Model-Assisted Optimization of Cobalt Biosorption on Macroalgae Padina pavonica for Wastewater Treatment

Aloufi, Abeer S.; Al Riyami, Bahja; Fawzy, Mustafa A.; Al-Yasi, Hatim M.; Koutb, Mostafa; Hassan, Sedky H. A.

doi:10.3390/w16060887

Cited by 5 publications

(3 citation statements)

References 68 publications

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“…In the FTIR peaks, a variable band corresponding to the N-H/O-H stretching of carboxylic acids was detected at 3274 cm −1 [25]. It is possible to explain the bands detected at 1636 to the stretching energies of -C = C (alkenes) [26]. The C-O strong peaks of ester can be identified by the absorption peaks focused at the band present at 1097.80 [27].…”

Section: Characterization Of Agnpsmentioning

confidence: 91%

Silver nanoparticles alleviate the impact of soil contamination and wastewater irrigation on rosemary plants: modulating of gene expression and secondary metabolites

Al Kashgry,

Darwish,

Aljomiha

et al. 2024

Mater. Res. Express

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A number of obstacles, including irrigated wastewater and soil contamination, arise in the growth of aromatic and medicinal plants. This study aimed to reduce the effects of contaminated soil and wastewater irrigation on rosemary (Rosmarinus officinalis L.) plants by using biosynthesized silver nanoparticles (AgNPs) produced by the ginger (Zingiber officinale) plant extract. The AgNPs were characterized using Attenuated Total Reflection Fourier Transform Infrared (ATR-FTIR). The experimental design involved three distinct groups of plants: one group was irrigated with regular tap water, another group was rooted in soil contaminated by sewage-wastewater and irrigated with processed wastewater, and the final group consisted of plants grown in wastewater-contaminated soil, irrigated with processed wastewater, and sprayed with 200 mM l−1 AgNPs. The study also examined the impact of different treatments on gene expression and secondary metabolite levels in rosemary plants. According to HPLC investigations, nineteen phenol compounds and flavonoids were identified in a methanolic extract of rosemary that was grown in contaminated soil, irrigated with wastewater, and sprayed with AgNPs. Plants treated with wastewater and nanoparticles produced quantities of secondary compounds, including resvertol, vanillic acid, and gallic acid with 1.11, 0.15, and 0.01 mg g−1 respectively, which are all regarded as significant antioxidants employed in the pharmaceutical industry. Hexokinase synthase (HK), geranyl diphosphate synthase (GPPS), and linalool synthase (LS) coding genes were found to have highly expressed expressions when plants grown in contaminated soil, wastewater-irrigated plants, and nanoparticle-sprayed plants, respectively, at a 23.2- and 5.54-fold level, where the HK gene was 8.7 times more strongly expressed. Conversely, plants grown in contaminated soil and irrigated with treated wastewater showed downregulation of these genes. Conclusively, using silver nanoparticles significantly reduced the influence of wastewater pollution on secondary metabolites in rosemary plants, which was increased by the gene expression results and was completely consistent with HPLC analysis.

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Section: Characterization Of Agnpsmentioning

confidence: 91%

Silver nanoparticles alleviate the impact of soil contamination and wastewater irrigation on rosemary plants: modulating of gene expression and secondary metabolites

Al Kashgry,

Darwish,

Aljomiha

et al. 2024

Mater. Res. Express

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“…The maximum K f values for Cu 2+ from C. ellipsoideum and D. 2). The n value is used for the evaluation of a good adsorbent, with values greater than 1 indicating favorable adsorption behavior [12]. Higher n values (2.05 and 2.17) for C. ellipsoideum and D. subspicatus, respectively suggested better biosorption and the formation of strong bonds between the metal ions and the adsorbent (table 2).…”

Section: Biosorption Isotherms Modelsmentioning

confidence: 99%

Bioremediation potential of microalgae for copper ion from wastewater and its impact on growth and biochemical contents: equilibrium isotherm studies

