Man-tailored cellulose-based carriers for invertase immobilization

Despite the extensive efforts of scientific community towards the development of a vast variety of immobilization methods, there is a limited number of immobilized biocatalysts used at industrial scale. Most often, cost issues prevent the transfer of methodologies to large scale but more recently also sustainability criteria are becoming increasingly relevant, so that petroleum based carriers for enzyme immobilization appear unsuitable for responding to new challenges of green and renewable chemistry. Here we report, for the first time, a preliminary overview of the potential of rice husk as carrier to be employed for both physical and covalent immobilization of enzymes. The data indicate that the chemical versatility of this lignocellulosic biomass, containing also silica, opens wide scenarios for optimizing different immobilization procedures requiring minimal pre-treatments and applicable to various enzymes and process conditions. The mechanical and chemical robustness of rice husk, along with its virtual unlimited availability worldwide, make this inexpensive natural matrix a promising candidate for replacing organic fossil-based carriers for enzyme immobilization.Computational construction of 3D models and surface analysis. Protein structures were visualized and recorded using the PyMOL software. The 3D-structures used for the hydrophobicity comparisons were retrieved from the PDB with the codes 1TCA for CaLB, 5DPF for Thermolysin and 4EQV for Invertase

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“…ISc activity was determined using the method of described by Bryjak et al 46 , incubating 0.1 mL of enzyme solution (0.002 mg mL -1…”

Section: Hydrolytic Activity Assay For Iscmentioning

confidence: 99%

Large scale applications of immobilized enzymes call for sustainable and inexpensive solutions: rice husks as renewable alternatives to fossil-based organic resins

Corîci¹,

Ferrario

Pellis

et al. 2016

RSC Adv.

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“…These biocatalysts have presented some advantages such as thermal stability, easy separation from reactor and reuse. These benefits lead to a reduction of process costs [1] . The industrial use of immobilized enzymes requires the evaluation of variables that may affect their activities in order to optimize their performance [2] .…”

Section: Introductionmentioning

confidence: 99%

High sucrolytic activity by invertase immobilized onto magnetic diatomaceous earth nanoparticles

Cabrera

Assis

Neri

et al. 2017

Biotechnology Reports

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“…To maximize enzyme activity, the supports should create a specific microenvironment for the enzymes and reduce the denaturation of enzyme protein (Becher et al 2004;Bryjak et al 2008;Huang et al 2009;Liu and Chang 2008;Lu and Hsieh 2010). Among different supporting materials, cellulose stands out since it is inert and biocompatible under physiological conditions, which has a dual hydrophilic/hydrophobic character that can be ''tuned'' to suit particular needs (Cunha and Gandini 2010;Kosaka et al 2007).…”

Section: Introductionmentioning

confidence: 99%

Immobilization of lipase onto cellulose ultrafine fiber membrane for oil hydrolysis in high performance bioreactor

Chen

Huang

et al. 2011

Cellulose

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Practical application of biphasic enzymeimmobilized membrane bioreactors (EMBR) requires efficient loading of the enzyme with retention of enzymatic activity. Here, we report a method to fabricate an ultrafine fiber membrane conjugated to lipase with high levels of enzyme loading and activity retention. A cellulose acetate (CA) non-woven ultrafine fiber membrane was prepared with 200 nm nominal fiber diameter by electrospinning, followed by alkaline hydrolysis to obtain regenerated cellulose (RC). The RC ultrafine fiber membrane was oxidized by exposure to NaIO 4 , simultaneously generating aldehyde groups to couple with pentaethylenehexamine (PEHA) as a spacer for lipase immobilization. A biphasic EMBR was assembled with the PEHAmodified and lipase-immobilized membranes. The effect of operation variables, namely aqueous-phase system, reaction pH, accelerant (sodium taurocholate) content, reaction temperature, and membrane usage on the performance of this bioreactor was investigated with the hydrolysis of olive oil. A bioreactor activity as high as 9.83 9 10 4 U/m 2 was obtained under optimum operational conditions.

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Man-tailored cellulose-based carriers for invertase immobilization

Cited by 16 publications

References 26 publications

Large scale applications of immobilized enzymes call for sustainable and inexpensive solutions: rice husks as renewable alternatives to fossil-based organic resins

Large scale applications of immobilized enzymes call for sustainable and inexpensive solutions: rice husks as renewable alternatives to fossil-based organic resins

High sucrolytic activity by invertase immobilized onto magnetic diatomaceous earth nanoparticles

Immobilization of lipase onto cellulose ultrafine fiber membrane for oil hydrolysis in high performance bioreactor

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