Journal of Environmental Science. 2014; 27; 110-5.
Jalali, J.B., & Agazade, M. (2007).“Fish Intoxication Heavy Metals and Its Significance on Public Health.” Maane Ketab Pub. 2007.
JRC, Van-Duijn. (1828). “Diseases of Fishes.” The Lancet 9(231); 651. doi: 10.1016/S0140-6736(02)97064-9.
Kamal, M.M., Malmgren-Hansen, A., & Badruzzaman, A.B. (1999). Assessment of pollution of the River Buriganga, Bangladesh, using a water quality model. Water science and technology. 1999 Jan 1; 40 (2); 129-36.
Karbassi, S., Nasrabadi, T., & Shahriari, T.(2016). Metallic pollution of soil in the vicinity of National Iranian Lead and Zinc (NILZ) Company. Environmental Earth Sciences, 75; 1-11.
Khalid, A.R. (2004). The interlinking of rivers project in India and International water law: an overview. Chinese J. Int’l L. 2004; 3; 553.
Khatun, N., Hossain, M.N., Islam, M.D., & Rahaman, A. (2023). Hazard Estimations Result from Arsenic Contamination in Common Foodstuffs, Soil, Sediment, and Water of Joypurhat District, Bangladesh. Pollution. 2023 Feb 1; 9(2); 531-44.
Khatun, N., Nayeem, J., Deb, N., Hossain, S., & Kibria, M.M. (2021). Heavy metals contamination: possible health risk assessment in highly consumed fish species and water of Karnafuli River Estuary, Bangladesh. Toxicology and Environmental Health Sciences. 2021 Dec;13(4); 375-88.
Li, H., Shi, A., Li, M., & Zhang, X. (2013). Effect of pH, temperature, dissolved oxygen, and flow rate of overlying water on heavy metals release from storm sewer sediments. Journal of Chemistry. 2013 Aug; 2013.
Loska, K., Cebula, J., Pelczar, J., Wiechuła, D., & Kwapuliński, J. (1997). Use of enrichment, and contamination factors together with geoaccumulation indexes to evaluate the content of Cd, Cu, and Ni in the Rybnik water reservoir in Poland. Water, Air, and Soil Pollution. 1997 Jan; 93; 347-65.
Lu, Y., Song, S., Wang, R., Liu, Z., Meng, J., Sweetman, A.J., Jenkins, A., Ferrier, R.C., Li, H., Luo, W., & Wang, T. (2015). Impacts of soil and water pollution on food safety and health risks in China. Environment international. 2015 Apr 1;77; 5-15.
Mendil D, Ünal O.F., Tüzen, M., & Soylak, M. (2010). Determination of trace metals in different fish species and sediments from the River Yes_ilirmak in Tokat, Turkey. Food and Chemical Toxicology, 48 (2010); 1383–1392
Mohiuddin, K., Alam, M., Ahmed, I., & Chowdhury, A. (2016). Heavy metal pollution load in sediment samples of the Buriganga river in Bangladesh. Journal of Bangladesh Agricultural University, 13 (2016); 229–238.
Mohiuddin, K.M., Otomo, K., Ogawa, Y., & Shikazono N. (2012). Seasonal and spatial distribution of heavy elements in the water and sediments of the Tsurumi River in Japan. Environmental monitoring and assessment. 2012 Jan;184; 265-79.
Nasrabadi, T., & Bidabadi, N.S.(2013). Evaluating the spatial distribution of quantitative risk and hazard level of arsenic exposure in groundwater, case study of Qorveh County, Kurdistan Iran. Iranian Journal of Environmental Health Science and Engineering, 10; 1-8.
Nasrabadi, T., Abbasi Maedeh, P., Sirdari, Z.Z., ShiraniBidabadi, N., Solgi, S., & Tajik, M.(2015). Analyzing the quantitative risk and hazard of different waterborne arsenic exposures: case study of Haraz River, Iran. Environmental earth sciences, 74; 521-532.
Nasrabadi, T., Ruegner, H., Schwientek, M., Bennett, J., Fazel Valipour, S., & Grathwohl, P. (2018). Bulk metal contaminations versus total suspended solids in rivers: Time-invariant & catchment-specific relationships. PloS one, 13(1); p.e0191314.
Persaud, D., Jaagumagi, R., & Hayton, A. (1993). “Guidelines for the Protection and Management Of.” Aquatic Sediment Quality in Ontário, Water Resources Branch, Ontario Ministry of the Environmental Toronto,.Jan; 73; 347-65.
Rahman, K., Barua, S., Ahammad, F., & Alam, M.A. (2020). Assessment of pollution and sources of heavy metals in the sediments of the Shitalakhya river, Bangladesh. International Journal of Advance Geoscience, 2020; 8 (1); 89-94.
