<i>Luffa cylindrica</i> sponges as a thermally and chemically stable support for <i>Aspergillus niger</i> lipase

Zdarta, Jakub; Jesionowski, Teofil

doi:10.1002/btpr.2253

Cited by 22 publications

(13 citation statements)

References 47 publications

(47 reference statements)

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“…Catalysts 2017, 7, 147 4 of 19 [32,33]. SEM images taken after enzyme immobilization (process parameters: 2 h process duration, 4 °C, pH 7) confirmed the successful deposition of the lipase by the presence of enzyme aggregates on the surface of the spongin fibers, as mentioned previously [34]. These results are confirmed by observations from digital microscopy (Figure 1e,f).…”

Section: Ftir Spectroscopysupporting

confidence: 84%

“…The marine keratosan demosponges exhibit a three-dimensional open network structure built from similar, branched spongin fibers with a slightly corrugated surface at a diameter of 20 μm The marine keratosan demosponges exhibit a three-dimensional open network structure built from similar, branched spongin fibers with a slightly corrugated surface at a diameter of 20 µm [32,33]. SEM images taken after enzyme immobilization (process parameters: 2 h process duration, 4 • C, pH 7) confirmed the successful deposition of the lipase by the presence of enzyme aggregates on the surface of the spongin fibers, as mentioned previously [34]. These results are confirmed by observations from digital microscopy (Figure 1e,f).…”

Section: Sem and Digital Microscopysupporting

confidence: 77%

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Spongin-Based Scaffolds from Hippospongia communis Demosponge as an Effective Support for Lipase Immobilization

et al. 2017

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The main purpose of the study was to achieve effective immobilization of lipase B from Candida antarctica (CALB) onto 3D spongin-based scaffolds from Hippospongia communis marine demosponge for rapeseed oil transesterification. Successful immobilization onto the marine sponge skeleton was confirmed for the first time. Lipase B-containing biocatalytic system exhibited the highest catalytic activity retention (89%) after 60 min of immobilization at pH 7 and temperature of 4 • C. Immobilization was found to improve the thermal and chemical stability compared to free lipase, and retain over 80% of its initial catalytic activity over a wide range of temperature (30-60 • C) and pH (6-9). Additionally, immobilized lipase has good storage stability and retains over 70% of its initial activity even after catalyzing of 25 reaction cycles. The obtained product was used in a transesterification reaction of rapeseed oil with methanol and proved to be an efficient biocatalyst for biofuel production. The highest conversion value and fatty acids methyl esters (FAME) concentration were observed after a process conducted at 40 • C and pH 10. The possible mechanism of interaction between the enzyme and the spongin-based support is proposed and discussed.

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Section: Ftir Spectroscopysupporting

confidence: 84%

Section: Sem and Digital Microscopysupporting

confidence: 77%

Spongin-Based Scaffolds from Hippospongia communis Demosponge as an Effective Support for Lipase Immobilization

et al. 2017

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“…As reported by Kim et al cellulose nanocrystals obtained from cotton linter cellulose can be used for immobilization by non-specific adsorption interactions of Candida rugosa lipase with high loading efficiency [65], whilst lipase was immobilized by entrapment by Tumturk et al using κ-carrageenan hydrogels [66]. Vegetable and marine sponges characterized by an open fibrous network that reduces diffusional limitations have also been used as matrices for the immobilization of lipases, mainly via hydrogen bonds [67,68]. It may be concluded that biopolymers can be used to immobilize enzymes belonging to various catalytic classes with the retention of good catalytic properties.…”

Section: Biopolymersmentioning

confidence: 99%

A General Overview of Support Materials for Enzyme Immobilization: Characteristics, Properties, Practical Utility

et al. 2018

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In recent years, enzyme immobilization has been presented as a powerful tool for the improvement of enzyme properties such as stability and reusability. However, the type of support material used plays a crucial role in the immobilization process due to the strong effect of these materials on the properties of the produced catalytic system. A large variety of inorganic and organic as well as hybrid and composite materials may be used as stable and efficient supports for biocatalysts. This review provides a general overview of the characteristics and properties of the materials applied for enzyme immobilization. For the purposes of this literature study, support materials are divided into two main groups, called Classic and New materials. The review will be useful in selection of appropriate support materials with tailored properties for the production of highly effective biocatalytic systems for use in various processes.

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“…For this reason, interference in the structure of the enzyme and its distortion upon immobilization are limited [57]. This is a possible explanation of the high specific activity of the immobilized laccase (52.5 U/mg) as compared to the free enzyme (56 U/mg), corresponding to an activity retention of 89% [58]. By contrast, Das et al immobilized laccase on magnetic iron nanoparticles and obtained specific activity of the immobilized protein was about 15 U/mg, that was almost two times lower as compared to free laccase (30 U/mg) [59].…”

Section: Characterization Of Products Following Immobilizationmentioning

confidence: 99%

3D Chitin Scaffolds from the Marine Demosponge Aplysina archeri as a Support for Laccase Immobilization and Its Use in the Removal of Pharmaceuticals

et al. 2020

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For the first time, 3D chitin scaffolds from the marine demosponge Aplysina archeri were used for adsorption and immobilization of laccase from Trametes versicolor. The resulting chitin–enzyme biocatalytic systems were applied in the removal of tetracycline. Effective enzyme immobilization was confirmed by scanning electron microscopy. Immobilization yield and kinetic parameters were investigated in detail, in addition to the activity of the enzyme after immobilization. The designed systems were further used for the removal of tetracycline under various process conditions. Optimum process conditions, enabling total removal of tetracycline from solutions at concentrations up to 1 mg/L, were found to be pH 5, temperature between 25 and 35 °C, and 1 h process duration. Due to the protective effect of the chitinous scaffolds and stabilization of the enzyme by multipoint attachment, the storage stability and thermal stability of the immobilized biomolecules were significantly improved as compared to the free enzyme. The produced biocatalytic systems also exhibited good reusability, as after 10 repeated uses they removed over 90% of tetracycline from solution. Finally, the immobilized laccase was used in a packed bed reactor for continuous removal of tetracycline, and enabled the removal of over 80% of the antibiotic after 24 h of continuous use.

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Luffa cylindrica sponges as a thermally and chemically stable support for Aspergillus niger lipase

Cited by 22 publications

References 47 publications

Spongin-Based Scaffolds from Hippospongia communis Demosponge as an Effective Support for Lipase Immobilization

Spongin-Based Scaffolds from Hippospongia communis Demosponge as an Effective Support for Lipase Immobilization

A General Overview of Support Materials for Enzyme Immobilization: Characteristics, Properties, Practical Utility

3D Chitin Scaffolds from the Marine Demosponge Aplysina archeri as a Support for Laccase Immobilization and Its Use in the Removal of Pharmaceuticals

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