Redox-Active Biomolecular Architectures and Self-Assembled Monolayers Based on a Cyclodecapeptide Regioselectively Addressable Functional Template

Devillers, Charles H.; Boturyn, Didier; Bucher, Christophe; Dumy, Pascal; Labbé, Pierre; Moutet, Jean‐Claude; Royal, Guy; Saint‐Aman, Eric

doi:10.1021/la060491m

Cited by 16 publications

(15 citation statements)

References 48 publications

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“…4). The increase of the Fc number in the stem-loop structure is associated with a logarithmic decrease of the E which tends to the theoretical value of 58 mV corresponding to a reversible redox system [11]. This improvement of system reversibility could be correlated to the thermodynamic study described previously that revealed a better stability of the hairpin structure for ODNs modified with a higher number of Ferrocenes (Table 1).…”

Section: Electrochemical Study Of Fc-odnsupporting

confidence: 76%

Synthesis of electrochemical probes for nucleic acid detection

Chatelain

Chaix

Brisset

et al. 2008

Sensors and Actuators B: Chemical

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Section: Electrochemical Study Of Fc-odnsupporting

confidence: 76%

Synthesis of electrochemical probes for nucleic acid detection

Chatelain

Chaix

Brisset

et al. 2008

Sensors and Actuators B: Chemical

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“…Ferrocenyl groups were attached to a cyclodecapeptide (designed for anion sensing) and immobilized on a gold electrode [359]. Using CV, the Laviron method was applied only to the cathodic branch of the E p vs. υ plot (only for overpotentials higher than 0.1 V) as the anodic wave became indistinguishable at scan rates > 100V/s.…”

Section: Bridge and Diluentmentioning

confidence: 99%

Electrochemistry of redox-active self-assembled monolayers

Eckermann

Feld

Shaw

et al. 2010

Coordination Chemistry Reviews

507

492

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Redox-active self-assembled monolayers (SAMs) provide an excellent platform for investigating electron transfer kinetics. Using a well-defined bridge, a redox center can be positioned at a fixed distance from the electrode and electron transfer kinetics probed using a variety of electrochemical techniques. Cyclic voltammetry, AC voltammetry, electrochemical impedance spectroscopy, and chronoamperometry are most commonly used to determine the rate of electron transfer of redoxactivated SAMs. A variety of redox species have been attached to SAMs, and include transition metal complexes (e.g., ferrocene, ruthenium pentaammine, osmium bisbipyridine, metal clusters) and organic molecules (e.g., galvinol, C 60 ). SAMs offer an ideal environment to study the outer-sphere interactions of redox species. The composition and integrity of the monolayer and the electrode material influence the electron transfer kinetics and can be investigated using electrochemical methods. Theoretical models have been developed for investigating SAM structure. This review discusses methods and monolayer compositions for electrochemical measurements of redox-active SAMs.

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“…37,38 Interestingly, they have also been used for the design of a nanometer scale redox active biomolecular architecture by using ferrocenyl units. 39 In this work we provide a comprehensive study of (i) the specic binding, (ii) the inuence of the residence time (i.e. contact time), and (iii) the inuence of the retraction rate on the hostguest rupture forces between a cyclodecapeptide scaffold bearing a monovalent or a tetravalent adamantyl (guest) group and two types of b-CD (host) covered substrates.…”

Section: Introductionmentioning

confidence: 99%

Multivalency: influence of the residence time and the retraction rate on rupture forces measured by AFM

et al. 2015

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International audienceThe Bell-Evans theory relative to rupture forces between non-covalently interacting molecules predicts that the rupture force increases linearly with the logarithm of the force loading rate. Here we investigate by force spectroscopy performed with an atomic force microscope (AFM) the rupture forces between surfaces covered by beta-cyclodextrin (beta-CD) molecules and AFM tips coated with adamantane (AD) groups. The beta-CD molecules are either deposited through a self-assembled monolayer (SAM) or grafted on poly(allylamine hydrochloride) chains (PAH-CD) that are adsorbed on the substrate. The AD groups are fixed covalently on the AFM tip through either a one-AD or a four-AD platform linked to the tip though a PEO chain. It is found that while the rupture forces between AFM tips covered with tetravalent AD molecules and SAM-CD surfaces do not exceed twice those found with tips covered by monovalent AD molecules, the rupture forces increase by a factor of 20 on PAH-CD substrates for a tetravalent AD covered tip compared to a monovalent one. Thus, there seems to exist a synergistic effect between the molecule multivalence and the polymeric nature of the CD-covered substrate. As found in the literature, we observe an increase of the intensity of the rupture forces between the AD-covered AFM tip and the beta-CD covered substrate with the contact time over timescales up to several seconds. Finally, we find that when the host-guest system involves the multivalency of the AD guest and/or the polymeric nature of the host the mean rupture force decreases with the loading rate in contrast to what is predicted by the Bell-Evans theory. We tentatively explain this ``anti-Bell-Evans'' behavior by the possibility of rebinding during the rupture process. This effect should have important implications in the understanding of forces at the cellular level

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Redox-Active Biomolecular Architectures and Self-Assembled Monolayers Based on a Cyclodecapeptide Regioselectively Addressable Functional Template

Cited by 16 publications

References 48 publications

Synthesis of electrochemical probes for nucleic acid detection

Synthesis of electrochemical probes for nucleic acid detection

Electrochemistry of redox-active self-assembled monolayers

Multivalency: influence of the residence time and the retraction rate on rupture forces measured by AFM

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