1,124 research outputs found
Material Dependence of the Wire-Particle Casimir Interaction
We study the Casimir interaction between a metallic cylindrical wire and a
metallic spherical particle by employing the scattering formalism. At large
separations, we derive the asymptotic form of the interaction. In addition, we
find the interaction between a metallic wire and an isotropic atom, both in the
non-retarded and retarded limits. We identify the conditions under which the
asymptotic Casimir interaction does not depend on the material properties of
the metallic wire and the particle. Moreover, we compute the exact Casimir
interaction between the particle and the wire numerically. We show that there
is a complete agreement between the numerics and the asymptotic energies at
large separations. For short separations, our numerical results show good
agreement with the proximity force approximation
Apex Exponents for Polymer--Probe Interactions
We consider self-avoiding polymers attached to the tip of an impenetrable
probe. The scaling exponents and , characterizing the
number of configurations for the attachment of the polymer by one end, or at
its midpoint, vary continuously with the tip's angle. These apex exponents are
calculated analytically by -expansion, and numerically by simulations
in three dimensions. We find that when the polymer can move through the
attachment point, it typically slides to one end; the apex exponents quantify
the entropic barrier to threading the eye of the probe
Universality versus material dependence of fluctuation forces between metallic wires
We calculate the Casimir interaction between two parallel wires and between a
wire and a metall plate. The dielectric properties of the objects are described
by the plasma, Drude and perfect metal models. We find that at asymptotically
large separation interactions involving plasma wires and/or plates are
independent of the material properties, but depend on the dc conductivity
for Drude wires. Counterintuitively, at intermediate separations the
interaction involving Drude wires can become independent of . At
smaller separations, we compute the interaction numerically and observe an
approach to the proximity approximation
The effect of quercetin on fertility of frozen-thawed ram epididymal spermatozoa
The aim of the present study was to evaluate the effects of quercetin as an antioxidant supplement on frozen-thawed ram epididymal sperm quality. Quercetin is a type of flavonoid antioxidant that is found in plants, with the ability to scavenge free radicals. Twenty testicles from mature rams were collected from a nearby slaughterhouse immediately after slaughter. Epididymal spermatozoa were recovered from the caudal of epididymides by injecting Bracket and Oliphant's (BO) medium retrogradely through the ductus deferens and extended with a tris egg-yolk-based extender and supplemented with 0, 5, 10, 15, 20, and 50 μg/mL quercetin. Following equilibration, the straws were frozen, and then plunged into liquid nitrogen. After thawing, optimized concentrations of quercetin were defined based on their viabilities and used to assess fertilization and developmental potential. The results showed that the viability of frozen-thawed spermatozoa significantly increased by using 5 and 10 μg/mL quercetin in the freezing extender. However, total and progressive motility of frozen-thawed spermatozoa were not affected by 5 and 10 μg/mL quercetin in comparison with control (0 μg/mL). The mean number of zygote, morula, and blastocyst stage embryos increased significantly by using 5 and 10 μg/mL quercetin compared with other frozen-thawed treatments(P <0.05). However, the blastocyst rate of fresh sperm was significantly higher (P <0.05). In conclusion, to improve the quality of frozen-thawed ram epididymal spermatozoa, 5 and 10 μg/mL quercetin appears to be an attractive option. Further studies are suggested to understand the synergistic effect of quercetin with other antioxidants to improve the ram freezing–thawing process.Keywords: antioxidant, cryopreservation, fertility, freezing extende
What drives the translocation of stiff chains?
