67 research outputs found
Modelling receding contact lines on superhydrophobic surfaces
We use mesoscale simulations to study the depinning of a receding contact
line on a superhydrophobic surface patterned by a regular array of posts. In
order that the simulations are feasible, we introduce a novel geometry where a
column of liquid dewets a capillary bounded by a superhydrophobic plane which
faces a smooth hydrophilic wall of variable contact angle. We present results
for the dependence of the depinning angle on the shape and spacing of the
posts, and discuss the form of the meniscus at depinning. We find, in agreement
with [17], that the local post concentration is a primary factor in controlling
the depinning angle, and show that the numerical results agree well with recent
experiments. We also present two examples of metastable pinned configurations
where the posts are partially wet.Comment: Revised version accepted for publication in Langmui
Capillary filling in microchannels patterned by posts
We investigate the capillary filling of three dimensional micro-channels with
surfaces patterned by posts of square cross section. We show that pinning on
the edges of the posts suppresses, and can halt, capillary filling. We stress
the importance of the channel walls in controlling whether filling can occur.
In particular for channels higher than the distance between adjacent posts,
filling occurs for contact angles less than a threshold angle \sim 55 deg.,
independent of the height of the channel.Comment: To appear in Phys. Rev.
Direct measurement of DNA-mediated adhesion between lipid bilayers
Multivalent interactions between deformable mesoscopic units are ubiquitous
in biology, where membrane macromolecules mediate the interactions between
neighbouring living cells and between cells and solid substrates. Lately,
analogous artificial materials have been synthesised by functionalising the
outer surface of compliant Brownian units, for example emulsion droplets and
lipid vesicles, with selective linkers, in particular short DNA sequences. This
development extended the range of applicability of DNA as a selective glue,
originally applied to solid nano and colloidal particles. On very deformable
lipid vesicles, the coupling between statistical effects of multivalent
interactions and mechanical deformation of the membranes gives rise to complex
emergent behaviours, as we recently contributed to demonstrate [Parolini et
al., Nature Communications, 2015, 6, 5948]. Several aspects of the complex
phenomenology observed in these systems still lack a quantitative experimental
characterisation and fundamental understanding. Here we focus on the
DNA-mediated multivalent interactions of a single liposome adhering to a flat
supported bilayer. This simplified geometry enables the estimate of the
membrane tension induced by the DNA-mediated adhesive forces acting on the
liposome. Our experimental investigation is completed by morphological
measurements and the characterisation of the DNA-melting transition, probed by
in-situ F\"{o}rster Resonant Energy Transfer spectroscopy. Experimental results
are compared with the predictions of an analytical theory that couples the
deformation of the vesicle to a full description of the statistical mechanics
of mobile linkers. With at most one fitting parameter, our theory is capable of
semi-quantitatively matching experimental data, confirming the quality of the
underlying assumptions.Comment: 16 pages, 7 figure
Antimicrobial resistance, an update from the ward: Increased incidence of new potential pathogens and site of infection-specific antibacterial resistances
In order to monitor the spread of antimicrobial resistance, the European Union requires hospitals to be equipped with infection control centers. With this aim, we analyzed 1583 bacterial strains isolated from samples of different origin from patients with community-onset and nosocomial infections in a public tertiary University Hospital on the outskirts of Turin, Italy. Statistical analyses of the isolates (source, type) and their antimicrobial resistance (AMR) were performed. The survey revealed infections associated with bacterial species considered as not-commensal and not-pathogenic, hence potentially emerging as new threats for human health. Conversely to the general observation of nosocomial strains being more resistant to antibiotics compared to community-acquired strains, nosocomial strains isolated in this study were more resistant only to 1/42 tested antibiotics (tetracycline). By adopting an ecological approach, we observed that blood infections are associated with the broadest range of species compared to infections affecting other areas and we obtained clear indications on the antibiotics that should be preferred in the treatment of infections at specific body sites. Future investigations carried out on a larger geographical scale will clarify whether these indications are limited to the geographical region investigated over this study, or whether the same trends are visible at national or international level
