Colette Lebrun scite author profile

Dye-sensitized photo-electrochemical cells (DS-PECs) for water splitting hold promises for the large-scale storage of solar energy in the form of (solar) fuels, owing to the low cost and ease to process of their constitutive photoelectrode materials. The efficiency of such systems ultimately depends on our capacity to promote unidirectional light-driven electron transfer from the electrode substrate to a catalytic moiety. We report here on the first noble-metal free and covalent dyecatalyst assembly able to achieve photo-electrochemical visible light-driven H 2 evolution in mildly acidic aqueous conditions when grafted onto p-type NiO electrode substrate.Photosynthesis has inspired for many years the development of water splitting dye-sensitized photo-electrochemical cells (DS-PECs) for hydrogen production.1-3 A key step has been achieved very recently with the report of the first fully operative tandem DS-PEC.4 In such devices, limitation currently arises from the photocathode performances. Therefore different architectures based on the co-grafting4,5 of catalyst and dye onto nickel oxide (NiO), layerby-layer6 or supramolecular linkage of the catalyst to a grafted dye7 have been investigated. NiO is a p-type transparent conducting oxide specifically suitable for fast hole injection from the highest occupied molecular orbital (HOMO) of the excited dye.8 Then H 2 evolution requires that the photogenerated electron is efficiently and rapidly transferred to a catalyst. In that perspect, push-pull organic dyes appear as particularly attractive since they combine large absorptivity in the visible spectrum and spatial charge separation in the Europe PMC Funders Author ManuscriptsEurope PMC Funders Author Manuscripts excited state that limits the undesired recombination reaction from the reduced dye to the NiO electrode.9,10 The push-pull architecture is also instrumental to foster unilateral electron transfer through direct connection of the acceptor moiety, where the lowest unoccupied molecular orbital (LUMO) is centered and the photogenerated electron located, to the catalyst. We report here the first example of a covalent dye-catalyst molecular assembly integrated in an operative photoelectrode for H 2 evolution (Figure 1).We previously reported that, upon grafting on NiO, an easily affordable push-pull dye based on a triarylamine electron-donor part and an ethyl cyanoacetate electron-acceptor part separated by a thiophene unit generates large photocurrents in the presence of an irreversible electron acceptor in mildly acidic aqueous solution (pH 4-5).11 Cobalt diimine-dioxime complexes are proven catalysts for H 2 evolution at low overvoltage.12,13 When grafted onto electrode surfaces, they display sustained activity in pH = 4.5 aqueous solution14 and tolerance to oxygen.15 These features make them particularly attractive for incorporation into dye-sensitized H 2 -evolving photoelectrodes. To prepare a covalent dye-catalyst assembly, we first synthesized a terminal alkyne derivative (1, Figure 2) of the a...

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Hepatocyte Targeting and Intracellular Copper Chelation by a Thiol-Containing Glycocyclopeptide

Pujol

et al. 2010

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Metal overload plays an important role in several diseases or intoxications, like in Wilson's disease, a major genetic disorder of copper metabolism in humans. To efficiently and selectively decrease copper concentration in the liver that is highly damaged, chelators should be targeted at the hepatocytes. In the present work, we synthesized a molecule able to both lower intracellular copper, namely Cu(I), and target hepatocytes, combining within the same structure a chelating unit and a carbohydrate recognition element. A cyclodecapeptide scaffold displaying a controlled conformation with two independent faces was chosen to introduce both units. One face displays a cluster of carbohydrates to ensure an efficient recognition of the asialoglycoprotein receptors, expressed on the surface of hepatocytes. The second face is devoted to metal ion complexation thanks to the thiolate functions of two cysteine side-chains. To obtain a chelator that is active only once inside the cells, the two thiol functions were oxidized in a disulfide bridge to afford the glycopeptide P(3). Two simple cyclodecapeptides modeling the reduced and complexing form of P(3) in cells proved a high affinity for Cu(I) and a high selectivity with respect to Zn(II). As expected, P(3) becomes an efficient Cu(I) chelator in the presence of glutathione that mimics the intracellular reducing environment. Finally, cellular uptake and ability to lower intracellular copper were demonstrated in hepatic cell lines, in particular in WIF-B9, making P(3) a good candidate to fight copper overload in the liver.

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Colette Lebrun

Covalent Design for Dye-Sensitized H₂-Evolving Photocathodes Based on a Cobalt Diimine–Dioxime Catalyst

Hepatocyte Targeting and Intracellular Copper Chelation by a Thiol-Containing Glycocyclopeptide

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Colette Lebrun

Covalent Design for Dye-Sensitized H2-Evolving Photocathodes Based on a Cobalt Diimine–Dioxime Catalyst

Hepatocyte Targeting and Intracellular Copper Chelation by a Thiol-Containing Glycocyclopeptide

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Covalent Design for Dye-Sensitized H₂-Evolving Photocathodes Based on a Cobalt Diimine–Dioxime Catalyst