We study the dynamics of the passage of a stiff chain through a pore into a
cell containing particles that bind reversibly to it. Using Brownian Molecular
Dynamics simulations we investigate the mean-first-passage time as a function
of the length of the chain inside, for different concentrations of binding
particles. As a consequence of the interactions with these particles, the chain
experiences a net force along its length whose calculated value from the
simulations accounts for the velocity at which it enters the cell. This force
can in turn be obtained from the solution of a generalized diffusion equation
incorporating an effective Langmuir adsorption free energy for the chain plus
binding particles. These results suggest a role of binding particles in the
translocation process which is in general quite different from that of a
Brownian ratchet. Furthermore, non-equilibrium effects contribute significantly
to the dynamics, \emph{e.g.}, the chain often enters the cell faster than
particle binding can be saturated, resulting in a force several times smaller
than the equilibrium value.Comment: 7 pages, 4 figure
Elastic Lattice Polymers
We study a model of "elastic" lattice polymer in which a fixed number of
monomers is hosted by a self-avoiding walk with fluctuating length . We
show that the stored length density scales asymptotically
for large as , where is the
polymer entropic exponent, so that can be determined from the analysis
of . We perform simulations for elastic lattice polymer loops with
various sizes and knots, in which we measure . The resulting estimates
support the hypothesis that the exponent is determined only by the
number of prime knots and not by their type. However, if knots are present, we
observe strong corrections to scaling, which help to understand how an entropic
competition between knots is affected by the finite length of the chain.Comment: 10 page
Collective charge fluctuations and Casimir interactions for quasi one-dimensional metals
We investigate the Casimir interaction between two parallel metallic
cylinders and between a metallic cylinder and plate. The material properties of
the metallic objects are implemented by the plasma, Drude and perfect metal
model dielectric functions. We calculate the Casimir interaction numerically at
all separation distances and analytically at large separations. The
large-distance asymptotic interaction between one plasma cylinder parallel to
another plasma cylinder or plate does not depend on the material properties,
but for a Drude cylinder it depends on the dc conductivity . At
intermediate separations, for plasma cylinders the asymptotic interaction
depends on the plasma wave length while for Drude cylinders
the Casimir interaction can become independent of the material properties. We
confirm the analytical results by the numerics and show that at short
separations, the numerical results approach the proximity force approximation
RNA topology remolds electrostatic stabilization of viruses
Simple RNA viruses efficiently encapsulate their genome into a nano-sized protein shell-the capsid. Spontaneous co-assembly of the genome and the capsid proteins is driven predominantly by electrostatic interactions between the negatively charged RNA and the positively charged inner capsid wall. Using field theoretic formulation we show that the inherently branched RNA secondary structure allows viruses to {\sl maximize} the amount of encapsulated genome and make assembly more efficient, allowing viral RNAs to out-compete cellular RNAs during replication in infected host cell
Antiviral activity of Holothuria sp. a sea cucumber against herpes simplex virus type 1 (HSV-1)
BACKGROUND: Finding the new
bioactive compounds with antiviral activity from
the natural resources are in interest of many drug
discovery scientists. Sea cucumber is among the
marine organisms a traditional food item in Asia
with different applications in traditional medicine.
METHODS: In current study, a cold water extract
of the Holothuria sp, one type Persian Gulf’s
sea cucumber was evaluated for its antiviral effects
against KOS strain of Herpes Simplex Virus
tyoe 1 (HSV-1) in cell culture. The half maximal inhibitory
concentration (IC50) values were calculated
for anti-adsorption activity and intracellular antiviral
activity of the crude extract separately.
RESULTS: The extract exhibited antiviral activity
not only against the virus adsorption to the cells,
but also on virus intracellular replication.The CC50
for sea cucumber extract was 32.57 mg/ml. The
IC50 values for the inhibition of the virus adsorption
to the cells and virus intracellular replication
were 120.2 and 189.9 μg/ml respectively. Selectivity
index (SI) value for anti-adsorption activity was
189 while that value for the extract’s intracellular
antiviral activity was 172.
CONCLUSIONS: The results showed that
Holothuria sp, water extract has remarkable antiviral
effect against HSV-1 in cell culture and it
is crucial to investigate the mechanism(s) of action
of extract. Moreover, identification of the effective
compound(s) within the extract would be
necessary for future studies towards developing
the new natural antiviral agent against HSV-1
Experimental and theoretical investigation of angular dependence of the Casimir force between sinusoidally corrugated surfaces
In the current work we present the complete results for the measurement of
normal Casimir force between shallow and smooth sinusoidally corrugated gold
coated sphere and a plate at various angles between the corrugations using an
atomic force microscope. All measured data were compared with the theoretical
approach using the proximity force approximation and theory based on derivative
expansion. In both cases real material properties of the surfaces and non-zero
temperature were taken into account. Special attention is paid to the
description of electrostatic interactions between corrugated surfaces at
different angels between corrugations and samples reparation and
characterization. The measured forces are found to be in good agreement with
the theory including correlation effects of geometry and material properties
and deviate significantly from the predictions of the proximity force
approximation approach. This provides the quantitative confirmation for the
observation of diffraction-type effects that are disregarded within the PFA
approach. The obtained results open new opportunities for control of the
Casimir effect in micromechanical systems
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