Fawzy,

Abdelsalam,

Hafez

et al. 2024

Mater. Res. Express

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In this study, the green microalgae Chloroidium ellipsoideum and Desmodesmus subspicatus were used to study copper uptake from nutrient media and its effect on algal growth and metabolism. The growth of C. ellipsoideum and D. subspicatus generally decreased with increasing copper concentrations. There was a decrease in the carbohydrate content of C. ellipsoideum , but an increase was observed in D. subspicatus by treatment with various copper concentrations. Low concentrations of copper helped to increase the protein content of C. ellipsoideum , but a decline in protein content was reported for D. subspicatus. By increasing the copper concentrations, an increase in the free amino acids and a decrease in the total lipid content of C. ellipsoideum and D. subspicatus were recorded. At 0.1 mgl–1,the maximum reduction of Cu2+ was 68.66% and 59.52% for C. ellipsoideum and D. subspicatus. The Langmuir, Freundlich, Temkin and Dubinin–Radushkevich models were applied to describe the isothermal biosorption of Cu2+ ions in studied algae. The Dubinin–Radushkevich model indicated that the copper biosorption mechanism was physical in nature. Cu2+ has a greater affinity for D. subspicatus than C. ellipsoideum , suggesting that C. ellipsoideum was relatively more resistant to Cu2+ toxicity than D. subspicatus. FT-IR analysis revealed that carboxyl, amide, amino, carbonyl, hydroxyl, methyl and alkyl groups were the key groups responsible for the biosorption process. Therefore, D. subspicatus and C. ellipsoideum are efficient biosorbents for Cu2+ and can be used as biosorbents for heavy metals removal from wastewater.

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“…However, they have drawbacks like ineffective metal removal at low concentrations and high chemical consumption. − Biotechnological approaches show promise, utilizing microorganisms for heavy metal remediation. − Microalgae, particularly Spirulina , are gaining attention for their pollutant abatement capabilities. − Spirulina’s integration into cleaner production and sustainability practices has gained traction, with studies highlighting its potential in wastewater treatment, carbon sequestration, and biofuel production. ,− Its rapid growth and high nutrient uptake efficiency make it effective for bioremediation. ,− Spirulina cultivation offers sustainable food and feed production, requiring minimal resources compared with conventional crops. Additionally, Spirulina -derived products contribute to a circular economy, promoting resource efficiency and waste valorization. − The literature reports the kinetic model of Spirulina based on the ability to remove metal ions, nutrients, and specific growth rates. − As per our knowledge, there is limited information on the growth model, which incorporates nutrient adsorption, light absorption, photosynthetic efficiency, respiration, and biosynthesis efficiency during synthetic or real wastewater cultivation. These parameters were important to predict Spirulina growth and control the effluent treatment process.…”

Section: Introductionmentioning

confidence: 99%

Unlocking the Potential: Algal Biomass Cultivation and Growth Kinetics Using Tanning Process Water

Gagrai

2024

ACS Sustainable Resour. Manage.

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A basic kinetic model has been applied to microalgae to predict the growth parameters in Zarrouk Media composition (ZMC) and precipitated chrome tanning effluent (PCTE). The model was fitted with the experimental data of Spirulina cultivation to estimate growth parameters: nutrient adsorption constant (K a) (h–1), nutrient desorption constant (K d) (h–1), rate of respiration (rR c)(h–1), efficiency of bio-synthesis (β) (g g–1), respiration rate (h–1)(rR c), rate of maximum photosynthesis (p max) (h–1), coefficient for light-absorption (α) (m2 g–1), photon efficiency (g.μmol–1 photons–1) (φm), etc. The model suggests a higher nutrient adsorption rate in ZMC (0.75 h–1) as compared to PCTE (1.40 × 10–2 h–1). The rate of respiration of Spirulina decreased due to cultivation in PCTE from 5.36 × 10–3 to 1.91 × 10–3 h–1. The biosynthetic efficiency of Spirulina decreased from 8.72 to 2.002 due to cultivation in PCTE media. The maximum photosynthetic rate h–1 was slightly higher in ZMC as compared to PCTE media. The model parameter values were lower for Spirulina in PCTE than those in ZMC. Spirulina’s cell density was lower in PCTE compared to ZMC, as the doubling time was increased from 9.97 h–1 to 31.47 h–1. Moreover, the optimum pH for growth was also shifted from 9.5 to 10.5. The higher dose of PCTE (Cl– > 2.96 × 103 mg L–1) restricted cell growth. Adding Cr(III) in ZMC has a higher impact on cell growth than Cr(VI). The model parameters with Cr(III) and Cr(VI) also showed a decrease in values except rRc and β have higher values for Cr(VI) as compared to Cr(III) added ZMC due to the non-interaction of Cr(VI) with algae. The model-predicted cell growth rates closely align with experimental results, with deviations within an ±7% margin. The addition of heavy metals to ZMC disrupts nutrient interactions and transport mechanisms during Spirulina cell growth.

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Model-Assisted Optimization of Cobalt Biosorption on Macroalgae Padina pavonica for Wastewater Treatment

Cited by 5 publications

References 68 publications

Silver nanoparticles alleviate the impact of soil contamination and wastewater irrigation on rosemary plants: modulating of gene expression and secondary metabolites

Silver nanoparticles alleviate the impact of soil contamination and wastewater irrigation on rosemary plants: modulating of gene expression and secondary metabolites

Bioremediation potential of microalgae for copper ion from wastewater and its impact on growth and biochemical contents: equilibrium isotherm studies

Unlocking the Potential: Algal Biomass Cultivation and Growth Kinetics Using Tanning Process Water

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