Duality in the Escherichia coli and methicillin resistant Staphylococcus aureus reduction mechanism under actinic light on innovative co-sputtered surfaces

The kinetics of bacterial reduction of Staphylococcus aureus (MRSA) on co-sputtered TiO2/Cu-polyester (TiO2/Cu-PES) was found to be little dependent on the applied light dose. But in the case of Escherichia coil, the bacterial reduction kinetics was observed to be strongly dependent on the applied light dose. The reasons for the different effect of the applied light dose on the bacterial reduction are discussed. Mechanistic considerations are suggested to account for this observation.TiO2/Cu-PES obtained by direct current magnetron co-sputtering and the bacterial reduction features compared to PES sputtered individually by TiO2 and Cu. This study presents the first evidence for the stabilizing effect of TiO2 on the amounts of the Cu released during bacterial inactivation by co-sputtered surfaces compared to sequential sputtering of Ti and/or Cu on PES. The release of Cu-monitored in the ppb range by inductively coupled plasma-mass spectrometry (ICP-MS) is indicative of an oligodynamic effect leading to bacterial reduction. The bacterial reduction of MRSA ATCC 43300 on co-sputtered TiO2/Cu led to a 5 log(10) (99.999%) reduction within 120 min in the dark and 60 min under low intensity actinic light. Diffuse reflectance spectroscopy (DRS), transmission electron microscopy (TEM) and X-ray fluorescence (XRF) describe the TiO2/Cu surfaces investigated in this study. (C) 2015 Elsevier B.V. All rights reserved.

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Myriam Koumba Sarah Ballo, Juan Kiwi, Danièle Laub, César Pulgarin, Sami Rtimi, Rosendo Sanjines
Elsevier, 2015
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https://infoscience.epfl.ch/record/210417?ln=fr

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New evidence for TiO2 uniform surfaces leading to complete bacterial reduction in the dark: Critical issues

Juan Kiwi, Danièle Laub, Jelena Nesic, César Pulgarin, Sami Rtimi

This study presents new evidence for the events leading to Escherichia coil reduction in the absence of light irradiation on TiO2-polyester (from now on TiO2-PES. By transmission electron microscopy (TEM) the diffusion of TiO2 NP's aggregates with the E. coil outer lipo-polyssacharide (LPS) layer is shown to be a prerequisite for the loss of bacterial cultivability. Within 30 min in the dark the TiO2 aggregates interact with E. coil cell wall leading within 120 min to the complete loss of bacterial cultivability on a TiO2-PES 5% TiO2 sample. The bacterial reduction was observed to increase with a higher TiO2 loading on the PES up to 5%. Bacterial disinfection on TiO2-PES in the dark was slower compared to the runs under low intensity simulated sunlight light irradiation. The interaction between the TiO2 aggregates and the E. coil cell wall is discussed in terms of the competition between the TiO2 units collapsing to form TiO2-aggregates at a physiologic pH-value followed by the electrostatic interaction with the bacteria surface. TiO2-PES samples were able to carry repetitive bacterial inactivation. This presents a potential for practical applications. X-ray photoelectron spectroscopy (XPS) evidence was found for the reduction of Ti4+ to Ti3+ contributing to redox interactions between TiO2-PES and the bacterial cell wall. Insight is provided into the mechanism of interaction between the E. coil cell wall and TiO2 NP's. The properties of the TiO2-PES surface like percentage atomic concentration, TiO2-loading, optical absorption, surface charge and crystallographic phases are reported in this study. (C) 2014 Elsevier B.V. All rights reserved.

Elsevier Science Bv2014

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A TEM study of Ni interfaces formed during activation of SOFC anodes in H-2: Influence of grain boundary symmetry and segregation of impurities

Cécile Hébert, Aïcha Hessler-Wyser, Quentin Thomas Jeangros, Jan Van Herle

The electrochemical properties of a solid oxide fuel cell depend on many parameters, including - on the anode side - the connectivity of the Ni network and the segregation of impurities at active points. In this work, advanced scanning transmission electron microscopy techniques are employed to assess 1) the influence of the symmetry of NiO/NiO grain boundaries on the percolation of the Ni phase after activation and 2) the segregation of impurities at these new Ni interfaces that form during NiO reduction. Automated crystal orientation mapping in the transmission electron microscope reveals that coherent NiO twin boundaries remain intact during reduction, while NiO grains separated by an incoherent boundary detach from each other when reducing to Ni. Small Ni domains twinned with respect, to the larger Ni grains are also observed to form during reduction of the NiO phase. Energy-dispersive X-ray spectroscopy reveals that Al and Si impurities, which are present in the raw materials, may block electrochemically active points of the anode by segregating in the form of a glassy film at the interfaces/ surfaces that appeared during activation. This oxidised film supports Ni nanoparticles that precipitated from volatile Ni hydroxide. (c) 2015 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.

Pergamon-Elsevier Science Ltd2016

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In situ Reduction and Oxidation of Nickel from Solid Oxide Fuel Cells in a Transmission Electron Microscope

Antonin Faes, Aïcha Hessler-Wyser, Quentin Thomas Jeangros, Jan Van Herle

Environmental transmission electron microscopy was used to characterize in situ the reduction and oxidation of nickel from a Ni/YSZ solid oxide fuel cell anode support between 300-500°C. The reduction is done under low hydrogen pressure. The reduction initiates at the NiO/YSZ interface, then moves to the center of the NiO grain. At higher temperature the reduction occurs also at the free NiO surface and the NiO/NiO grain boundaries. The growth of Ni is epitaxial on its oxide. Due to high volume decrease, nanopores are formed during reduction. During oxidation, oxide nanocrystallites are formed on the nickel surface. The crystallites fill up the nickel porosity and create an inhomogeneous structure with remaining voids. This change in structure causes the nickel oxide to expand during a RedOx cycle.

2009

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Microscopie électronique en transmission

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Spectrométrie de fluorescence des rayons X

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Le terme bactérie est un nom vernaculaire qui désigne certains organismes vivants microscopiques et procaryotes présents dans tous les milieux. Le plus souvent unicellulaires, elles sont parfois plu