The existence of heavy metal pollutants in fish within aquatic ecosystems presents a threat to human health due to trophic shift. This research sought to identify the concentrations of cadmium (Cd), arsenic (As), copper (Cu), lead (Pb), and chromium (Cr) in two economically significant cultured fish species, pangus (Pangasius hypophthalmus) and catla (Labeo catla), which were sourced from key fish markets in Khulna, Bangladesh. Nevertheless, there has been a scarcity of studies addressing the metal concentrations in these species within this region. To evaluate the levels of trace elements, atomic absorption spectrophotometry (AAS) was employed following the acid digestion of the samples. The concentrations of Cd, As, Cu, Pb, and Cr were observed as 0.372, 0.232, 0.741, 0.758, and 1.356 mg/kg in pangus and 0.395, 0.297, 1.175, 0.616, and 0.959 mg/kg in catla fish, respectively. The concentrations of Pb and Cd exceeded the maximum permissible limits established by the FAO and WHO. Apart from Cu, the estimated daily intakes (EDI) for both seasons and age groups exceeded the recommended daily allowance (RDA), indicating that other trace elements could be detrimental to human health. In contrast, the calculated hazard index (HI) and total hazard quotient (THQ) remained below 1, suggesting that the fish examined would not pose health risks to adults but the HI value for children surpassed the acceptable limit. Moreover, Cd (for adult group) and Cd and Cr (for children group) surpassed the acceptable range for carcinogenic risk (CR), and the total carcinogenic risk (TCR) exceeded the permissible limit for both groups. This study concluded that studied fishes may represent a health risk for consumers, underscoring the necessity for ongoing monitoring of trace elements in other fish species within that catchment area.
Nanocellulose, a promising green material derived from various bio-sources, has potentiality on and off-site in the agricultural sector. Due to its special qualities, which include high strength, hydrophilicity, and biocompatibility, it is a material that may be used in a variety of industries, especially agriculture. This review explores in this article production processes, post-processing procedures, and uses of nanocellulose in soil fertility increment and sustainable agriculture. A variety of plant materials, agricultural waste, and even microbes can be used to isolate nanocellulose. Nanocellulose is produced using both top-down and bottom-up methods, each of which has benefits and limitations of its own. It can be applied as nano-biofertilizer in agriculture to enhance beneficial microbial activity, increase nutrient availability, and improve soil health. Moreover, nanocellulose can be used in fertilizer and pesticide formulations with controlled releases to increase efficacy and lessen environmental effects. Innovative approaches to sustainable agriculture are provided by nanocellulose technologies, which also support the UN's Sustainable Development Goals (SDGs), especially those pertaining to eradicating hunger and encouraging responsible consumption. Nanocellulose promotes climate action and ecosystem preservation by increasing resource efficiency and decreasing dependency on hazardous chemicals, ultimately leading to the development of a circular bioeconomy. Nonetheless, there are still issues with the high cost of production and the energy-intensive isolation procedures. Despite its various potentialities, challenges such as high production costs, environmental concerns, and regulatory issues must be addressed for nanocellulose to be widely adopted and effectively integrated into farming practices.