Enzyme immobilization on photopatterned temperature‐response poly (N‐isopropylacrylamide) for microfluidic biocatalysis

Shi

J of Chemical Tech & Biotech

2019

BACKGROUND The objective of this research was to use a step‐by‐step method to prepare a novel biocatalytic system (GO‐CEL‐E/N‐GA‐GOD): ‐OH and ‐COOH on the surface of graphene oxide (GO) were used to immobilize cellulase (CEL) and glucose oxidase (GOD), respectively, which may be easier to control the loading of enzymes with different kinds, to achieve the one‐pot conversion of gluconic acid from carboxymethyl cellulose (CMC). RESULTS The loadings capability of CEL and GOD on GO‐CEL‐E/N‐GA‐GOD were 49.07 ± 7.47 mg g−1 and 10.22 ± 2.03 mg g−1, respectively. The multi‐enzyme systems had shallow temperature and pH optima of 40 °C and 5.0. The kinetic constants of GO‐CEL‐E/N‐GA‐GOD (of CEL‐GOD) were Km = 0.15 ± 0.02 (0.43 ± 0.09) mmol L−1, Vmax = 0.18 ± 0.01 (0.21 ± 0.07) μmol L−1 s−1, and kcat/Km = 24.12 ± 0.52 (17.74 ± 0.85) s−1 mmol−1 L. Nearly 65% of the initial activity of GO‐CEL‐E/N‐GA‐GOD could be retained after seven cycles. Notably the conversion of gluconic acid was able to reach 63.82 ± 8.03% within 2 h. CONCLUSION Step‐by‐step immobilization method made full use of different functional groups on GO, avoiding the competition for fixed sites between CEL and GOD in the immobilization processes. The results reflected the feasibility of the strategy to build bio‐microsystem as CEL and GOD immobilized on GO by covalent bonds to achieve the conversion from CMC to gluconic acid in one‐step. © 2019 Society of Chemical Industry

Section: Resultsmentioning

confidence: 99%

Co‐immobilization of cellulase and glucose oxidase on graphene oxide by covalent bonds: a biocatalytic system for one‐pot conversion of gluconic acid from carboxymethyl cellulose

Shi

J of Chemical Tech & Biotech

2019

J of Chemical Tech & Biotech

“…One of the effective ways to use enzymes as a biocatalyst is to immobilize them on an appropriate support . This method has advantages such as improved process design, a decrease in operating cost, the integration of the operating unit, higher productivity, and fewer byproducts . Furthermore, membrane separations are easy to scale up and also involve low energy requirements, since no phase change usually takes place in such processes .…”

Section: Introductionmentioning

confidence: 99%

Decolorization of dye solutions by tyrosinase in enzymatic membrane reactors

Veismoradi

Mousavi

Taherian

2019

BACKGROUND:The main aim of this study was to investigate the decolorization performance of enzymatic membrane reactors (EMRs) using tyrosinase, including direct contact membrane reactor (DCMR) and immobilized enzyme membrane reactor (IEMR). The crosslinked polyacrylonitrile (PAN)/chitosan composite membrane was employed in a separation unit as support for tyrosinase immobilization to decolorize two common Acid Blue 113 (AB113) and Direct Black 22 (DB22) azo dyes for the first time.RESULTS: According to the obtained results, the optimum enzyme amount, which could be immobilized on the membrane surface, was 25 units. The proper operating conditions for both DCMR and IEMR were determined as pH 6.5 and temperature 30 ∘ C. Both the reactors initially accounted for around 96% and 94% decolorization for AB113 and DB22, respectively. To determine the reusability of EMRs after 10 cycles, 83.1% and 78.5% dye removal were achieved using IEMR for AB133 and DB22, respectively; while for DCMR, this amount reduced to 60.5% and 58.3% for AB113 and DB22, respectively. CONCLUSION:The proposed IEMR maintained a high dye removal amount through the studied pH and temperature ranges. However, the performance of DCMR considerably reduced under the intensive operating conditions as well as in the long-term operation. As a result, the suggested immobilized enzyme showed superior and stable performance compared to the free one in the long-term operation.

Front. Bioeng. Biotechnol.

“…Polymer monoliths are very interesting macrostructures developed in 1990s, mainly based on methacrylates, acrylates, and styrenes. The polymerization is performed in templates such as rod polymer for chromatographic columns (Watanabe et al, 2009;Li et al, 2010;Duan et al, 2020), disks (Lin et al, 2020), and microfluidic channels (Knob et al, 2016;Parker et al, 2019; Zhu et al, 2019). Monoliths can be functionalized with different groups such as epoxy, aldehyde or alkene groups (Masini and Svec, 2017).…”

Section: Polymer Monoliths-enzyme Hybridsmentioning

confidence: 99%

Tunable Polymeric Scaffolds for Enzyme Immobilization

Rodriguez‐Abetxuko

Sánchez-deAlcázar

Muñumer

et al. 2020

The number of methodologies for the immobilization of enzymes using polymeric supports is continuously growing due to the developments in the fields of biotechnology, polymer chemistry, and nanotechnology in the last years. Despite being excellent catalysts, enzymes are very sensitive molecules and can undergo denaturation beyond their natural environment. For overcoming this issue, polymer chemistry offers a wealth of opportunities for the successful combination of enzymes with versatile natural or synthetic polymers. The fabrication of functional, stable, and robust biocatalytic hybrid materials (nanoparticles, capsules, hydrogels, or films) has been proven advantageous for several applications such as biomedicine, organic synthesis, biosensing, and bioremediation. In this review, supported with recent examples of enzyme-protein hybrids, we provide an overview of the methods used to combine both macromolecules, as well as the future directions and the main challenges that are currently being tackled in this field.