Assessment of Environmental Hazard and Heavy Metal Contamination in Dhaleshwari River Sediment: A Toxicity based Study on Pollution

Document Type : Original Research Paper

Authors

1 Department of Civil Engineering, University of Asia Pacific, Dhaka 1205, Bangladesh

2 Department of Soil, Water and Environment, Dhaka University, Dhaka 1000, Bangladesh

3 Department of Environmental Science and Management, North South University, Dhaka 1229, Bangladesh

10.22059/poll.2022.342243.1455

Abstract

Developing nations, such as Bangladesh, face an enormous crisis in maintaining natural sustainability due to heavy metal contamination by the peripheral rivers. Frequent heavy metals discharged from tanneries, dyeing, and potential anthropogenic activities in Savar city pollute the Dhaleshwari river, which is an important river of the capital city, Dhaka. The present study aimed to assess the heavy metals contamination in the Dhaleshwari river sediment and evaluate the subsequent ecological risk indices emerging from the deposits. The contamination levels of heavy metals such as lead (Pb), cadmium (Cd), chromium (Cr), and nickel (Ni) were analyzed in the Dhaleshwari River sediment. Various environmental indices, such as Potential Enrichment Risk (PER), Geo-accumulation Index (Igeo), Enrichment factor (EF), Toxic unit analysis (TUs), etc., were observed in various compartments. The concentration of heavy metals ranged as follows: Lead (Pb), 297.3-414.6 mg/L; Cadmium (Cd), 1.5-4.4 mg/L; chromium (Cr), 97.9 -282.4 mg/L; Nickle (Ni), 85.1-264.5 mg/L; Iron (Fe), 11800-14375 mg/L. The metal concentrations were higher than the threshold effect level (TEL) and probable effect level (PEL) standards. Based on the TUs, the probability of toxicity is about 76% (TU > 2.3) at the Dhaleshwari river. Comparative evaluation of different environmental indices between present and past studies indicated progressive deterioration of sediments by heavy metals. Linear correlations of heavy metals in sediment samples demonstrated toxic accumulation of heavy metals in the surrounding ecosystem. The study outcomes emphasize the necessity of systematic investigation in the Dhaleshwari river and warranting effective prioritization to ensure river health over industrial wastewater discharge.

