Risk assessment of trace element accumulation in soil and Brassica oleracea after wastewater irrigation.
Ali Haider ShahMuhammad ShahidMaria TahirNatasha NatashaIrshad BibiTasveer Zahra TariqSana KhalidMuhammad NadeemGhulam AbbasMuhammad Farhan SaeedSabah AnsarCamille DumatPublished in: Environmental geochemistry and health (2022)
The risk assessment of trace elements has received substantial attention for the achievement of UN Sustainable Developmental Goals (UN-SDGs). The present study aimed to evaluate health and ecological risks associated with trace element accumulation in Brassica oleracea under wastewater irrigations from three different areas. This study, for the first time, compared the pros and cons of mixed water crop irrigation (wastewater with fresh/groundwater). A pot experiment was conducted to evaluate the buildup of eight trace elements (As, Cu, Cd, Mn, Fe, Pb, Ni and Zn) in soil and B. oleracea plants irrigated with wastewater alone and mixed with fresh/groundwater. Specific ecological [degree of contamination (C d ), potential ecological risk index (PERI), pollution load index (PLI), geo-accumulation index (I geo )], phytoaccumulation [bioconcentration factor (BCF) and transfer factor (TF)] and health risk models [chronic daily intake (CDI), hazard quotient (HQ), cancer risk (CR)] were applied to assess the overall contamination of trace elements in the soil-plant-human system. Moreover, these indices were compared with the literature data. The concentration of Cd, Fe and Mn exceeded the threshold limits of 10, 500 and 200 mg kg -1 , respectively, for agricultural soil. Overall, all the irrigation waters caused significant pollution load in soil indicating high ecological risk (C d > 24, PERI > 380, Igeo > 5, PLI > 2). Not all the mixing treatments caused a reduction in trace element buildup in soil. The mixing of wastewater-1 with either groundwater or freshwater increased trace element levels in the soil as well as risk indices compared to wastewater alone. The BCF and TF values were > 1, respectively, for 66% and 7% treatments. Trace element concentration in plants and associated health risk were minimized in mixed wastewater treatments. There were 22% and 32% reduction in HQ and CR when wastewater was mixed with freshwater and 29% and 8% when mixed with groundwater. Despite total reduction, a great variation in % change in risk indices was observed with respect to the area of wastewater collection. Therefore, mixed water irrigation may be a good management strategy, but its recommendation depends on soil properties and composition of waters used for mixing. Moreover, it is recommended that the freshwater and wastewater of the particular area may be continuously monitored to avoid potential associated health hazards.
Keyphrases
- heavy metals
- human health
- risk assessment
- health risk
- wastewater treatment
- health risk assessment
- climate change
- anaerobic digestion
- drinking water
- plant growth
- healthcare
- metal organic framework
- machine learning
- social media
- water quality
- physical activity
- mental health
- electronic health record
- weight gain
- artificial intelligence
- air pollution
- working memory
- weight loss
- body mass index