In Operando Analysis of Diffusion in Porous Metal‐Organic Framework Catalysts

Gao, Wen; Cardenal, Ashley D.; Wang, Chen‐Hao; Powers, Dennis A.

doi:10.1002/chem.201804490

Cited by 48 publications

(62 citation statements)

References 119 publications

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“…Hence, the effect of the bead size on the enzyme performance under aqueous conditions is more dramatic when using bulky and hydrophobic substrates (TFA and benzaldehyde) than using small and polar ones (acetone and formic acid). In porous and functionalized materials, both the polarity and size of the substrates affect their diffusion through the carriers where the active phase is immobilized [4,33]. Furthermore, the nature of the solid materials (hydrophilic or hydrophobic) can also hamper the diffusion of the substrates through their porous microstructure [14].…”

Section: Functional Heterogeneity Of a Co-immobilized His-bsadh/nadh mentioning

confidence: 99%

“…For this reason, enzyme technologists are encouraged to develop 2 of 16 highly active and stable heterogeneous biocatalysts [2]; however, molecular characterization of the supported enzymes is rather limited. Thus far, techniques for the molecular characterization of solid-supported enzymes are scarce, unlike chemical catalysis, where molecular characterization drives the design and optimization of heterogeneous catalysts [3,4]. Recently, several authors have deeply reviewed different techniques for the advanced characterization of heterogeneous biocatalysts [5][6][7].…”

Section: Introductionmentioning

confidence: 99%

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Deciphering the Effect of Microbead Size Distribution on the Kinetics of Heterogeneous Biocatalysts through Single-Particle Analysis Based on Fluorescence Microscopy

et al. 2019

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Understanding the functionality of immobilized enzymes with spatiotemporal resolution and under operando conditions is an unmet need in applied biocatalysis, as well as priceless information to guide the optimization of heterogeneous biocatalysts for industrial purposes. Unfortunately, enzyme immobilization still relies on trial-and-error approximations that prevail over rational designs. Hence, a modern fabrication process to achieve efficient and robust heterogeneous biocatalysts demands comprehensive characterization techniques to track and understand the immobilization process at the protein–material interface. Recently, our group has developed a new generation of self-sufficient heterogeneous biocatalysts based on alcohol dehydrogenases co-immobilized with nicotinamide cofactors on agarose porous microbeads. Harnessing the autofluorescence of NAD+(P)H and using time-lapse fluorescence microscopy, enzyme activity toward the redox cofactors can be monitored inside the beads. To analyze these data, herein we present an image analytical tool to quantify the apparent Michaelis–Menten parameters of alcohol dehydrogenases co-immobilized with NAD(P)+/H at the single-particle level. Using this tool, we found a strong negative correlation between the apparent catalytic performance of the immobilized enzymes and the bead radius when using exogenous bulky substrates in reduction reactions. Therefore, applying image analytics routines to microscopy studies, we can directly unravel the functional heterogeneity of different heterogeneous biocatalyst samples tested under different reaction conditions.

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Section: Functional Heterogeneity Of a Co-immobilized His-bsadh/nadh mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Deciphering the Effect of Microbead Size Distribution on the Kinetics of Heterogeneous Biocatalysts through Single-Particle Analysis Based on Fluorescence Microscopy

et al. 2019

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“…where equation [1] gives the chemical shift (δ) of CO2 located in a crystal at angle θ relative to B0, given residual chemical shift anisotropy parameters δ// and δ⊥. Equation [2] gives the effective diffusion coefficient for CO2 in a given crystal obtained from PFG NMR measurements, where the magnetic field gradient is applied along the z-direction (Deff,z). Equations [3] and [4] give the signal decay observed in pulsed-field gradient NMR experiments performed with the 13-interval sequence, 46 where I(b) is the integrated signal intensity for a given b value, g is the applied magnet field gradient strength, b0 is the b value at the smallest g used, and γ is the gyromagnetic ratio of the studied nucleus (see also Figure S13).…”

Section: Synthesis Of Zn2(dobpdc)mentioning

confidence: 99%

Influence of Pore Size on Carbon Dioxide Diffusion in Two Isoreticular Metal–Organic Frameworks

et al. 2020

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The rapid diffusion of molecules in porous materials is critical for numerous applications including separations, energy storage, sensing, and catalysis. A common strategy for tuning guest diffusion rates is to vary the material pore size, although detailed studies that isolate the effect of changing this particular variable are lacking. Here, we begin to address this challenge by measuring the diffusion of carbon dioxide in two isoreticular metal-organic frameworks featuring channels with different diameters, Zn2(dobdc) (dobdc 4-= 2,5dioxidobenzene-1,4-dicarboxylate) and Zn2(dobpdc) (dobpdc 4− = 4,4′-dioxidobiphenyl-3,3′-dicarboxylate), using pulsed field gradient NMR spectroscopy. An increase in the pore diameter from 15 Å in Zn2(dobdc) to 22 Å in Zn2(dobpdc) is accompanied by an increase in the self-diffusion of CO2 by a factor of 4 to 6, depending on the gas pressure. Analysis of the diffusion anisotropy in Zn2(dobdc) reveals that the self-diffusion coefficient for motion of CO2 along the framework channels is at least 10,000 times greater than for motion between the framework channels. Our findings should aid the design of improved porous materials for a range of applications where diffusion plays a critical role in determining performance.

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“…These key features responsible for its success as DDS are the following: i) nanoscale materials; nowadays there are diverse synthetic methods for the preparation of MOFs at the nanoscale [13,[37][38][39][40], and these nanosized MOFs (below 200 nm) are superior as DDS due to their higher cellular uptake (internalization rates), longer bloodcirculation times, and enhanced permeability and retention (EPR) effect to increase the drug concentration at tumor regions [43, 52, 61-]. Moreover, the smaller the size (i.e., shorter diffusion paths [62,63]) the faster the delivery kinetics are.…”

Section: Key Features Of Mofs For Drug Deliverymentioning

confidence: 99%

Nanoscale metal–organic frameworks as key players in the context of drug delivery: evolution toward theranostic platforms

Carrillo‐Carrión

2019

Anal Bioanal Chem

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In Operando Analysis of Diffusion in Porous Metal‐Organic Framework Catalysts

Cited by 48 publications

References 119 publications

Deciphering the Effect of Microbead Size Distribution on the Kinetics of Heterogeneous Biocatalysts through Single-Particle Analysis Based on Fluorescence Microscopy

Deciphering the Effect of Microbead Size Distribution on the Kinetics of Heterogeneous Biocatalysts through Single-Particle Analysis Based on Fluorescence Microscopy

Influence of Pore Size on Carbon Dioxide Diffusion in Two Isoreticular Metal–Organic Frameworks

Nanoscale metal–organic frameworks as key players in the context of drug delivery: evolution toward theranostic platforms

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