Research Progress on the Antidepressant Effects of Baicalin and Its Aglycone Baicalein: A Systematic Review of the Biological Mechanisms.

Depression is the most prevalent mental disorder, affecting more than 300 million adults worldwide each year, which can lead to serious economic and social problems. Antidepressants are usually the first-line treatment for depression, however, traditional antidepressants on the market have the disadvantage of low remission rates and may cause side effects to patients, therefore, the current focus in the field of depression is to develop novel therapeutic agents with high remission rates and few side effects. In this context, the antidepressant effects of natural compounds have received attention. Baicalin (baicalein-7-O-glucuronide) and its aglycone baicalein (5,6,7-trihydroxyflavone) are flavonoid compounds extracted from the root of Scutellaria baicalensis. Although lacking the support of clinical data, they have been shown to have significantly promising antidepressant activity in many preclinical studies through various rodent models of depression. This paper reviews the antidepressant effects of baicalin and baicalein in experimental animal models, with emphasis on summarizing the molecular mechanisms of their antidepressant effects including regulation of the HPA axis, inhibition of inflammation and oxidative stress, reduction of neuronal apoptosis and promotion of neurogenesis, as well as amelioration of mitochondrial dysfunction. Controlled clinical trials should be conducted in the future to examine the effects of baicalin and baicalein on depression in humans.

Role of Noncoding RNA in Pulmonary Arterial Hypertension and Potential Drug Therapeutic Target.

Pulmonary arterial hypertension (PAH) is a devastating disease without effective drugs available for its treatment. An in-depth exploration of the pathogenesis of PAH, as well as inquiry into potential therapeutic targets, remains an urgent issue. Non-coding RNAs (ncRNAs) have arisen as key players in malignant tumors, cardiovascular diseases and more recently in PAH progression and development. Network pharmacology is a new discipline based on system biology, which can predict potential therapeutic targets in diseases regulated by multiple genes. In this review, we discuss the current knowledge of ncRNAs and network pharmacology regulated genes involved in PAH, as well as the search for potential drug targets for PAH.

[Effect of lead on learn and memory and release of intracellular free Ca2+ from calcium pool in dissociated mouse hippocampal neurons].

OBJECTIVE: To study effect of lead on learn and memory and the release of intracellular free Ca2+ from calcium pool in dissociated mouse hippocampal neurons. METHODS: Using a water maze we measured the ability of spatial learning of mouses. Digesting with low concentration of trypsin and gently triturating mode were used to dissociate hippocampal neurons. Using inositol 1,4,5-triphosphate (IP3) sensitive calcium store antagonist-heparine and non-IP3 sensitive calcium store (ryanodine) antagonist-procaine to stimulate hippocampal neurons, and observed the effect of Pb2+ on [Ca2+]i of hippocampal neurons by Fura-2 double wavelength fluoremetry. RESULTS: In the Morris water maze task, results indicated that mouses having drink lead water displayed significant impairment in their performance, and this extent of impairment showed in lead concentration dependent manner. Compared with control group, in condition of none of extracellular free calcium, 25 micromol x L(-1) of Pb2+ induced markedly increase of intracellular free calcium of hippocampal neurons in mouse. Heparin (IP3 sensitive calcium store antagonist) of 30 microg x ml(-1) and procaine (non-IP3 sensitive calcium store atagonist) of 0.1 mg x ml(-1) blocked the increases of [Ca2+]i in mouse hippocampal neurons elicited by 25 micromol x L(-1) of Pb2+. CONCLUSION: Chronic exposure to lead (Pb2+) reduces the ability of spatial learing and memory of mice. High level of Pb2+ facilitated release of intracellular free calcium from IP3 sensitive and non-IP3 sensitive calcium store and induced the increases of intracellular free calcium in mouse hippocampal neurons.

Gastric mucosal injury due to hemorrhagic reperfusion and efficacy of Salvia miltiorrhizae extract F and cimetidine.

