Research progress on the oxazolidinone drug linezolid resistance.

OBJECTIVE: The oxazolidinone drug linezolid is mainly used for severe infections caused by multidrug-resistant Gram-positive bacteria. However, emerging linezolid resistance is aggravating difficulties in the treatment of certain infectious diseases. The objective of this review was to provide a reference for researchers and clinicians to be able to better face together the serious challenge of antimicrobial resistance. MATERIALS AND METHODS: A systematic literature search was performed using PubMed, Web of Science, Google Scholar, and the China National Knowledge Infrastructure (CNKI) database. The articles were scrutinized to extract information on oxazolidinone drug linezolid resistance, and the prevalence of the resistance gene optrA. We reviewed the latest advances in epidemic properties, resistance mechanism, and transfer mechanism of linezolid resistance genes in different isolates isolated from various samples worldwide. RESULTS: Initially, it was thought that linezolid resistance was related to the change in drug target mediated by mutations in the 23S rRNA gene, rplC, rplD, and cfr. optrA was discovered in 2015, and is a gene encoding oxazolidinone resistance, which exists in both plasmids and chromosomes, but mostly plasmids. The emergence of the novel plasmid-borne ABC transporter gene optrA expanded the understanding of the mechanism of linezolid resistance. CONCLUSIONS: At present, the prevalence of linezolid resistance has become increasingly serious. The resistance gene optrA has been reported in Enterococcus, Staphylococcus squirrel and Streptococcus, which indicates that this gene has a strong ability to spread across bacteria, so the prevalence and spread of optrA gene should be monitored carefully.

Polarization-driven topological insulator transition in a GaN/InN/GaN quantum well.

Topological insulator (TI) states have been demonstrated in materials with a narrow gap and large spin-orbit interactions (SOI). Here we demonstrate that nanoscale engineering can also give rise to a TI state, even in conventional semiconductors with a sizable gap and small SOI. Based on advanced first-principles calculations combined with an effective low-energy k · p Hamiltonian, we show that the intrinsic polarization of materials can be utilized to simultaneously reduce the energy gap and enhance the SOI, driving the system to a TI state. The proposed system consists of ultrathin InN layers embedded into GaN, a layer structure that is experimentally achievable.

Rh2O3 versus IrO2: relativistic effects and the stability of Ir4+.

Despite the wide-ranging applications of binary Rh and Ir oxides, their stability and trends in Rh and Ir oxidation states are not fully understood. Using first-principles electronic structure calculations, we demonstrate that the origin of the categorical stability of Ir(4+) is the relativistic contraction of the 6s orbital and, consequently, an expansion of 5d orbitals. Relativistic effects significantly stabilize Ir(4+)-containing metallic rutile IrO(2) over a wide range of O chemical potentials, despite the choice that Ir has of forming semiconducting corundum Ir(2)O(3). In contrast, Rh is found to display a wider stability range for corundum Rh(2)O(3) with Rh(3+) and a greater propensity for multiple oxidation states.

Density functional theory calculations of pressure effects on the vibrational structure of alpha-RDX.

Pressure effects on the vibrational structure of alpha-RDX were examined using density functional theory (DFT) up to 4 GPa. The calculated vibrational frequencies at ambient conditions are in better agreement with experimental data than are previous single molecule calculations. The calculations showed the following pressure-induced changes: (i) larger shifts for lattice modes and for internal modes associated with the CH(2) and NO(2) groups as compared to the pressure shifts for modes associated with the triazine ring, (ii) enhancement of mixing between different vibrations, for example, between NN stretching and CH(2) scissor, wagging, twisting vibrations, and (iii) increase in mixing between translational lattice vibrations and the NO(2) wagging vibrations, reducing the distinction between internal and lattice modes. The calculated volume and lattice constants at ambient pressure are larger than the experimental values, due to the inability of the present density functional approach to correctly account for van der Waals forces. Consequently, the pressure-induced frequency shifts of many modes deviate substantially from experimental data for pressures below 1 GPa. With increasing pressure, both the lattice constants and the frequency shifts agree more closely with experimental values.

Universal transition state for high-pressure zinc blende to rocksalt phase transitions.

First-principles density functional calculations show that the high-pressure transitions of different semiconductors from zinc blende to rocksalt go through a transition state, which is universal in the sense that its position along the path and the corresponding geometry is independent of the chemical components of the semiconductor. This is explained using a Landau-like model expansion of the free energy in cosine functions of atomic position.

[Clinical and experimental study on treatment of fatty liver of phlegm-dampness stagnation type by zhiganle capsule].

OBJECTIVE: To explore the mechanism of Zhiganle capsule (ZGLC) in treating fatty liver of Phlegm-Dampness Stagnation type. METHODS: One hundred and forty-six patients were treated with ZGLC, the effects were observed and compared with those treated with Dongbao Gantai (DBGT,) tablets as control. The effect of ZGLC on ethionine induced hyperlipemia model rats was also observed. RESULTS: The effect of ZGLC was obviously better than those of DBGT in relieving or removing symptoms, normalizing the ultrasonic abnormal findings, lowering the serum levels of lipid and enzyme and improving hemorrheologic properties. Experimental study showed that ZGLC could reduce the blood lipids, inhibit the lipid deposition in liver. As compared with the model group, level of triglyceride in the ZGLC treatment group were much lowered (P < 0.01) and the effect was better than those in the control group. CONCLUSIONS: ZGLC has the effect of reducing blood triglyceride level, inhibiting lipid deposition in liver and improving hemorrheologic properties.