Uptake Prediction of Eight Potentially Toxic Elements by Pistia stratiotes L. Grown in the Al-Sero Drain (South Nile Delta, Egypt): A Biomonitoring Approach

Eid, Ebrahem M.; Dakhil, Mohammed A.; Hassan, Loutfy M.; Salama, Shaimaa G.; Galal, Tarek M.

doi:10.3390/su13095276

Cited by 6 publications

(2 citation statements)

References 66 publications

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“…The biomass of P. stratiotes can be utilized to produce fertilizers and compost, and the utility of P. stratiotes as an organic phosphate fertilizer for rice cultivation has also been investigated (Polthanee et al, 2015). The potential of P. stratiotes biomass as an organic fertilizer for tomato cultivation has also been reported (Eid et al, 2021). Studies have shown the effectiveness of using macrophytes as organic fertilizers because they accumulate high concentrations of nutrients present in the water (Martínez-Soto et al, 2021).…”

Section: Discussionmentioning

confidence: 99%

Enhancing water quality and sustainable organic-phosphate fertilizer production through phytoremediation of cattle farm effluent using artificial wetlands

Kulangana,

Ariyarathne,

Priyantha

et al. 2024

Sri Lankan J. Biol.

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Eutrophication, which results from the excessive introduction of phosphorus into water bodies, poses a critical ecological challenge, although it is not the exclusive factor driving this phenomenon. The indispensability of phosphate fertilizers for global food production, coupled with the gradual depletion of natural phosphate reserves, underscores the urgency of sustainable phosphorus management. This research investigated the efficacy of two aquatic plant species, Salvinia and Pistia, for phosphate removal from cattle farm effluent while also exploring their potential use as organic fertilizers. These two species have been extensively employed in phytoremediation studies, underscoring their established roles in environmental remediation processes. Additionally, the study measured alterations in water quality parameters within an artificial wetland (AW) designed for wastewater treatment. Cattle farm effluent was collected during the cleaning and washing of the animal farm. Macrophytes were collected within a 500m diameter area of the pond using the systematic random sampling technique. The selected macrophytes were grown in identical plastic tanks filled with cattle farm effluent. Following a 21-day growth period, the harvested plants were subjected to drying at 70°C and were then ground into smaller particles to be transformed into fertilizer. The collected water samples were analyzed for residual phosphate concentrations and other water quality indicators, including pH, temperature, conductivity (EC), total dissolved solids (TDS) and dissolved oxygen percentage (DO%). Measurements of water quality indicators were replicated three times to report the average data and standard deviations. In this experimental setup, different water samples (AW I, AW II, AW III and AW IV) served as the experimental units, with corresponding dilution factors of 1:3 for AW I and AW III, and 1:2 for AW II and AW IV. The plant species involved in the study were Salvinia for AW I and AW II, and Pistia for AW III and AW IV. Statistical analysis employing Minitab 17 software enabled quantitative comparisons. Results demonstrated a consistent reduction in phosphate concentrations within the AWs over time, affirming their phosphate-removing potential. The phosphate removal efficiency of Salvinia was 37.87±6.50% and 35.69±1.32% for AW I and AW II, respectively. Similarly, for AW III and AW IV, Pistia demonstrated remarkable removal rates of 84.32±4.26% and 47.51±3.98%, respectively. Phosphate content in the fertilizers derived from Salvinia was 35.71±1.48 mg/kg and 29.44±0.91 mg/kg for AW I and AW II, respectively, while Pistia fertilizers from AW III and AW IV contained 38.00±2.29 mg/kg and 31.56±1.23 mg/kg, respectively. Furthermore, the investigation underscored the effectiveness of AWs as a potent phytoremediation technology for wastewater treatment, as evidenced by the water quality parameter analysis. This study not only highlights the promising potential of aquatic plants for sustainable phosphate management but also underscores the vital role of AWs in addressing phytoremediation potential in aquatic ecosystems.

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Section: Discussionmentioning

confidence: 99%

Enhancing water quality and sustainable organic-phosphate fertilizer production through phytoremediation of cattle farm effluent using artificial wetlands

Kulangana,

Ariyarathne,

Priyantha

et al. 2024

Sri Lankan J. Biol.

