Eleni Bletsa scite author profile

h i g h l i g h t sIn situ growth of small magnetite nanoparticles at natural clay nanotubes (halloysite). Novel, facile synthetic strategy involving a modified wetimpregnation method. Efficient catalytic decomposition of pentachlorophenol by magnetite@halloysite hybrids. Catalytic efficiency of hybrids significant higher compared to free nanoparticles. Hybrids can be reused for multiple catalytic cycles without noteworthy loss of activity.

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Antioxidant Hydrogen-Atom-Transfer to DPPH Radicals by Hybrids of {Hyaluronic-Acid Components}@SiO₂

Theofanous

Sarli

Fragou

et al. 2022

Langmuir

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Hydrogen-atom-transfer (HAT) is among the key mechanisms of antioxidant and antiradical activity in natural systems. Hyaluronic acid (HyA) is currently used extensively in health and cosmetics applications. Herein it is shown that {HyA@SiO2} hybrids based on hyaluronic acid (HyA) components grafted on SiO2 nanoparticles enable significant HAT activity versus DPPH radicals, while the homogeneous HyA counterparts are practically inactive. The {HyA@SiO2} hybrids consist of the two building blocks of HyA [d-glucuronic acid (GLA) and N-acetyl-d-glucosamine (GLAM)] covalently grafted on SiO2 nanoparticles. Based on the kinetic-thermodynamic Arrhenius study, we show that the {SiO2@GLA} hybrids operate spontaneously via hydrogen-atom-transfer (HAT) with a low activation energy barrier, i.e., by ΔΕ α ∼ 20 kJ/mol vs the nongrafted counterparts. Moreover, a doubly grafted {GLA@SiO2@GLAM} nanohybrid, i.e. that contains both components of HyA, shows the most significant antioxidant activity. FTIR and Raman analysis reveal that local H-bonding between the SiO2 matrix, GLA, and GLAM in {GLA@SiO2@GLAM} decreases the activation barrier of the HAT mechanism. Thus, {GLA@SiO2@GLAM} nanohybrids exemplify a novel family of materials that are not the mere sum of their components. The present case is the first example of non-phenolic molecules being able to perform antiradical HAT, opening new perspectives not foreseen until today.

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Oxidative catalytic evolution of redox- and spin-states of a Fe-phthalocyanine studied by EPR

Bletsa

Solakidou

Louloudi

et al. 2016

Chemical Physics Letters

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Eleni Bletsa

Interfacial Hydrogen Atom Transfer by nanohybrids based on Humic Acid Like Polycondensates

Axial ligand effect on the catalytic activity of biomimetic Fe-porphyrin catalyst: An experimental and DFT study

Halloysite nanotube-magnetic iron oxide nanoparticle hybrids for the rapid catalytic decomposition of pentachlorophenol

Antioxidant Hydrogen-Atom-Transfer to DPPH Radicals by Hybrids of {Hyaluronic-Acid Components}@SiO₂

Oxidative catalytic evolution of redox- and spin-states of a Fe-phthalocyanine studied by EPR

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Eleni Bletsa

Interfacial Hydrogen Atom Transfer by nanohybrids based on Humic Acid Like Polycondensates

Axial ligand effect on the catalytic activity of biomimetic Fe-porphyrin catalyst: An experimental and DFT study

Halloysite nanotube-magnetic iron oxide nanoparticle hybrids for the rapid catalytic decomposition of pentachlorophenol

Antioxidant Hydrogen-Atom-Transfer to DPPH Radicals by Hybrids of {Hyaluronic-Acid Components}@SiO2

Oxidative catalytic evolution of redox- and spin-states of a Fe-phthalocyanine studied by EPR

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Antioxidant Hydrogen-Atom-Transfer to DPPH Radicals by Hybrids of {Hyaluronic-Acid Components}@SiO₂