[Interferonogenic activity of the strain BH-3 duck hepatitis virus type I (Picornaviridae: Avihepatovirus: Avihepatovirus A)].

INTRODUCTION: Duck viral hepatitis type I (DVH-I) is a poorly studied contagious disease caused by RNA-containing duck (Anatinae) hepatitis virus type I (Picornaviridae: Avihepatovirus: Avihepatovirus A). This infection is widespread in many countries, including Russia, and causes significant damage to industrial duck breeding. The study of interferonogenic activity of its etiologic agent strains is of great importance in solving the problem of developing effective means to control the disease. MATERIAL AND METHODS: Strain BH-3 of duck hepatitis virus type I isolated from the liver of sick ducklings was used in the study. The strain was adapted to developing 10-12 day old duck embryos, to the cell culture of chicken and duck fibroblasts and deposited in the State Collection of Viruses of the D.I. Ivanovsky Institute of Virology of FSBI «National Research Centre for Epidemiology and Microbiology named after the honorary academician N.F. Gamaleya¼ of the Ministry of Health of Russia. Experiments were performed using the standard tissue culture method. RESULTS AND DISCUSSION: Data on the ability of the viral strain BH-3 to induce interferon (IFN) and its sensitivity to the action of exogenous interferon in the culture of duck fibroblasts are presented. It has been shown that the interferonogenic activity of this strain of the hepatitis virus is in direct proportion to the multiplicity of infection. The maximum induction of IFN (1 : 256 CEPD50) was observed at a dose of 1.0 TCD50/cell in 72-96 hrs after inoculation of the cell culture. Exogenous IFN at a dose of 1 : 128 completely suppressed the cytopathic effect and death of duck embryos infected with hepatitis virus at a dose of 100 TCD50/cell. CONCLUSION: The data obtained allow us to state that the vaccine strain BH-3 of duck hepatitis virus type I has a pronounced interferonogenic activity and sensitivity to the action of exogenous IFN. This may have implications for the development of effective therapeutic agents against DVH-I.

Revealing the Complex Nature of Bonding in the Binary High-Pressure Compound FeO_{2}.

Extreme pressures and temperatures are known to drastically affect the chemistry of iron oxides, resulting in numerous compounds forming homologous series nFeOmFe_{2}O_{3} and the appearance of FeO_{2}. Here, based on the results of in situ single-crystal x-ray diffraction, Mössbauer spectroscopy, x-ray absorption spectroscopy, and density-functional theory+dynamical mean-field theory calculations, we demonstrate that iron in high-pressure cubic FeO_{2} and isostructural FeO_{2}H_{0.5} is ferric (Fe^{3+}), and oxygen has a formal valence less than 2. Reduction of oxygen valence from 2, common for oxides, down to 1.5 can be explained by a formation of a localized hole at oxygen sites.

THE KINETICS OF THE INACTIVATION OF THE HEPATITIS VIRUS TYPE I (AVIHEPATOVIRUS, PICORNAVIRIDAE).

Experimental data on the kinetics of the inactivation of the vaccine strain of the duckling hepatitis virus of the type I with increased temperature and aminoethyl ethylenimine are presented. It was shown that the vaccine strain 3M-UNIIP of the hepatitis virus of ducklings of type I was comparatively thermostable at 56°C and sensitive to the action of aminoethyl ethylenimine; the time of complete inactivation of the virus at a final concentration of 0.1% at 37°C was 24 h. The obtained results suggest that aminoethyl ethylenimine can be used as an inactivator in manufacturing inactivated vaccine against viral hepatitis of ducklings of type I.

Correlation-Driven Topological Fermi Surface Transition in FeSe.

The electronic structure and phase stability of paramagnetic FeSe is computed by using a combination of ab initio methods for calculating band structure and dynamical mean-field theory. Our results reveal a topological change (Lifshitz transition) of the Fermi surface upon a moderate expansion of the lattice. The Lifshitz transition is accompanied with a sharp increase of the local moments and results in an entire reconstruction of magnetic correlations from the in-plane magnetic wave vector, (π,π) to (π,0). We attribute this behavior to a correlation-induced shift of the van Hove singularity originating from the d(xy) and d(xz)/d(yz) bands at the M point across the Fermi level. We propose that superconductivity is strongly influenced, or even induced, by a van Hove singularity.

