IntroductionIn recent years, metal

Introduction
In recent years, metal contamination in the aquatic environment has attracted global attention owing to its environmental toxicity, abundance and persistence (Sin et al., 2001, Armitage et al., 2007 and Yuan et al., 2011). Large quantities of hazardous chemicals especially heavy metals have been released into rivers worldwide due to global rapid population growth and intensive domestic activities, as well as expanding industrial and agricultural production (Srebotnjak et al., 2012, Su et al., 2013 and Islam et al., 2014). Rivers in urban areas have also been associated with water quality problems because of the practice of discharging of untreated domestic and industrial waste into the water bodies which leads to the increase in the level of metals in river water (Khadse et al., 2008 and Venugopal et al., 2009).

The behavior of metals in the natural water is a function of the substrate sediment composition, the suspended sediment composition, and the water chemistry (Mohiuddin et al., 2012). During transport, heavy metals may undergo numerous changes in their speciation due to dissolution, precipitation, sorption, and complexation phenomena (Dassenakis et al., 1998, Akcay et al., 2003 and Abdel-Ghani and Elchaghaby, 2007), which affect their behavior and bioavailability (Nicolau et al., 2006 and Nouri et al., 2011). Sediment is an integral and dynamic part of the river basin, with the variety of habitats and environments. However, information on total metal concentrations is not sufficient for the assessment of environmental impact of sediment contamination which lead to the particular interest of chemical fractionation of sediment (Jain, 2004 and Nwuche and Ugoji, 2010). The overall behavior of heavy metals in the aquatic environment is strongly influenced by the association of metals with various geochemical phases in sediments (Morillo et al., 2004). Geochemical speciation and distribution of metals in the defined chemical fraction also been used in predicting the potential contamination, mobility and bioavailability (Kabala and Singh, 2001, Pueyo et al., 2003 and Caeiro et al., 2005). Thus, it is important to assess the concentrations and distribution of heavy metals in the riverine ecosystem.

In Bangladesh, everyday a huge amount of untreated industrial wastes is being discharged into open water bodies and its adjacent lands. Besides, a considerable amount of heavy metal enriched suspended solids is coming down from neighboring country like India through the Teesta and the Brahmaputra Rivers. Bogra district, known as the northern capital of Bangladesh is situated on the bank of the river Korotoa which is connected to the river Teesta and Brahmaputra. The study river recently has been raised attention to public concern due to its extreme pollution. To date, no scientific research regarding heavy metal issues in the study area has been conducted so far. Therefore, the objectives of this study are – to assess the pollution status of the river Korotoa by estimating the levels of heavy metals in water and sediment, and to observe the metal enrichment in relation to chemical speciation in sediments.