Single occupancy spectroelectrochemistry of freely diffusing flavin mononucleotide in zero-dimensional nanophotonic structures

Zaino, Lawrence P.; Grismer, Dane A.; Han, Donghoon; Crouch, Garrison M.; Bohn, Paul W.

doi:10.1039/c5fd00072f

Cited by 42 publications

(64 citation statements)

References 43 publications

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“…Flavin is brightly fluorescent in the oxidized state and dim in the reduced state, while the semi-quinone is somewhere in between. 20, 28 Chronofluorometry experiments of FMN showed the ability to cycle between the bright (oxidized) and dark (reduced) states of the molecule. However, cyclic potential sweep fluorescence of the same species showed a scan rate dependence wherein at fast scan rates the emission spectra is similar to the bulk solution measurement, while at slow scan rates distinct intermediates states are observed between the oxidized and reduced species.…”

Section: Discussionmentioning

confidence: 99%

“…However, cyclic potential sweep fluorescence of the same species showed a scan rate dependence wherein at fast scan rates the emission spectra is similar to the bulk solution measurement, while at slow scan rates distinct intermediates states are observed between the oxidized and reduced species. 28 It was hypothesized that this appearance was a result of the stabilization of the semi-quinone in the zero-mode waveguide nanopore. The speciation observed in our experiments agrees with this hypothesis.…”

Section: Discussionmentioning

confidence: 99%

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SERS speciation of the electrochemical oxidation–reduction of riboflavin

Bailey

Schultz

2016

Analyst

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The reduction and oxidation of the flavin system is an important electron transfer reaction in biological systems. Several reaction pathways exist to connect oxidized to fully reduced riboflavin, each with unique intermediates including a semi-quinone radical. By performing surface-enhanced Raman scattering (SERS) with simultaneous electrochemical detection of riboflavin at different pH values, we are able to correlate reversible changes in spectral features to the current changes observed in the cyclic voltammetry. Multivariate curve resolution analysis of the SERS spectra indicates that three distinct components were present at the SERS electrode at each pH during the potential sweep. To verify and better understand the variations in Raman bands across the voltammogram, density functional theory (DFT) calculations were performed to model the effect of pH and oxidation state on the riboflavin Raman spectrum. The calculated spectra show qualitative agreement with the species identified in the chemometric analysis. This combination of results indicates the presence of the oxidized, semi-quinone, and reduced forms of riboflavin and provides insight into the mechanism of the flavin redox system.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

SERS speciation of the electrochemical oxidation–reduction of riboflavin

Bailey

Schultz

2016

Analyst

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“…[38] There are many variants of this type of experiment for the monitoring of enzyme kinetics,a shasb een recently reviewed. [41] FMN is aredox enzyme cofactor,and closely related electrochemically and optically to the ubiquitous enzyme cofactor flavin adenine dinucleotide.I mportantly, when excited, the oxidized form is fluorescent but the reduced form is less fluorescent. [40] A particularly exciting development in this field is the development by Bohn and co-workers of arrays of zero-mode waveguides for spectroelectrochemical investigation of as ingle flavin mononucleotide (FMN) imaged in aw idefield format.…”

Section: Massively Parallel Near-field Measurementsmentioning

confidence: 99%

Single‐Molecule Sensors: Challenges and Opportunities for Quantitative Analysis

Gooding¹,

2016

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Measurement science has been converging to smaller and smaller samples, such that it is now possible to detect single molecules. This Review focuses on the next generation of analytical tools that combine single-molecule detection with the ability to measure many single molecules simultaneously and/or process larger and more complex samples. Such single-molecule sensors constitute a new type of quantitative analytical tool, as they perform analysis by molecular counting and thus potentially capture the heterogeneity of the sample. This Review outlines the advantages and potential of these new, quantitative single-molecule sensors, the measurement challenges in making single-molecule devices suitable for analysis, the inspiration biology provides for overcoming these challenges, and some of the solutions currently being explored.

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“…Moreover, reduction and oxidation half‐reactions were shown to be independent . The second case concerns immobilized FAD and flavin mononucleotide freely diffusing in the nanopores . A similar setup allowed to study the spectroelectrochemical behavior, and especially fluorescence arising from single‐electron transfer events of these two cofactors.…”

Section: Kineticsmentioning

confidence: 99%

Micro‐ and Nanoscopic Imaging of Enzymatic Electrodes: A Review

2019

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Redox enzymes, which catalyze electron transfer reactions in living organisms, can be used as selective and sensitive bioreceptors in biosensors, or as efficient catalysts in biofuel cells. In these bioelectrochemical devices, the enzymes are immobilized at a conductive surface, the electrode, with which they must be able to exchange electrons. Different physicochemical methods have been coupled to electrochemistry to characterize the enzyme‐modified electrochemical interface. In this Review, we summarize most efforts performed to investigate the enzymatic electrodes at the micro‐ and even nanoscale, thanks to microscopy techniques. Contrary to electrochemistry, which gives only a global information about all processes occurring at the electrode surface, microscopy offers a spatial resolution. Several techniques have been implemented; mostly scanning probe microscopies like atomic force microscopy, scanning tunneling microscopy, and scanning electrochemical microscopy, but also scanning electron microscopy and fluorescence microscopy. These studies demonstrate that various information can be obtained thanks to microscopy at different scales. Electrode imaging has been performed to confirm the presence of enzymes, to quantify and localize the biomolecules, but also to evaluate the morphology of immobilized enzymes, their possible conformation changes upon turnover, and their orientation at the electrode surface. Local redox activity has also been imaged and kinetics has been resolved.

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Single occupancy spectroelectrochemistry of freely diffusing flavin mononucleotide in zero-dimensional nanophotonic structures

Cited by 42 publications

References 43 publications

SERS speciation of the electrochemical oxidation–reduction of riboflavin

SERS speciation of the electrochemical oxidation–reduction of riboflavin

Single‐Molecule Sensors: Challenges and Opportunities for Quantitative Analysis

Micro‐ and Nanoscopic Imaging of Enzymatic Electrodes: A Review

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