Electronic correlations determine the phase stability of iron up to the melting temperature.

We present theoretical results on the high-temperature phase stability and phonon spectra of paramagnetic bcc iron which explicitly take into account many-body effects. Several peculiarities, including a pronounced softening of the [110] transverse (T1) mode and a dynamical instability of the bcc lattice in harmonic approximation are identified. We relate these features to the α-to-γ and γ-to-δ phase transformations in iron. The high-temperature bcc phase is found to be highly anharmonic and appears to be stabilized by the lattice entropy.

First-principles calculation of atomic forces and structural distortions in strongly correlated materials.

We introduce a novel computational approach for the investigation of complex correlated electron materials which makes it possible to evaluate interatomic forces and, thereby, determine atomic displacements and structural transformations induced by electronic correlations. It combines ab initio band structure and dynamical mean-field theory and is implemented with the linear-response formalism regarding atomic displacements. We apply this new technique to explore structural transitions of prototypical correlated systems such as elemental hydrogen, SrVO3, and KCuF3.

Electronic correlations at the α-γ structural phase transition in paramagnetic iron.

We compute the equilibrium crystal structure and phase stability of iron at the α(bcc)-γ(fcc) phase transition as a function of temperature, by employing a combination of ab initio methods for calculating electronic band structures and dynamical mean-field theory. The magnetic correlation energy is found to be an essential driving force behind the α-γ structural phase transition in paramagnetic iron.

Optical evidence for symmetry changes above the Néel temperature of KCuF3.

We report on optical measurements of the 1D Heisenberg antiferromagnet KCuF3. The crystal-field excitations of the Cu2+ ions have been observed and their temperature dependence can be understood in terms of magnetic and exchange-induced dipole mechanisms and vibronic interactions. Above TN we observe a new temperature scale TS characterized by the emergence of narrow absorption features that correlate with changes of the orbital ordering as observed by Paolasini et al. [Phys. Rev. Lett. 88, 106403 (2002)]. The appearance of these optical transitions provides evidence for a symmetry change above the Néel temperature that affects the orbital ordering and paves the way for the antiferromagnetic ordering.

Structural relaxation due to electronic correlations in the paramagnetic insulator KCuF3.

A computational scheme for the investigation of complex materials with strongly interacting electrons is formulated which is able to treat atomic displacements, and hence structural relaxation, caused by electronic correlations. It combines ab initio band structure and dynamical mean-field theory and is implemented in terms of plane-wave pseudopotentials. The equilibrium Jahn-Teller distortion and antiferro-orbital order found for paramagnetic KCuF3 agree well with experiment.

Charge and orbital order in Fe3O4.

Charge and orbital ordering in the low-temperature monoclinic structure of magnetite (Fe3O4) is investigated using the local spin density approximation with Coulomb interaction correction method. While the difference between t(2g) minority occupancies of Fe(2+)(B) and Fe(3+)(B) cations is large and gives direct evidence for charge ordering, the screening is so effective that the total 3d charge disproportion is rather small. The charge order has a pronounced [001] modulation, which is incompatible with the Anderson criterion. The orbital order agrees with the Kugel-Khomskii theory.

[Tuberculosis as hospital acquired infection]. / Tuberkulez kak gospital'naia infektsiia.

Tuberculosis morbidity rates were analyzed in the staff of antituberculosis dispensaries and institutions of the general therapeutical network. There were 74 cases of tuberculosis among the medical workers in 1993-1996. The sociomedical characteristics of the medical staff suffering from tuberculosis are given. The findings show it necessary to refer tuberculosis to a group of hospital-acquired infections and to implement a package of prophylactic measures to reduce tuberculosis morbidity rates among medical workers, as well as to timely detect patients with tuberculosis at general hospitals. Measures for preventing tuberculosis are proposed for the personnel of therapeutical institutions.