9,657 research outputs found
On -- the basic ingredients for strangeness production in heavy ion collisions
The strangeness production in heavy ion collisions was proposed to be probes
of the nuclear equation of state, Kaon potential in nuclear medium, strange
quark matter and quark-gluon plasma, etc. However, to act as reliable probes,
proper understanding of the basic ingredients for the strangeness production,
such as , and is
necessary. Recent study of these reactions clearly shows that previously
ignored contributions from the spin-parity resonances, and
, are in fact very important for these reactions, especially
for near-threshold energies. It is necessary to include these contributions for
getting reliable calculation for the strangeness production in heavy ion
collisions.Comment: 12 pages, 12 figures, Contributed to the proceedings of the
International workshop on nuclear dynamics in heavy-ion reactions and neutron
stars, July, 10-14, Beijing, Chin
TNFRSF11B computational development network construction and analysis between frontal cortex of HIV encephalitis (HIVE) and HIVE-control patients
<p>Abstract</p> <p>Background</p> <p><it>TNFRSF11B </it>computational development network construction and analysis of frontal cortex of HIV encephalitis (HIVE) is very useful to identify novel markers and potential targets for prognosis and therapy.</p> <p>Methods</p> <p>By integration of gene regulatory network infer (GRNInfer) and the database for annotation, visualization and integrated discovery (DAVID) we identified and constructed significant molecule <it>TNFRSF11B </it>development network from 12 frontal cortex of HIVE-control patients and 16 HIVE in the same GEO Dataset GDS1726.</p> <p>Results</p> <p>Our result verified <it>TNFRSF11B </it>developmental process only in the downstream of frontal cortex of HIVE-control patients (<it>BST2, DGKG, GAS1, PDCD4, TGFBR3, VEZF1 </it>inhibition), whereas in the upstream of frontal cortex of HIVE (<it>DGKG, PDCD4 </it>activation) and downstream (<it>CFDP1, DGKG, GAS1, PAX6 </it>activation; <it>BST2, PDCD4, TGFBR3, VEZF1 </it>inhibition). Importantly, we datamined that <it>TNFRSF11B </it>development cluster of HIVE is involved in T-cell mediated immunity, cell projection organization and cell motion (only in HIVE terms) without apoptosis, plasma membrane and kinase activity (only in HIVE-control patients terms), the condition is vital to inflammation, brain morphology and cognition impairment of HIVE. Our result demonstrated that common terms in both HIVE-control patients and HIVE include developmental process, signal transduction, negative regulation of cell proliferation, RNA-binding, zinc-finger, cell development, positive regulation of biological process and cell differentiation.</p> <p>Conclusions</p> <p>We deduced the stronger <it>TNFRSF11B </it>development network in HIVE consistent with our number computation. It would be necessary of the stronger <it>TNFRSF11B </it>development function to inflammation, brain morphology and cognition of HIVE.</p
Synthesis and characterization of photoaffinity labelling reagents towards the Hsp90 C-terminal domain
Glucosyl-novobiocin-based diazirine photoaffinity labelling reagents (PALs) were designed and synthesized to probe the Hsp90 C-terminal domain unknown binding pocket and the structure-activity relationship. Five PALs were successfully synthesized from novobiocin in six consecutive steps employing phase transfer catalytic glycosylation. Reactions were monitored and guided by analytical LC/MS which led to different strategies of adding either a PAL precursor or a sugar moiety first. The structures and bonding linkages of these compounds were characterised by various 2D-NMR spectroscopy and MS techniques. Synthetic techniques provide powerful probes for unknown protein binding pockets
Controllable molecular packing motif and overlap type in organic nanomaterials for advanced optical properties
The optical properties of organic materials are very sensitive to subtle structural modification, and a proper understanding of the structure-property relationship is essential to improve the performance of organic electronic devices. The phase transitions of the η-CuPc to the α-CuPc, then to the β-CuPc were investigated using In situ X-ray diffraction and the differential scanning calorimetry (DSC). The five stages in the phase-transition process from low to high-temperature were observed, which consisted of (1) the η-CuPc; (2) a mixture of the η- and α-CuPc; (3) a mixture of the η-, α- and β-CuPc; (4) a mixture of the α- and β-CuPc; and (5) the β-CuPc. The vibrational and optical properties at different phase-transition stages were correlated to molecular packing motif and molecule overlap type through systematic analyses of the Fourier–transform infrared, Raman and UV-VIS spectra. Moreover, the mechanism for the morphology evolution was also discussed in detail
Rayleigh scattering in fused silica samples for gravitational wave detectors
Laser interferometer gravitational wave detectors require very high optical quality test masses. We report the bulk Rayleigh scattering in high quality fused silica samples. Results show that the scattering of the high quality fused silica is similar for various grades of fused silica from Heraeus. The total integrated scattering is about 0.7 ppm cm− 1at 1064 nm wavelength, which agrees with the theoretical value calculated using known fused silica parameters. All samples show Rayleigh scattering ratio inhomogeneity of ~ 4%
In Situ SiRNA Assembly in Living Cells for Gene Therapy with MicroRNA Triggered Cascade Reactions Templated by Nucleic Acids
The in situ generation of siRNAs in living cells can greatly enhance the specificity and efficiency of gene therapy. Inspired by the natural molecular machines that organize different compartments sequentially in a limited space to facilitate cellular process, this work constructs a DNA nanomachine (DNM) by alternately hybridizing two pairs of DNA/RNA hybrids to a DNA scaffold generated by rolling circle amplification for highly efficient in situ siRNA assembly in living cells. After target cell-specific delivery of DNM, intracellular specific microRNA can work as a trigger to operate the DNM by initiating DNA cascade displacement reaction between DNA/RNA hybrids along the scaffold for continuous generation of siRNAs. Using miR-21 as a model, efficient siRNAs generation is achieved via DNA templated cascade reaction, which demonstrated impressive suppressions to VEGF mRNA and protein expressions in cells and in vivo tumor growth and indicated promising application of the designed strategy in gene therapy
InGaN/GaN multiple-quantum-well light-emitting diodes with a grading InN composition suppressing the Auger recombination
Cataloged from PDF version of article.In conventional InGaN/GaN light-emitting diodes (LEDs), thin InGaN quantum wells are usually adopted to mitigate the quantum confined Stark effect (QCSE), caused due to strong polarization induced electric field, through spatially confining electrons and holes in small recombination volumes. However, this inevitably increases the carrier density in quantum wells, which in turn aggravates the Auger recombination, since the Auger recombination scales with the third power of the carrier density. As a result, the efficiency droop of the Auger recombination severely limits the LED performance. Here, we proposed and showed wide InGaN quantum wells with the InN composition linearly grading along the growth orientation in LED structures suppressing the Auger recombination and the QCSE simultaneously. Theoretically, the physical mechanisms behind the Auger recombination suppression are also revealed. The proposed LED structure has experimentally demonstrated significant improvement in optical output power and efficiency droop, proving to be an effective solution to this important problem of Auger recombination. (C) 2014 AIP Publishing LLC
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