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Recently there have been a few studies on MPs pollution in India but most of these studies are on coastal or marine sediments (Jayasiri et al. 2013; Reddy et al. 2006; Robin et al. 2020; Suman et al. 2020) and studies on fresh water environments are almost non‐existent (Table 2.1). Owens & Kamil (2020) carried out a study of plastic pollution in a river in Kerela, India (Karamana River) and Indonesia (Tukad Badung River).

      In one of the first reports on MPs in the freshwater environments in India, Sruthy & Ramasamy (2017) studied the sediments of Vembanad Lake, a Ramsar site in India with low‐density polythene dominating the sediment samples. The authors pointed out that as the locals consume the aquatic fishes and clams from this lake, the fate of MPs entering humans via the food web is a potential threat. Ram & Kumar (2020) studied MPs from Sabarmati River sediments, where they reported that higher amount of MPs were observed in the river in areas near landfill sites from where the surface runoff might have carried the plastic debris to the river. Sarkar et al. (2019) estimated distribution of meso‐ and microplastics in the sediments of the lower reaches of the river Ganga, where they observed a relation between MPs abundance and other water quality parameters such as BOD. Karthik et al. (2018) studied MPs particles at beaches along the southeast coastal region of India, where they found the highest abundance of MPs on beaches adjacent to the river mouth. They also found the MPs in 10.1% of the 79 fishes they studied. Reddy et al. (2006) reported the observed plastic debris in the marine sediments on the coast of Gujarat, and a group of researchers reported plastic particles in the beaches of Mumbai (Jayasiri et al. 2013). Veerasingam et al. (2016) studied the MPs in surface sediments along the Chennai coast during March 2015 (pre‐Chennai flood) and November 2015 (post‐Chennai flood) and found that the MPs in the sediments increased threefold in post flooding, which may be due to huge input of MPs through the Cooum and Adyar rivers during the flood. This study highlights the importance of rivers as sources of plastic pollution to the marine environment.

Sl. No. Location Average concentration Method Sample type Size Polymer type References
1 River Ganga 11.48–63.79 ng/g FT‐IR Sediments 63–850 μm, 850 μm–5 mm PET, PE Sarkar et al. (2019)
2 Sabarmati River 134.53–581.70 mg/kg SEM Sediments 4 mm–75 μm Plastic debris and fibers Ram & Kumar (2020)
3 Vembanad Lake 0.27 g/l Raman Sediments 0.2–1 mm Sruthy & Ramasamy (2017)
4. Netravathi River 288 pieces/m3 (water), 96 pieces/kg (sediment) 84.45 pieces /kg (soil) Water, sediments, and soil 5–0.3 mm PE, PET Amrutha & Warrier (2020)

      Although the awareness of plastic pollution is increasing, the knowledge of the scale and severity of impacts on humans and ecosystems is limited. With the growing awareness of the potential threat and subsequent consequences of plastic pollution to human populations, more detailed investigations of these emerging pollutants are needed for effective management action and risk assessment to reduce the detrimental social, ecological, and economic impacts. Detailed studies on qualitative and quantitative estimation of macro‐ and microplastics with strong focus on predicting current and future trends across spatial and temporal scales, using portable sensors, etc., is imperative to address the global plastic wastes. Together with a detailed understanding and quantification of the origins, transport pathways, fluxes, and fate of these emerging pollutants, urgent steps to manage plastic wastes such as making laws banning plastic littering more stringent, providing for plastic waste management infrastructure, and making waste segregation at source mandatory, are required to determine and reduce the risks to marine ecosystem as well as all other ecosystems and humans as a whole.

      1 Alam, F.C., Sembiring, E., Muntalif, B.S., and Suendo, V. (2019). Microplastic distribution in surface water and sediment river around slum and industrial area (case study: Ciwalengke River, Majalaya district, Indonesia). Chemosphere 224: 637–645.

      2 Alimi, O.S., Farner Budarz, J., Hernandez, L.M., and Tufenkji, N. (2018). Microplastics and nanoplastics in aquatic environments: aggregation, deposition, and enhanced contaminant transport. Environmental Science & Technology 52 (4): 1704–1724.

      3 Amrutha, K. and Warrier, A.K. (2020). The first report on the source‐to‐sink characterization of microplastic pollution from a riverine environment in tropical India. Science of the Total Environment 739: 140377.

      4 Andrady,

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