Nemanja Anicˇić scite author profile

Nemanja Anicˇić

2Publications

49Citation Statements Received

60Citation Statements Given

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Affiliations

Jožef Stefan Institute

Publications

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Fewer Defects in the Surface Slows the Hydrolysis Rate, Decreases the ROS Generation Potential, and Improves the Non‐ROS Antimicrobial Activity of MgO

Anicˇić

Vukomanović

Koklicˇ

et al. 2018

Small

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Magnesium oxide (MgO) is recognised as exhibiting a contact-based antibacterial activity. However, a comprehensive study of the impact of atomic-scale surface features on MgO's antibacterial activity is lacking. In this study, the nature and abundance of the native surface defects on different MgO powders are thoroughly investigated. Their impacts on the hydrolysis kinetics, antibacterial activity against Escherichia coli (ATCC 47076), Staphylococcus epidermidis and Pseudomonas aeruginosa and the reactive oxygen species (ROS) generation potential are determined and explained. It is shown that a reduction in the abundance of low-coordinated oxygen atoms on the surface of the MgO improves its resistance to both hydrolysis and antibacterial activity. The ROS generation potential, determined in-situ using a fluorescence microplate assay and electron paramagnetic resonance spectroscopy, is not an inherent property of the studied MgO, rather it is a side product of hydrolysis (only for the most highly defected MgO particles) and/or a consequence of the MgO/bacteria interaction. The evaluation of the mutual correlations of the hydrolysis, the antibacterial activity and the ROS generation, with their origin in the surface defects' peculiarities, led to the conclusion that the acid/base reaction between the MgO surface and the bacterial wall contributes considerably to the MgO's antibacterial activity.

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MgO Antibacterial Properties: Fewer Defects in the Surface Slows the Hydrolysis Rate, Decreases the ROS Generation Potential, and Improves the Non‐ROS Antimicrobial Activity of MgO (Small 26/2018)

Anicˇić

Vukomanović

Koklicˇ

et al. 2018

Small

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In article number https://doi.org/10.1002/smll.201800205, Marija Vukomanović and co‐workers determine the impact of native surface defects on different MgO powders to a non‐reactive‐oxygen‐species (ROS), contact‐based mechanism of antibacterial activity. A reduction in the abundance of low‐coordinated oxygen atoms on the surface of the MgO improves its resistance to both hydrolysis and antibacterial activity. ROS generation potential, is not an inherent property of the studied MgO, rather it is a side product of hydrolysis and/or a consequence of the MgO/bacteria interaction.

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