AIM: To observe the gastric mucosal injury caused by hemorrhagic shock and reperfusion and to compare the effect between Salvia miltiorrhizae extract F (SEF) and cimetidine (CI) on it. METHODS: A model of hemorrhage/reperfusion injury was produced by Itoh method. Wistar rats were randomly divided into three groups: 0.9% sodium chloride treatment group (NS group), SEF treatment group (SEF group), and CI treatment group (CI group). Saline, SEF and CI were injected respectively. The index of gastric mucosal lesions (IGML) was expressed as the percentage of lesion area in the gastric mucosa. The degree of gastric mucosal lesions was categorized into grades 0, 1, 2, 3. Atom absorption method was used to measure the intracellular calcium content. Radioimmunoassay was used to measure the concentrations of prostaglandins. RESULTS: IGML (%) and grade 3 (%) were 23.18+/-6.82, 58.44+/-9.07 in NS group, 4.42+/-1.39, 20.32+/-6.95 in SEF group and 3.74+/-1.56, 23.12+/-5.09 in CI group, and the above parameters in SEF group and CI group decreased significantly (IGML: SEF vs NS, t = 6.712, P = 0.000<0.01; CI vs NS, t = 6.943, P = 0.000<0.01; grade 3: SEF vs NS, t = 8.386, P = 0.000; CI vs NS, t = 8.411, P = 0.000), but the grade 0 and grade 1 damage in SEF group (22.05+/-5.96, 34.12+/-8.12) and CI group (18.54+/-4.82, 30.15+/-7.12) were markedly higher than those in NS group (3.01+/-1.01, 8.35+/-1.95; grade 0: SEF vs NS, t = 8.434, P = 0.000<0.01; CI vs NS, t = 7.950, P = 0.000<0.01; grade 1: SEF vs NS, t = 8.422, P = 0.000<0.01; CI vs NS, t = 8.448, P = 0.000<0.01). The intracellular calcium content (microg/mg) in SEF group (0.104+/-0.015) and CI group (0.102+/-0.010) was markedly lower than that in NS group (0.131+/-0.019, SEF vs NS, t = 2.463, P = 0.038<0.05; CI vs NS, t = 3.056, P = 0.017<0.05). The levels (pg/mg) of PGE(2), 6-keto-PGF(1alpha) and 6-keto-PGF(1alpha)/TXB(2) were 540+/-183, 714+/-124, 17.38+/-5.93 in NS group and 581+/-168, 737+/-102, 19.04+/-8.03 in CI group, 760+/-192, 1 248+/-158, 33.42+/-9.24 in SEF group, and the above parameters in SEF group markedly raised (PGE(2): SEF vs NS, t = 2.282, P = 0.046<0.05; SEF vs CI, t = 2.265, P = 0.047<0.05; 6-keto-PGF(1alpha): SEF vs NS, t = 6.583, P = 0.000<0.000; SEF vs CI, t = 6.708, P = 0.000<0.01; 6-keto-PGF(1alpha)/TXB(2): SEF vs NS, t = 3.963, P = 0.003<0.001; SEF vs CI, t = 3.243, P = 0.009<0.01), whereas TXB(2) level in SEF group (45.37+/-7.54) was obviously lower than that in NS group (58.28+/-6.74, t = 3.086, P = 0.014<0.05) and CI group (54.32+/-6.89, t = 2.265, P = 0.047<0.05). No significant difference was shown between NS group and CI group (PGE(2): t = 0.414, P = 0.688>0.05; 6-keto-PGF(1alpha): t = 0.310, P = 0.763>0.05; TXB(2): t = 1.099, P = 0.298>0.05; 6-keto-PGF(1alpha)/TXB(2): t = 0.372, P = 0.718>0.05). CONCLUSION: Both SEF and CI could inhibit reperfusion-induced injury in gastric mucosa, but with different mechanisms. SEF could not only enhance the protective effect of gastric mucosa, but also abate the injury factors, while CI can only abate the injury factors.