Pseudo-dipeptide bearing α,α-difluoromethyl ketone moiety as electrophilic warhead with activity against coronaviruses
The synthesis of α-fluorinated methyl ketones has always been challenging. New methods based on the homologation chemistry via nucleophilic halocarbenoid transfer, carried out recently in our labs, allowed us to design and synthesize a target-directed dipeptidyl α,α-difluoromethyl ketone (DFMK) 8 as a potential antiviral agent with activity against human coronaviruses. The abil-ity of the newly synthesized compound to inhibit viral replication was evaluated by a viral cyto-pathic effect (CPE)-based assay performed on MCR5 cells infected with one of the four human coro-naviruses associated with respiratory distress, i.e., hCoV-229E, showing antiproliferative activity in the micromolar range (EC50 = 12.9 ± 1.22 ΌM), with a very low cytotoxicity profile (CC50 = 170 ± 3.79 ΌM, 307 ± 11.63 ΌM, and 174 ± 7.6 ΌM for A549, human embryonic lung fibroblasts (HELFs), and MRC5 cells, respectively). Docking and molecular dynamics simulations studies indicated that 8 efficaciously binds to the intended target hCoV-229E main protease (Mpro). Moreover, due to the high similarity between hCoV-229E Mpro and SARS-CoV-2 Mpro, we also performed the in silico analysis towards the second target, which showed results comparable to those obtained for hCoV-229E Mpro and promising in terms of energy of binding and docking pose
Pseudo-dipeptide bearing α,α-difluoromethyl ketone moiety as electrophilic warhead with activity against coronaviruses
The synthesis of α-fluorinated methyl ketones has always been challenging. New methods based on the homologation chemistry via nucleophilic halocarbenoid transfer, carried out recently in our labs, allowed us to design and synthesize a target-directed dipeptidyl α,α-difluoromethyl ketone (DFMK) 8 as a potential antiviral agent with activity against human coronaviruses. The ability of the newly synthesized compound to inhibit viral replication was evaluated by a viral cytopathic effect (CPE)-based assay performed on MCR5 cells infected with one of the four human coronaviruses associated with respiratory distress, i.e., hCoV-229E, showing antiproliferative activity in the micromolar range (EC50 = 12.9 ± 1.22 ”M), with a very low cytotoxicity profile (CC50 = 170 ± 3.79 ”M, 307 ± 11.63 ”M, and 174 ± 7.6 ”M for A549, human embryonic lung fibroblasts (HELFs), and MRC5 cells, respectively). Docking and molecular dynamics simulations studies indicated that 8 efficaciously binds to the intended target hCoV-229E main protease (Mpro). Moreover, due to the high similarity between hCoV-229E Mpro and SARS-CoV-2 Mpro, we also performed the in silico analysis towards the second target, which showed results comparable to those obtained for hCoV-229E Mpro and promising in terms of energy of binding and docking pose
Coarse-grained models for fluids and their mixtures: Comparison of Monte Carlo studies of their phase behavior with perturbation theory and experiment
The prediction of the equation of state and the phase behavior of simple
fluids (noble gases, carbon dioxide, benzene, methane, short alkane chains) and
their mixtures by Monte Carlo computer simulation and analytic approximations
based on thermodynamic perturbation theory is discussed. Molecules are
described by coarse grained (CG) models, where either the whole molecule
(carbon dioxide, benzene, methane) or a group of a few successive CH_2 groups
(in the case of alkanes) are lumped into an effective point particle.
Interactions among these point particles are fitted by Lennard-Jones (LJ)
potentials such that the vapor-liquid critical point of the fluid is reproduced
in agreement with experiment; in the case of quadrupolar molecules a
quadrupole-quadrupole interaction is included. These models are shown to
provide a satisfactory description of the liquid-vapour phase diagram of these
pure fluids. Investigations of mixtures, using the Lorentz-Berthelot (LB)
combining rule, also produce satisfactory results if compared with experiment,
while in some previous attempts (in which polar solvents were modelled without
explicitly taking into account quadrupolar interaction), strong violations of
the LB rules were required. For this reason, the present investigation is a
step towards predictive modelling of polar mixtures at low computational cost.