Keywords


Abrahim, G. (2005). Holocene sediments of Tamaki Estuary: Characterisation and impact of recent human activity on an urban estuary in Auckland, New Zealand.
Alam, K. (2003). Cleanup of the Buriganga river: Integrating the environment into decision making (Doctoral dissertation, Murdoch University).
Ahmed, M. K., Ahamed, S., Rahman, S., Haque, M. R., and Islam, M. M. (2009). Heavy metals concentration in water, sediments and their bioaccumulations in some freshwater fishes and mussel in Dhaleshwari River, Bangladesh. Terr Aquat Environ Toxicol, 3(1), 33-41.
ATSDR, T. (2000). ATSDR (Agency for toxic substances and disease registry). Prepared by clement international corp., under contract, 205, 88-0608.
Ayangbenro, A. S. and Babalola, O. O. (2017). A new strategy for heavy metal polluted environments: a review of microbial biosorbents. International journal of environmental research and public health, 14(1), 94.
Bai, J., Cui, B., Chen, B., Zhang, K., Deng, W., Gao, H. and Xiao, R. (2011). Spatial distribution and ecological risk assessment of heavy metals in surface sediments from a typical plateau lake wetland, China. Ecological modelling, 222(2), 301-306.
Bastami, K. D., Bagheri, H., Haghparast, S., Soltani, F., Hamzehpoor, A. and Bastami, M. D. (2012). Geochemical and geo-statistical assessment of selected heavy metals in the surface sediments of the Gorgan Bay, Iran. Marine pollution bulletin, 64(12), 2877-2884.
Bhuyan, M. S., Bakar, M. A., Akhtar, A., Hossain, M. B., Ali, M. M. and Islam, M. S. (2017). Heavy metal contamination in surface water and sediment of the Meghna River, Bangladesh. Environmental nanotechnology, monitoring & management, 8, 273-279.
Caplat, C., Basuyaux, O., Pineau, S., Deborde, J., Grolleau, A. M., Leglatin, S. and Mahaut, M. L. (2020). Transfer of elements released by aluminum galvanic anodes in a marine sedimentary compartment after long-term monitoring in harbor and laboratory environments. Chemosphere, 239, 124720.
Das, K. K., Das, S. N. and Dhundasi, S. A. (2008). Nickel, its adverse health effects & oxidative stress. Indian journal of medical research, 128(4), 412.
Faisal, I. M., Kabir, M. R. and Nishat, A. (1999). Non-structural flood mitigation measures for Dhaka City. Urban water, 1(2), 145-153.
Förstner, U. (1987). Sediment-associated contaminants—an overview of scientific bases for developing remedial options. Hydrobiologia, 149(1), 221-246.
Ghrefat, H. and Yusuf, N. (2006). Assessing Mn, Fe, Cu, Zn, and Cd pollution in bottom sediments of Wadi Al-Arab Dam, Jordan. Chemosphere, 65(11), 2114-2121.
Guo, W., Liu, X., Liu, Z. and Li, G. (2010). Pollution and potential ecological risk evaluation of heavy metals in the sediments around Dongjiang Harbor, Tianjin. Procedia environmental sciences, 2, 729-736.
Hasan, M., Ahmed, M. and Adnan, R. (2020). Assessment of physico-chemical characteristics of river water emphasizing tannery industrial park: a case study of Dhaleshwari River, Bangladesh. Environmental Monitoring and Assessment, 192(12), 1-24.
Hakanson, L. (1980). An ecological risk index for aquatic pollution control. A sedimentological approach. Water research, 14(8), 975-1001.
Helen, D., Vaithyanathan, C., & Ramalingom Pillai, A. (2016). Assessment of heavy metal contamination and sediment quality of Thengapattinam estuary in Kanyakumari District. IJCPS, 5(1), 8-17.
Ian, H. (2010). An introduction to geographical information systems. Pearson Education India.
Islam, M. S., Ahmed, M. K., Habibullah-Al-Mamun, M., Islam, K. N., Ibrahim, M. and Masunaga, S. (2014). Arsenic and lead in foods: a potential threat to human health in Bangladesh. Food Additives & Contaminants: Part A, 31(12), 1982-1992.
Islam, M., Ahmed, M., Habibullah-Al-Mamun, M. and Hoque, M. (2015). Preliminary assessment of heavy metal contamination in surface sediments from a river in Bangladesh. Environmental earth sciences, 73(4), 1837-1848.
Islam, M. S., Proshad, R. and Ahmed, S. (2018). Ecological risk of heavy metals in sediment of an urban river in Bangladesh. Human and ecological risk assessment: an international journal, 24(3), 699-720.
Juel, M. A. I., Alam, M. S., Pichtel, J. and Ahmed, T. (2020). Environmental and health risks of metal-contaminated soil in the former tannery area of Hazaribagh, Dhaka. SN Applied Sciences, 2(11), 1-17.
Luo, W., Lu, Y., Giesy, J. P., Wang, T., Shi, Y., Wang, G. and Xing, Y. (2007). Effects of land use on concentrations of metals in surface soils and ecological risk around Guanting Reservoir, China. Environmental geochemistry and health, 29(6), 459-471.
Majed N. and Islam MAS. (2022). Contaminant discharge from outfalls and subsequent aquatic ecological risks in the river systems in Dhaka city: Extent of waste load contribution in pollution. Front. Public Health, 10:880399.