Rahman, M.B., Islam, M.M., Ruma, M., & Rahman, M.M. (2020). Effects of environmental condition on spatial-temporal changes of fish diversity and morphology of Shitalakshya River. Ecologia. 2020; 10(1); 38-49.
Rahman, M.S., Saha, N., & Molla, A.H. (2014). Potential ecological risk assessment of heavy metal contamination in sediment and water body around Dhaka export processing zone, Bangladesh. Environmental earth sciences. 2014 Mar;71; 2293-308.
Rajendran, S., Priya, T.A., Khoo, K.S., Hoang, T.K., Ng, H.S., Munawaroh, H.S., Karaman, C., Orooji, Y., & Show, P.L. (2022). A critical review on various remediation approaches for heavy metal contaminants removal from contaminated soils. Chemosphere. 2022 Jan 1; 287; 132369.
Rao, L.M., & Padmaja, G. (2000). Bioaccumulation of heavy metals in M. cyprinoids from the harbor waters of Visakhapatnam. Bull Pure Appl Sci. 2000; 19(2); 77-85.
Report, TBS. (2019). “Savar Tannery ETP Stuck by a String | The Business Standard.” The Business Standard.
Suresh, G., Sutharsan, P., Ramasamy, V., & Venkatachalapathy, R. (2012). Assessment of spatial distribution and potential ecological risk of the heavy metals in relation to granulometric contents of Veeranam lake sediments, India. Ecotoxicology and environmental safety. 2012 Oct 1; 84; 117-24.
Tao, Y., Yuan, Z., Xiaona, H., & Wei, M. (2012). Distribution and bioaccumulation of heavy metals in aquatic organisms of different trophic levels and potential health risk assessment from Taihu lake, China. Ecotoxicology and Environmental Safety. 2012 Jul 1; 81; 55-64.
Tomlinson, D.L., Wilson, J.G., Harris, C.R., & Jeffrey, D.W. (1980). Problems in the assessment of heavy-metal levels in estuaries and the formation of a pollution index. Helgoländermeeresuntersuchungen. 1980 Mar; 33; 566 -75.
Turekian, K.K., & Wedepohl, K.H. (1961). Distribution of the elements in some major units of the earth’s crust. Geological society of America bulletin. 1961 Feb 1; 72 (2):175-92.
Uddin M.J and Jeong Y.K. (2021). Urban river pollution in Bangladesh during last 40 years: potential public health and ecological risk, present policy, and future prospects toward smart water management. Heliyon7 (2); (2021); e06107
Uddin, M., Kormoker, T., Siddique, M.A., Billah, M.M., Rokonuzzaman, M., Al Ragib, A., Proshad, R., Hossain, M.Y., Haque, M.K., Ibrahim, K.A., & Idris, A.M. (2023). An overview on water quality, pollution sources, and associated ecological and human health concerns of the lake water of megacity: a case study on Dhaka city lakes in Bangladesh. Urban Water Journal. 2023 Mar 16; 20(3); 261-77.
UN. (2017). “Goal 6: Clean Water and Sanitation in The Sustainable Development Goals Report.” United Nations 60.
USEPA, December (1989) “Risk Assessment Guidance for Superfund.” Human Health Evaluation Manual Part A I(202).
USEPA. (2001). “Methods for Collection, Storage and Maripulation of Sediment for Chemical and Toxicological Analyses: Technical Manual.” (October).
USFDA (1993). United States Food and Drug Administration, Guidance Document for Chromium in Shell Fish. DHHS/PHS/FDA/CFSAN/Office of Seafood, Washington DC.
WHO. World Health Organization. (2005). “Evaluation of Certain Food Additives : Sixty-Third Report of the Joint FAO/WHO Expert Committee on Food Additives.” 157.
Yahaya, M.I., Mohammad, S., & Abdullahi, B.K. (2009). Seasonal variations of heavy metals contamination in abattoir dumping site soil in Nigeria. Journal of Applied Sciences and Environmental Management. 2009; 13(4).
Yasasve, M., Manjusha, M., Manojj, D., Hariharan, N.M., Preethi, P.S., Asaithambi, P., Karmegam, N., & Saravanan, M. (2022). Unravelling the emerging carcinogenic contaminants from industrial waste water for prospective remediation by electrocoagulation–a review. Chemosphere. 2022 Aug 14:136017.
Zolitschka, B., Francus, P., & Ojala, A.E. (2015). Schimmelmann A. Varves in lake sediments–a review. Quaternary Science Reviews. 2015 Jun 1;117:1-41.