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“…The increase in the biomass shows increasing carbon absorption, which is attributed to the ability of P. stratiotes and S. molesta to utilize organic and inorganic contaminants as energy and carbon sources (Kumar et al 2017). The increase in biomass with after treatment of landfi ll leachates also shows the infl uence of the landfi ll leachate and CW sediment nutrient status on the rate of decomposition and respiration rate in P. stratiotes and S. molesta (Eid et al 2021). This is because factors such as sediment quality, water chemistry, nutrient inputs, and interspecifi c competition play a role in the growth and establishment of macrophytes (Clarke and Wharton 2001).…”

Section: Biomass and Bioaccumulation Factor Of P Stratiotes And S Mol...mentioning

confidence: 95%

Modelling Assisted Phytoremediation of Landfill Leachate using Surface Flow Constructed Wetland Enhanced by <i>Pistia stratiote</i> and <i>Salvinia molesta</i>

Ugya¹,

Meguellati²

2022

J. Ecol. Eng.

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The current study is aiming to expose the efficiency of surface flow constructed wetland (CW) assisted by Pistia stratiote and Salvinia molesta in the remediation of landfill leachates. A laboratory-scale surface flow constructed wetland was constructed to imitate the characteristic of a natural pond. Composite sample of leachates was collected and transported to the laboratory for further analysis and studies. The removal efficiency of phenol, pesticides, sulphate, chloride, colour, turbidity, total suspend solid (TSS), total dissolved solid (TDS), biological oxygen demand (BOD), chemical oxygen demand (COD), ammonia nitrate and heavy metals (Pb, Cr, Cu, Cd, Ni, Hg)). The removal of heavy metal ions in the CW was determined by using a phyto-system dynamic (phyto-SDA) model while the composite design (CCD) type of response surface methodology (RSM) was employed in this study for the optimization of pesticides and phenol removal from the landfill leachates by the constructed wetland (CW). The study also predicts that the deviation from the linearity between the heavy metals in the leachates and heavy metals in the sediment and in the plant tissues is influenced by the physicochemical status of the leachate and the mixed cultivation of Pistia stratiote and Salvinia molesta. The study reaffirms the role of sediments in the determination of the fate of heavy metals due to its crucial role in the bioavailability of heavy metals for uptake by P. stratiotes and S. molesta in a CW. The study also shows a positive effect of concentration and exposure time on the reduction efficiency of both pesticides and phenol. The result shows that exposure time and concentration of phenol and pesticides are useful in the optimization of the removal efficiency of pesticides and phenol.

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Macrophytes as passive bioindicators of trace element pollution in the aquatic environment

Polechońska

Klink

2022

WIREs Water

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Pollution with trace elements is considered a global problem due to their persistence, nondegradability, and toxicity to living organisms. Aquatic ecosystems are often the final sinks for trace elements, but these pollutants are quickly diluted and difficult to detect and, therefore, comprehensive monitoring of pollution is needed to implement appropriate control measures and prevent irreversible damage to these habitats. Bioindication is one of the recommended methods as it provides information not only on the pollution level but also on the bioavailability of elements and their biological impact. The paper is a synthetic review of the knowledge about the use of macrophytes as passive bioindicators (accumulator taxa) of trace element pollution in aquatic ecosystems. Various aspects of bioindication using accumulator aquatic plants are discussed: the criteria defined for the organisms used in biogeochemical bioindication, advantages of plants as accumulative bioindicators, general trends in the uptake, and accumulation of pollutants by macrophytes (including differences between life forms, organs, and seasons). The use of various groups of macrophytes in accumulative bioindication is described in detail with an emphasis on the relationship between element levels in plant tissues and their habitat as well as performance in the detection of pollution gradients.Knowledge gaps and limitations in the field of bioindication using accumulative macrophytes are indicated and the future perspective is outlined.

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Uptake Prediction of Eight Potentially Toxic Elements by Pistia stratiotes L. Grown in the Al-Sero Drain (South Nile Delta, Egypt): A Biomonitoring Approach

Cited by 6 publications

References 66 publications

Enhancing water quality and sustainable organic-phosphate fertilizer production through phytoremediation of cattle farm effluent using artificial wetlands

Enhancing water quality and sustainable organic-phosphate fertilizer production through phytoremediation of cattle farm effluent using artificial wetlands

Modelling Assisted Phytoremediation of Landfill Leachate using Surface Flow Constructed Wetland Enhanced by <i>Pistia stratiote</i> and <i>Salvinia molesta</i>

Macrophytes as passive bioindicators of trace element pollution in the aquatic environment

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