Majed, N., Real, M. I. H., Redwan, A. and Azam, H. M. (2022). How dynamic is the heavy metals pollution in the Buriganga River of Bangladesh? A spatiotemporal assessment based on environmental indices. International Journal of Environmental Science and Technology, 19(5), 4181-4200.
Maleva, M. G., Malec, P., Prasad, M. N. V. and Strzałka, K. (2016). Kinetics of nickel bioaccumulation and its relevance to selected cellular processes in leaves of Elodea canadensis during short-term exposure. Protoplasma, 253(2), 543-551.
MacDonald, D. D., Ingersoll, C. G. and Berger, T. A. (2000). Development and evaluation of consensus-based sediment quality guidelines for freshwater ecosystems. Archives of environmental contamination and toxicology, 39(1), 20-31.
Mucha, A. P., Vasconcelos, M. T. S. and Bordalo, A. A. (2003). Macrobenthic community in the Douro estuary: relations with trace metals and natural sediment characteristics. Environmental pollution, 121(2), 169-180.
Mohanta, L. C., Niloy, M. N. H., Chowdhury, G. W., Islam, D. and Lipy, E. P. (2019). Heavy metals in water, sediment and three fish species of Dhaleshwari river, Savar. Bangladesh Journal of Zoology, 47(2), 263-272.
Mohiuddin, K. M., Ogawa, Y. Z. H. M., Zakir, H. M., Otomo, K. and Shikazono, N. (2011). Heavy metals contamination in water and sediments of an urban river in a developing country. International journal of environmental science & technology, 8(4), 723-736.
Mmolawa, K. B., Likuku, A. S. and Gaboutloeloe, G. K. (2011). Assessment of heavy metal pollution in soils along major roadside areas in Botswana. African Journal of Environmental Science and Technology, 5(3), 186-196.
Mwamburi, J. (2003). Variations in trace elements in bottom sediments of major rivers in Lake Victoria’s basin, Kenya. Lakes & Reservoirs: Research & Management, 8(1), 5-13.
Mizan, A., Zohra, F. T., Ahmed, S., Nurnabi, M. and Alam, M. Z. (2016). Low cost adsorbent for mitigation of water pollution caused by tannery effluents at Hazaribagh. Bangladesh Journal of Scientific and Industrial Research, 51(3), 215-220.
Pekey, H., Karakaş, D., Ayberk, S., Tolun, L. and Bakoǧlu, M. (2004). Ecological risk assessment using trace elements from surface sediments of Izmit Bay (Northeastern Marmara Sea) Turkey. Marine pollution bulletin, 48(9-10), 946-953.
Puyate, Y. T., Rim-Rukeh, A. and Awatefe, J. K. (2007). Metal pollution assessment and particle size distribution of bottom sediment of Orogodo River, Agbor, Delta State, Nigeria. J. Appl. Sci. Res, 3(12), 2056-2061. 
Rahman, M. J., Wahab, M. A. and Meisner, C. A. (2015). ECOFISHBD Project: A joint initiative of government-nongovernment-donor for hilsa and other fisheries resources conservation, productivity improvement and strengthening fishers capacity. National Fish Week, 116-118.
Rahman, K., Barua, S., Alam, S. and Alam, A. (2020). Ecological Risk Assessment of Heavy Metals concentration in Sediment of the Shitalakhya River. Int. J. Sci. Res. in Multidisciplinary Studies Vol, 6(6).
Reboredo, F. (1993). How differences in the field influence Cu, Fe and Zn uptake by Halimione portulacoides and Spartina maritima. Science of the total environment, 133(1-2), 111-132.
Ruiz, F. (2001). Trace metals in estuarine sediments from the southwestern Spanish coast. Marine Pollution Bulletin, 42(6), 481-489.
Sayadi, M. H., Sayyed, M. R. G. and Kumar, S. (2010). Short-term accumulative signatures of heavy metals in river bed sediments in the industrial area, Tehran, Iran. Environmental monitoring and assessment, 162(1), 465-473.
Shanbehzadeh, S., Vahid Dastjerdi, M., Hassanzadeh, A. and Kiyanizadeh, T. (2014). Heavy metals in water and sediment: a case study of Tembi River. Journal of environmental and public health, 2014.
United States. Environmental Protection Agency. Office of Emergency, and Remedial Response. (1989). Risk assessment guidance for superfund. Office of Emergency and Remedial Response, US Environmental Protection Agency.
Varol, M. (2011). Assessment of heavy metal contamination in sediments of the Tigris River (Turkey) using pollution indices and multivariate statistical techniques. Journal of hazardous materials, 195, 355-364.
Wakida, F. T., Lara-Ruiz, D., Temores-Pena, J., Rodriguez-Ventura, J. G., Diaz, C. and Garcia-Flores, E. (2008). Heavy metals in sediments of the Tecate River, Mexico. Environmental Geology, 54(3), 637-642.
World Health Organization, and Światowa Organizacja Zdrowia. (2004). World report on knowledge for better health: strengthening health systems. World Health Organization.
Xiao, R., Bai, J., Gao, H., Wang, J., Huang, L. and Liu, P. (2012). Distribution and contamination assessment of heavy metals in water and soils from the college town in the Pearl River Delta, China. CLEAN–Soil, Air, Water, 40(10), 1167-1173.
Zhang, H. and Shan, B. (2008). Historical records of heavy metal accumulation in sediments and the relationship with agricultural intensification in the Yangtze–Huaihe region, China. Science of the Total Environment, 399(1-3), 113-120.