We show by Molecular Dynamics that amphiphilic Au nanoparticles (NP) with a diameter of 4 nm generate curvature in phosphatidylcholine lipid membranes. NPs generate negative curvature when they adsorb on...
Transmission of viruses through contact with contaminated
surfaces
is an important pathway for the spread of infections. Antiviral surface
coatings are useful to minimize such risks. Current state-of-the-art
approaches toward antiviral surface coatings either involve metal-based
materials or complex synthetic polymers. These approaches, however,
even if successful, will have to face great challenges when it comes
to large-scale applications and their environmental sustainability.
Here, an antiviral surface coating was prepared by spin-coating lignin,
a natural biomass residue of the paper production industry. We show
effective inactivation of herpes simplex virus type 2 (>99% after
30 min) on a surface coating that is low-cost and environmentally
sustainable. The antiviral mechanism of the lignin surface was investigated
and is attributed to reactive oxygen species generated upon oxidation
of lignin phenols. This mechanism does not consume the surface coating
(as opposed to the release of a specific antiviral agent) and does
not require regeneration. The coating is stable in ambient conditions,
as demonstrated in a 6 month aging study that did not reveal any decrease
in antiviral activity. This research suggests that natural compounds
may be used for the development of affordable and sustainable antiviral
coatings.
Monolayer-protected metal nanoparticles (NPs) are not only promising materials with a wide range of potential industrial and biological applications, but they are also a powerful tool to investigate the behavior of matter at nanoscopic scales, including the stability of dispersions and colloidal systems. This stability is dependent on a delicate balance between electrostatic and steric interactions that occur in the solution, and it is described in quantitative terms by the classic Derjaguin-Landau-Vewey-Overbeek (DLVO) theory, that posits that aggregation between NPs is driven by hydrophobic interactions and opposed by electrostatic interactions. To investigate the limits of this theory at the nanoscale, where the continuum assumptions required by the DLVO theory break down, here we investigate NP dimerization by computing the Potential of Mean Force (PMF) of this process using fully atomistic MD simulations. Serendipitously, we find that electrostatic interactions can lead to the formation of metastable NP dimers. These dimers are stabilized by complexes formed by negatively charged ligands belonging to distinct NPs that are bridged by positively charged ions present in solution. We validate our findings by collecting tomographic EM images of NPs in solution and by quantifying their radial distribution function, that shows a marked peak at interparticle distance comparable with that of MD simulations. Taken together, our results suggest that not only hydrophobic interactions, but also electrostatic interactions, contribute to attraction between nano-sized charged objects at very short length scales.
Monolayer-protected metal nanoparticles are a powerful tool to investigate the behavior of matter at nanoscales. We found that electrostatic interactions can lead to the formation of metastable NP dimers at moderate ionic strenghts.
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