Process of gallnut suppository preparation / 中国中药杂志

The main objective was to research the process of gallnut suppository preparation with its water extract as the main drug, and evaluate its irritation to rectal mucosa. gallnut extract was obtained by decocting method, and its suppository preparation was obtained by fusion method with semi-synthetic aliphatic esters and rose flower oil as the matrix. Weight difference and in vitro melting time limit of the suppository were assayed and UV-Vis was used to determine the contents of polyphenols, tannin and saccharide. The irritation to colon mucosa was evaluated after successive administration of 14 days to New Zealand white rabbits. Finally, the prescription compositions were determined: semi-synthetic aliphatic esters and rose flower oil with the ratio of 2:1 as the proper matrix, with the drug loading of 54%. The prepared suppository was brown, conical and smooth. The weight difference was (1.43±0.03) g, with an average melting time limit of (17±2) min. The Contents of Polyphenols, tannic and polysaccharide were 332.4, 245.0, 3.3 mg•g-1 respectively in each suppository. The results also showed that the continuous administration had no irritation to rectal mucosa. It can be concluded that the suppository was an acceptable administrate form, whose preparation process was easily controlled, and with no irritation to rectum mucosa.

Diverse expression of ER-α36, a novel variant of ER-α, in hippocampus and cortex of neonatal and adult rats / 生理学报

ER-α36, a novel variant of ER-α, is expressed in breast, uterus, digestive tract, respiratory tract etc. The aim of the present study was to investigate the distribution and expression of ER-α36 in the central nervous system (CNS). Here, we comparatively analyzed the expression pattern of ER-α36 in the hippocampus and cortex of neonatal (1-day-old) and adult (12-week-old) Sprague-Dawley (SD) rats by using immunohistochemistry/immunocytochemistry analysis and Western blot. The results showed that ER-α36 was expressed both in hippocampus and cortex of adult rats, but mainly distributed in pyramidal neurons. ER-α36 was mainly located on the cytomembrane of hippocampal and cortical neurons from neonatal rats. Compared with the cortical neurons, the hippocampal neurons showed lower ER-α36 protein expression in the neonatal rats, but exhibited higher level of ER-α36 in the adult rats. Furthermore, the adult rats showed higher levels of ER-α36 expression in both hippocampus and cortex compared with the neonatal rats. These results suggest that ER-α36 might be involved in the regulation of membrane-initiated estrogen signaling throughout the postnatal development of diverse brain regions, and thus will be a potential target for the treatment of degenerative diseases in nervous system.

Knock-down of ERα36 impacts the expression of differentiation protein in PC12 cells / 生理学报

ERα36 is a novel subtype of estrogen receptor alpha (ERα) known to play an important role in breast cancer development and widely expressed in normal tissues and cells including nerve cells. However, the expression and function of ERα36 in nerve cells have not been well elucidated. To examine whether ERα36 is involved in differentiation of nerve cells, the differentiated and undifferentiated PC12 (PC12D and PC12unD) cells were used. Transfection of ERα36-shRNA plasmid into PC12 cells was performed to establish the ERα36 gene knock-down cells model. Immunocytofluorescence and Western blot were used to analyze the expression of Nestin, β-tubulinIII and Neu-N in the PC12 cells. The results showed that ERα36 was expressed in both cell types. Compared with PC12D cells, PC12unD cells showed higher expression of Nestin and lower expression of β-tubulinIII. ERα36-shRNA-mediated knock-down of ERα36 expression enhanced the expression of β-tubulinIII and Neu-N, but attenuated Nestin expressions in PC12unD cells; ERα36 knock-down in PC12D cells mediated Nestin, β-tubulinIII and Neu-N in a contrary manner. These results indicate that ERα36 knock-down appear to be associated with inhibiting differentiation in differentiated cells and promoting differentiation in undifferentiated cells, suggesting that ERα36 is a dual regulator in nerve differentiation.