The
nucleation inducing ability of agarose gels has been exploited
to study the crystallization of proteins in diffusion-dominated environments.
The crystal size was successfully tuned in a wide range of gel, protein,
and precipitant concentrations. The impact of the gel content on crystal
size was independent of the specific protein, allowing the mathematical
prediction of crystal size and pointing out the exclusivity of physical
interactions between the gel and the protein. The versatility of the
technique and the fine-tuning of the nucleation flux was demonstrated
by crystallizing five different proteins and implementing batch and
counter-diffusion crystallization. In addition, the potential of agarose
gel to be used not only as a growth but also as a delivery medium
for serial crystallography applications has been proven by preparing
unidimensional microcrystal slurries with 0.1% (w/v) gel.
The controlled modification of surface properties represents a pervasive requirement to be fulfilled when developing new technologies. In this paper, we propose an easy-to-implement protocol for the functionalization of glass with self-assembled monolayers (SAMs). The adaptivity of the synthesis route was demonstrated by the controlled anchoring of thiol, amino, glycidyloxy, and methacrylate groups onto the glass surface. The optimization of the synthetic pathway was mirrored by extremely smooth SAMs (approximately 150 pm roughness), layer thickness comparable to the theoretical molecule length, absence of silane islands along the surface, quasi-unitary degree of packing, and tailored wettability and charge. The functionalization kinetics of two model silanes, 3-mercapto- and 3-amino-propyltrimethoxysilane, was determined by cross-comparing x-ray photoelectron spectroscopy and time of flight secondary ion mass spectrometry data. Our SAMs with tailored physicochemical attributes will be implemented as supports for the crystallization of pharmaceuticals and biomolecules in upcoming studies. Here, the application to a small molecule drug model, namely aspirin, was discussed as a proof of concept.
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.
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