Covalent Organic Framework Cladding on Peptide-Amphiphile-Based Biomimetic Catalysts

Mahato, Ashok Kumar; Pal, Sumit; Dey, Kaushik; Reja, Antara; Paul, Satyadip; Shelke, Ankita; Ajithkumar, T. G.; Das, Dibyendu; Banerjee, Rahul

doi:10.1021/jacs.3c03562

Cited by 12 publications

(8 citation statements)

References 58 publications

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“…Immobilizing enzymes on solid supports is an effective strategy to enhance their stability, reusability, and easy operation, which are desired for the development of enzyme catalysts. − Due to the advantages of reticular chemistry materials (such as high porosity, stability, and tunability), metal–organic frameworks (MOFs) and covalent organic frameworks (COFs) have recently been regarded as excellent supports for enzyme immobilization. − To date, a series of MOFs, especially ZIFs, have been widely explored for de novo immobilizing enzymes; however, the bioactivity of immobilized enzymes is sometimes far from satisfactory, which is caused by the diffusion barriers of ZIFs (pore size of the commonly used ZIF-8: 0.34 nm) and the unavoidable activity loss during the immobilizing process, such as harmful metal ions. − Meanwhile, a lot of research has successfully enhanced the activity of the immobilized enzyme, such as modulating the microenvironment, shortening diffusion paths, and enabling biocatalytic cascades. − However, there is still an essential problem that has not been solved in enzyme@MOF biocomposites, which is the unavoidable influence of metal ions on enzymatic activity. Some reports have proved that metal ions can coordinate with enzymes, which may perturb their conformation or cover their active sites, leading to unpredictable changes in activity and even the complete inactivation of enzymes. − …”

Section: Introductionmentioning

confidence: 99%

Improving the Bioactivity and Stability of Embedded Enzymes by Covalent Organic Frameworks

Li,

Ren

et al. 2023

ACS Appl. Mater. Interfaces

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De novo embedding enzymes within reticular chemistry materials have shown the enhancement of physical and chemical stability for versatile catalytic reactions. Compared to metal−organic frameworks (MOFs), covalent organic frameworks (COFs) are usually considered to be the more superior host of enzymes because of their large channels with low diffusion barriers, outstanding chemical/ thermal stability, and metal-free nature. However, detailed investigations on the comparison of COFs and MOFs in enhancing biocatalytic performance have not been explored. Here, we de novo encapsulated enzymes within two COFs via a mechanochemical strategy, which avoided the extreme synthetic conditions of COFs and highly maintained the biological activities of the embedded enzymes. The enzymes@COFs biocomposites exhibited a much higher activity (3.4−14.7 times higher) and enhanced stability than those in MOFs (ZIF-8, ZIF-67, HKUST-1, MIL-53, and CaBDC), and the rate parameter (k cat /K m ) of enzyme@COFs was 41.3 times higher than that of enzyme@ZIF-8. Further explorations showed that the conformation of enzymes inside MOFs was disrupted, owing to the harmful interfacial interactions between enzymes and metal ions as confirmed by ATR-FTIR, fluorescence spectroscopy, and XPS data. In contrast, enzymes that were embedded in metal-free COFs highly preserved the natural conformation of free enzymes. This study provides a better understanding of the interfacial interactions between reticular supports and enzymes, which paves a new road for optimizing the bioactivities of immobilized enzymes.

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Section: Introductionmentioning

confidence: 99%

Improving the Bioactivity and Stability of Embedded Enzymes by Covalent Organic Frameworks

Li,

Ren

et al. 2023

ACS Appl. Mater. Interfaces

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“…4 However, the endeavor of choosing the right template is critical, and it can be challenging to find suitable templates for some desired structures. 5 Moreover, it is difficult to remove the template without damaging the final structure, and traces of residue may remain, affecting the final material's properties. 2 In this context, breath figure (BF) methods have emerged as a promising technique for the fabrication of highly ordered, porous films similar to the honeycomb structure pattern (HCP) first reported by Widawski et al 6 The formation of the porous films by the BF method was facilitated by casting the polymer solution under humidity.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Self-templated synthesis allows precise control over the final product’s size, shape, and morphology and a high degree of pore uniformity . However, the endeavor of choosing the right template is critical, and it can be challenging to find suitable templates for some desired structures . Moreover, it is difficult to remove the template without damaging the final structure, and traces of residue may remain, affecting the final material’s properties …”

Section: Introductionmentioning

confidence: 99%

Novel Capturer-Catalyst Microreactor System with a Polypyrrole/Metal Nanoparticle Composite Incorporated in the Porous Honeycomb-Patterned Film

