Reusable polyethylenimine-coated polysulfone/bacterial biomass composite fiber biosorbent for recovery of Pd(II) from acidic solutions

Cho, Chul-Woong; Kang, Su Bin; Kim, Sok; Yun, Yeoung‐Sang; Won, Sangchul

doi:10.1016/j.cej.2016.05.091

Cited by 48 publications

(9 citation statements)

References 35 publications

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“…The biocomposite was stable in real acetic acid industrial effluent from the Cavita process and could be used to recovery ruthenium in flow-through column system, showing 120 beds of breakthrough volume [59]. The same biosorbent can be used for recovery of Pd(II) ions from acidic solutions [60].…”

Section: Immobilized Bacterial Biosorbentsmentioning

confidence: 98%

Immobilized microbial biosorbents for heavy metals removal

Velkova

Kirova

Stoytcheva

et al. 2018

Engineering in Life Sciences

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Intensive industrial and urban growth has led to the release of increasing amounts of environmental pollutants. Contamination by metals, in particular, deserves special attention due to their toxicity and potential to bioaccumulate via the food chain. Conventional techniques for the removal of toxic metals, radionuclides and precious metals from wastewater all have a number of drawbacks, such as incomplete metal extraction, high cost and risk of generating hazardous by‐products. Biosorption is a cost‐effective and environment‐friendly technology, an alternative to conventional wastewater treatment methods. Biosorption is a metabolically independent process, in which dead microbial biomass is capable of removal and concentrating metal ions from aqueous solutions. Free microbial biosorbents are of small size and low density, insufficient mechanical stability and low elasticity, which causes problems with metal ion desorption, separation of the sorbent from the medium and its regeneration. Hence, the possibilities for the implementation of continuous biosorbent processes for metal removal in flow‐type reactor systems are reduced and the practical application of biosorption in industrial conditions is limited. By immobilizing microbial biomass on suitable carriers the disadvantages of free biosorbents are eliminated and more opportunities for practical use of biosorption become available. This review examines different immobilization techniques and carriers, certain basic features and possibilities of using immobilized microbial biosorbents for the removal and concentration of metals from aqueous solutions.

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Section: Immobilized Bacterial Biosorbentsmentioning

confidence: 98%

Immobilized microbial biosorbents for heavy metals removal

Velkova

Kirova

Stoytcheva

et al. 2018

Engineering in Life Sciences

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“…Pseudomonas sp. immobilized with polyacrylamide matrix, 18 Nanocellulose coupled with polypyrrole matrix, 19 Saccharomyces cerevisiae ‐polypropylene, Saccharomyces cerevisiae ‐polystyrene composites, 20 polyacrylamide‐grafted coconut coir pith, 21 polyethyleneimine‐coated polysulfone‐ Escherichia coli biomass composite, 22 Corynebacterium glutamicum immobilized with polyurethane and polysulfone matrix 23 are various examples of immobilized sorbent systems prepared using synthetic polymeric matrices for the sorption of various contaminants. However, the preparation of such immobilized biosorbents often involves complex processes that cannot survive commercially 24,25 .…”

Section: Introductionmentioning

confidence: 99%

Attached culture of Gibberella fujikuroi for biocomposite sorbent production and ciprofloxacin sequestration applications

Akar

Sayin

Çelik

et al. 2021

J of Chemical Tech & Biotech

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BACKGROUND The fluoroquinolone antibiotics in water sources are significant threats to public health, as well as the water ecosystem and water reuse. In this study, the feasibility of the biosorption of ciprofloxacin (CIP) using pine needles biomass‐Gibberella fujikuroi immobilized biocomposite (PNGFB) was promoted. It was prepared by passive cell immobilization onto the lignocellulosic matrix. The suggested biosorbent was characterized by Fourier Transform Infrared (FTIR) analysis, Scanning Electron Microscope (SEM), and zeta potential analysis. Series of batch and continuous mode experiments were conducted. RESULTS The results of both systems showed that the PNGFB was effectively used for the treatment of CIP contamination. The maximum uptake occurred at pH 6.0, 40 min contact time, 1.0 mL min−1 flow rate, and 0.10 g (batch) and 0.20 g (column) PNGFB dosages. Redlich–Peterson isotherm model was the best suited to equilibrium data and the pseudo‐second‐order model predicted the biosorption kinetics. The maximum monolayer biosorption capability was 39.17 mg g−1. The suggested biocomposite also reached CIP removal yields of 64.14% and 53.74% in synthetic hospital effluent and synthetic urine samples containing 100 mg L−1 antibiotic, respectively. The regeneration study indicates that PNGFB retained its high biosorption and desorption yields during five cycles of the biosorption‐desorption. CONCLUSION The findings clearly showed that the PNGFB seems to be an eco‐friendly, effective, economic, and potentially viable biocomposite sorbent for the sustainable removal of CIP contamination. © 2021 Society of Chemical Industry (SCI).

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“…In recent decades, immobilization biological technology has been applied to biological fermentation, environmental purification, energy production and so on [5] [6] [7]. Microorganisms cells was embed in the carrier skeleton to protect them from the toxicity of pollutants, which not only increases the effective biomass, reduces the cost of cell reconstruction, but also shows good dispersion and recyclability [8] [9]. In this paper, P. pastoris were embed with sodium alginate to recover palladium from the solution, and the immobilized pellets with palladium were used as a supported catalyst for the reduction of 4-np.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Palladium Adsorption by Immobilized <i>Pichia pastoris</i>: A Reusable Catalyst for Reduction of 4-Nitrophenol

Lin¹,

Jing²,

Chen³

2020

MSCE

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In this paper, the immobilized pellets were prepared by embedding Pichia pastoris (P. pastoris) with sodium alginate and used for the recovery of palladium ions in solution. The catalytic activity of immobilized Pd/P. pastoris for 4-nitrophenol (4-NP) was studied. The results showed that the recovery rate of Pd ions could be significantly increased by immobilized cells. The immobilized Pd/P. pastoris pellets showed good catalytic activity for the reduction of 4-NP, and the catalyst remained good catalytic activity even after multiple reuses.

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Reusable polyethylenimine-coated polysulfone/bacterial biomass composite fiber biosorbent for recovery of Pd(II) from acidic solutions

Cited by 48 publications

References 35 publications

Immobilized microbial biosorbents for heavy metals removal

Immobilized microbial biosorbents for heavy metals removal

Attached culture of Gibberella fujikuroi for biocomposite sorbent production and ciprofloxacin sequestration applications

Enhanced Palladium Adsorption by Immobilized <i>Pichia pastoris</i>: A Reusable Catalyst for Reduction of 4-Nitrophenol

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Reusable polyethylenimine-coated polysulfone/bacterial biomass composite fiber biosorbent for recovery of Pd(II) from acidic solutions

Cited by 48 publications

References 35 publications

Immobilized microbial biosorbents for heavy metals removal

Immobilized microbial biosorbents for heavy metals removal

Attached culture of Gibberella fujikuroi for biocomposite sorbent production and ciprofloxacin sequestration applications

Enhanced Palladium Adsorption by Immobilized &lt;i&gt;Pichia pastoris&lt;/i&gt;: A Reusable Catalyst for Reduction of 4-Nitrophenol

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Enhanced Palladium Adsorption by Immobilized <i>Pichia pastoris</i>: A Reusable Catalyst for Reduction of 4-Nitrophenol