Detection of Drug Resistance in Escherichia coli Isolated from Animals and ERIC Analysis of Multidrug-resistant Strains

The drug resistance of Escherichia coli from animals was detected in Shandong Province in 2016,the gene mapping of Enterobacterial Repetitive Intergenic Consensus-PCR (ERIC-PCR) of multidrug-resistant isolates were analyzed,and then the relationship between ERIC-PCR genotyping and drug resistance of highly-resistant E.coli with multidrug resistance was discussed.A total of 110 E.coli isolates were separated and identified from diseased swine and avian,and their resistance to 10 kinds of antimicrobials was determined by the agar dilution method.Twenty highly-resistant isolates with multidrug resistance were selected to carry on the ERIC-PCR,followed by cluster genetic analysis according to the DNA fingerprints.The swine-sourced E.coli isolates possessed serious resistance against several kinds of antimicrobial agents,for example,all isolates were tolerant to florfenicol,doxycycline and ampicillin (100%),but had a relative lower resistance rate to cefotaxime sodium (57.14%).The same situation was observed in the poultry-sourced E.coli isolates,which had a resistance rate of 95.51% against florfenicol,while the lowest rate of 61.80% appeared on ciprofloxacin.Analysis of ERTIC showed dispersive fingerprint patterns of highly-resistant and multidrug- resistant isolates which represented a multiple clone resources,and there were certain correlation between the B genotype and the drug-resistant characteristics.It indicated that the animal-sourced E.coli isolates had a high level of drug resistance and were multidrug-resistant,which meant there was severe antibiotic resistance against not only different kinds of antibiotics but also different drugs of the same kind.The highly-resistant E.coli isolates with multidrug resistance had no apparent species preference,while their spread and pervasion posed a potential threat to the development of animal husbandry and the public health security.

Synthesis and Field Emission Properties of Carbon Nanowire-Single Walled Carbon Nanotube Networks Hybrid Films

Carbon nanowire (CNW)-singlewalled carbon nanotube (SWCNT) networks hybrid films with a large area (~400 mm2) are grown on molybdenum (Mo) layers by microwave plasma chemical vapour deposition system. The Mo layers, which were deposited on Al2O3 ceramic substrates through electron beam evaporation deposition, were pretreated by a laser-grooving (LG) technology. Furthermore, the surface morphology, micro-structure and field emission properties of these samples are characterized by scanning electron microscope, Raman spectra, and field emission I - V measurements. ACNW-SWCNT networks hybrid film was formed in the surface of Mo layer, but the laser etched area (linear pits array area) the distribution of the CNW-SWCNT networks density is lower than the un-etched area CNW-SWCNT networks distribution density. The diameter of the CNWs and SWCNTs, respectively in the 8 - 15 nm and 0.9 - 1.5 nm range, and the length of CNW-SWCNTs ranges from 1 μm to 4 μm. The growth mechanisms of the films were discussed. Effects of LG pretreatment on surface morphologies and microstructure of the hybrid films were investigated. The field electron emission experimental results shown that the ture on field as low as 1.6 V/μm, and a current density of 0.15 mA/cm2 at an electric field of 4.3 V/μm was obtained.

Impacts of Microalloying Elements on the Hardening β"‑Phase in Automotive AlMgSi Alloys

Microalloying elements play a crucial role in mechanical properties and phase stability of metallic alloys.In this work,we employ first-principles calculations and atomic-scale high-angle annular dark-field scanning transmission electron microscopy(HAADF-STEM)to find promising microalloying elements that will improve the stability and properties ofβ"/Al interface andβ"phase in Al–Mg-Si alloys.First,we define a substitution energy for evaluating the stability ofβ"phase andβ"/Al interface with microalloying elements doped.Then,experiments of HAADF-STEM imaging are carried out to verify the calculational results.Next,using the most stable structures doped with microalloying elements,the mechanical properties of theβ"bulk and theβ"/Al interface were calculated and analyzed.At last,we have figured out the effects of all considered microalloying elements and obtained a rule that the stable occupancy of solute atoms is related to their own radius and the radius of Mg,Si,and Al.These findings will provide some theoretical basis for future microalloying strategies of Al–Mg-Si alloys.

The stability of deformation twins in aluminum enhanced by alloying elements

Introducing and stabilizing twins in aluminum is a challenge for metals research due to their high formation energy.Employing first-principles calculations,we investigated the twin boundary segregation of alloying elements and their impact on the twin boundary energy in aluminum.Alloying elements with small solubilities but strong interaction with twin boundary would significantly reduce twin boundary energies in aluminum at low temperatures.With increasing temperature,their segregation near twin boundary weakens,leading to their influence on twin boundary energies reduced.Some elements with large solubilities may greatly reduce the twin energies not only at low temperatures but also at high temperatures.Based on careful analysis of charge density and atomic radius,it has been found that chemical difference has little influence on twin boundary energy whereas the atomic size effect plays a leading role in causing the change of twin boundary energy.