Falak,

Shin,

Kang

et al. 2023

ACS Appl. Mater. Interfaces

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A composite of polypyrrole/metal nanoparticles (PPy/MNPs) was selectively incorporated into the pores of a honeycomb-patterned porous polycaprolactone polymer film to fabricate a novel capturer−catalyst microreactor system. This fabrication involved a modified breath figure method, where the polymer solution containing metal ions as an oxidizing agent was cast under humid conditions along with the pyrrole monomer through an interfacial reaction in a one-step in situ process. The higher hydrophilicity of the metal ions compared to the polymer solution led to their self-assembly around the pore surface, resulting in the selective incorporation of the PPy/MNP composite into the porous film. Copper (Cu), silver (Ag), and gold (Au) were used for the PPy/MNP fabrication. Various methods characterized the fabricated film. Strong catalytic degradations of methylene blue and methyl orange were obtained with PCL-PPy/MNPs. Recycling experiments showed no loss of activity even after five cycles of recycling. Comparative analysis of PCL-PPy, PCL-MNP, and PCL-PPy/MNP results indicated the synergistic action of PPy and MNPs in dye degradation. High-performance liquid chromatography and mass spectroscopy analyses confirmed dye degradation after treatment with a fabricated microreactor. PPy might have acted as a capturer of the dye molecule and MNPs as a catalyst, thereby enhancing the efficiency of dye degradation. Additionally, the PCL-PPy/Cu composite exhibited strong antimicrobial properties against Grampositive (Staphylococcus aureus) and Gram-negative bacteria (Escherichia coli) with no cytotoxicity as measured by the MTT assay. Therefore, the fabricated microreactor film has promising applications in various fields.

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“…Countless attempts have been made in recent years to engineer polymeric or derived polymeric composite materials that possess excellent CO 2 adsorption attributes. In this regard, there is a rising interest in exploring the avenues of polymer-COF membranes, since COFs, due to their astounding property of organic coordination framework, offer enhanced processability and compatibility to be employed as membrane materials with varied polymers. − COF-membranes have been assessed for their usefulness in energy storage, water purification, biofuel generation, and other fields, − and it is projected that the field of membrane technology will increase in the next years. Many techniques for fabricating COF membranes have been investigated, including solvothermal, interfacial polymerization, layer-by-layer stacking, and so on, − but the demand for simple and active production methods is still unmet.…”

Section: Introductionmentioning

confidence: 99%

Assessing CO₂ Adsorption Behavior onto Free-Standing, Flexible Organic Framework-PVDF Composite Membrane: An Empirical Modeling and Validation of an Experimental Data Set

Bora,

Borpatra Gohain,

Barman

et al. 2023

ACS Omega

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Covalent organic framework (COF) materials have greatly expanded their range in a variety of applications since the cognitive goal of a highly organized and durable adsorbent is quite rational. The characteristics of a conjugated organic framework are combined with an industrially relevant polymer to produce a composite membrane optimized for selectively adsorbing carbon dioxide (CO2) gas across a wide temperature range. Additionally, treatment of the composite membrane with cold atmospheric plasma (CAP) that specifically enhanced the parent membrane’s surface area by 36% is established. Following CAP treatment, the membrane accelerates the CO2 uptake by as much as 66%. This is primarily due to a Lewis acid–base interaction between the electron-deficient carbon atom of CO2 and the newly acquired functionalities on the COFs@PVDF membrane’s surface. In particular, the C–N bonds, which appear to be a higher electron density site, play a key role in this interaction. Moreover, the empirical model proposed here has confirmed CO2 adsorption phenomena in the COF@PVDF composite membrane, which closely matches the findings from the experimental data set under designated operating conditions. As a result, the current study may pave the way for future design work as well as refine the covalent framework polymer composite membrane’s features, revealing a more sophisticated approach to addressing CO2 capture problems.

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Covalent Organic Framework Cladding on Peptide-Amphiphile-Based Biomimetic Catalysts

Cited by 12 publications

References 58 publications

Improving the Bioactivity and Stability of Embedded Enzymes by Covalent Organic Frameworks

Improving the Bioactivity and Stability of Embedded Enzymes by Covalent Organic Frameworks

Novel Capturer-Catalyst Microreactor System with a Polypyrrole/Metal Nanoparticle Composite Incorporated in the Porous Honeycomb-Patterned Film

Assessing CO₂ Adsorption Behavior onto Free-Standing, Flexible Organic Framework-PVDF Composite Membrane: An Empirical Modeling and Validation of an Experimental Data Set

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Covalent Organic Framework Cladding on Peptide-Amphiphile-Based Biomimetic Catalysts

Cited by 12 publications

References 58 publications

Improving the Bioactivity and Stability of Embedded Enzymes by Covalent Organic Frameworks

Improving the Bioactivity and Stability of Embedded Enzymes by Covalent Organic Frameworks

Novel Capturer-Catalyst Microreactor System with a Polypyrrole/Metal Nanoparticle Composite Incorporated in the Porous Honeycomb-Patterned Film

Assessing CO2 Adsorption Behavior onto Free-Standing, Flexible Organic Framework-PVDF Composite Membrane: An Empirical Modeling and Validation of an Experimental Data Set

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Product

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Assessing CO₂ Adsorption Behavior onto Free-Standing, Flexible Organic Framework-PVDF Composite Membrane: An Empirical Modeling and Validation of an Experimental Data Set