These very simple coarse-grained models of small molecules developed here
should be useful e.g. for simulations of polymer solutions with such molecules
as solvent.Comment: J. Chem. Phys., accepte
Vapor phase mediated cellular uptake of sub 5 nm nanoparticles
Nanoparticles became an important and wide-used tool for cell imaging because of their unique optical properties. Although the potential of nanoparticles (NPs) in biology is promising, a number of questions concerning the safety of nanomaterials and the risk/benefit ratio of their usage are open. Here, we have shown that nanoparticles produced from silicon carbide (NPs) dispersed in colloidal suspensions are able to penetrate into surrounding air environment during the natural evaporation of the colloids and label biological cells via vapor phase. Natural gradual size-tuning of NPs in dependence to the distance from the NP liquid source allows progressive shift of the fluorescence color of labeled cells in the blue region according to the increase of the distance from the NP suspension. This effect may be used for the soft vapor labeling of biological cells with the possibility of controlling the color of fluorescence. However, scientists dealing with the colloidal NPs have to seriously consider such a NP's natural transfer in order to protect their own health as well as to avoid any contamination of the control samples
Controlling the temperature sensitivity of DNA-mediated colloidal interactions through competing linkages
We propose a new strategy to improve the self-assembly properties of
DNA-functionalised colloids. The problem that we address is that
DNA-functionalised colloids typically crystallize in a narrow temperature
window, if at all. The underlying reason is the extreme sensitivity of
DNA-mediated interactions to temperature or other physical control parameters.
We propose to widen the window for colloidal crystallization by exploiting the
competition between DNA linkages with different nucleotide sequences, which
results in a temperature-dependent switching of the dominant bond type.
Following such a strategy, we can decrease the temperature dependence of
DNA-mediated self assembly to make systems that can crystallize in a wider
temperature window than is possible with existing systems of DNA functionalised
colloids. We report Monte Carlo simulations that show that the proposed
strategy can indeed work in practice for real systems and specific, designable
DNA sequences. Depending on the length ratio of the different DNA constructs,
we find that the bond switching is either energetically driven (equal length or
`symmetric' DNA) or controlled by a combinatorial entropy gain (`asymmetric'
DNA), which results from the large number of possible binding partners for each
DNA strand. We provide specific suggestions for the DNA sequences with which
these effects can be achieved experimentally
Anti-HER-2 DNA vaccine protects Syrian hamsters against squamous cell carcinomas
This paper illustrates the efficacy of DNA vaccination through electroporation in the prevention of oral transplantable carcinoma in Syrian hamsters. At 21 and 7 days before tumour challenge, 19 hamsters were vaccinated with plasmids coding for the extracellular and transmembrane domains of rat HER-2 receptor (EC-TM plasmids), whereas 19 control hamsters were injected intramuscularly with the empty plasmid. Immediately following plasmid injection, hamsters of both groups received two square-wave 25âms, 375âVâcmâ1 electric pulses via two electrodes placed on the skin of the injection area. At day 0, all hamsters were challenged in the submucosa of the right cheek pouch with HER-2-positive HCPC I cells established in vitro from an 7,12-dimethylbenz[a]anthracene-induced oral carcinoma. This challenge gave rise to HER-2-positive buccal neoplastic lesions in 14 controls (73.37%), compared with only seven (36.8%, P<0.0027) vaccinated hamsters. In addition, the vaccinated hamsters displayed both a stronger proliferative and cytotoxic response than the controls and a significant anti-HER-2 antibody response. Most of the hamsters that rejected the challenge displayed the highest antibody titres. These findings suggest that DNA vaccination may have a future in the prevention of HER-2-positive human oral cancer
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