Here we report the bipolar doping of GaN1-xAsx with high As content to conductivities above 4 S/cm at room temperature using Mg or Te. The carrier type was confirmed by thermopower measurements. Doping requires an increase in Ga flux during growth resulting in a mixed phase material of polycrystalline selleck products GaAs:N embedded in amorphous GaN1-xAsx. VC 2011 American Institute of Physics. [doi: 10.1063/1.3657779]“
“Since prostate growth is governed by the androgen signaling pathway, blockade of the pathway is regarded as an
appropriate strategy for the treatment of benign prostatic hyperplasia (BPH). Panax ginseng is known to have various pharmacological activities. Of several products of its root, red ginseng, having many bioactive ginsenosides, is most popularly used in Korea, and recently has been reported to control the proliferation of cancer cells. We here tested the effect of
a water extract of Korean red ginseng (WKRG) on testosterone-induced prostate hyperplasia. WKRG (daily intraperitoneal injection) prevented prostate overgrowth and epithelial thickening induced by testosterone in rats, and suppressed a rat prostate kallikrein-S3. In human prostate cells, WKRG inhibited testosterone-induced cell proliferation, arrested cell cycle by inducing p21 and p27, and induced apoptosis. INCB028050 in vitro Testosterone-induced expression of human kallikrein-3 mRNA and activation of androgen receptor (AR) were effectively inhibited by WKRG. Of the major ginsenosides included in WKRG, 20(S)-Rg3 was identified to repress AR activity and to attenuate prostate cell growth during testosterone stimulation. Moreover, 20(S)-Rg3 downregulated AR by facilitating the degradation of AR protein. WKRG and 20(S)-Rg3 were found to have new pharmacological activities against GSK621 testosterone-induced prostate
overgrowth. Given that red ginseng has been used safely in Asia for 1000 years, red ginseng and 20(S)-Rg3 could be potential therapeutic regimens for treating BPH.”
“Over the last 20 years, nearly 5000 cases of differentiated thyroid cancer have been diagnosed and treated in the regions of Russia, Ukraine and Belarus in young people previously exposed to the Chernobyl radioactive fallout during childhood. At diagnosis, 60-70% of the Chernobyl-related paediatric thyroid cancers had clinically evident cervical lymph node metastases (N1) and 10-15% had distant metastases (M1). Despite early reports suggesting that the paediatric thyroid cancer cases that developed after exposure to Chernobyl fallout were particularly aggressive, it now seems that the initial presentation and early clinical course of most of these cases are very similar to both non-radiation-associated paediatric thyroid cancers and thyroid cancers that arise after exposure to external beam irradiation.