Cardiovascular Protective Effect of Shenmai Injection： A Review / 中国实验方剂学杂志

With the improvement of people's living standards and the increasing aging population， the incidence of cardiovascular diseases has sharply risen， making it the leading cause of death and a major "killer" for humans. The prevention and treatment of cardiovascular diseases still face severe challenges. Shenmai injection （SMI）， a Chinese medicinal preparation， is widely used in the prevention and treatment of cardiovascular diseases because of its individualized advantages in syndrome differentiation and definite efficacy. Meanwhile， its pharmacological effects and related mechanism are becoming increasingly clear. Modern research shows that SMI can exert cardioprotective effects by reducing myocardial inflammatory response， alleviating oxidative stress， inhibiting myocardial cell apoptosis， improving microcirculatory dysfunction after myocardial ischemia-reperfusion， protecting mitochondrial structure and function， inhibiting ventricular remodeling， reducing drug-induced cardiotoxicity， and possessing antiviral properties. Additionally， it can produce cardiovascular protection by relaxing blood vessels， protecting endothelial cells， and promoting angiogenesis. Furthermore， SMI can lower blood viscosity and lipid levels， thus improving blood rheology. In the future， more clinical trials and basic research are needed to clarify its therapeutic efficacy and target mechanism to further confirm the effectiveness and safety of its clinical application.

Chemical compositions and pharmacological activities of natural musk (Moschus) and artificial musk: A review.

ETHNOPHARMACOLOGICAL RELEVANCE: Natural musk (Moschus), derived naturally from male musk deer (Moschus berezovskii Flerov, Moschus sifanicus Przewalski, or Moschus moschiferus Linnaeus), has long been an important component of traditional Chinese medicine (TCM), and was used as resuscitation, blood circulation, and collateral drainage. detumescence and pain relief. Artificial musk was researched and applied into TCM as natural musk being as unsustainable resources. AIM OF THE STUDY: We mainly summarized chemical compositions, pharmacological activities and mechanism of action of natural and artificial musk, and designed to serve as a foundation for further research into musk chemical compositions and pharmacological effect. MATERIALS AND METHODS: Those mainstream scientific databases including Google Scholar, ScienceDirect, SpringerLink, CNKI, Wiley Online Library, web of science, were used for searching with below "Keywords", as well as literature-tracking. Literatures spanned 1962 to 2021, and involved into Chinese, English, Janpanese, Korean. RESULTS: Natural musk contains some very desirable but scarce compounds, as well as their biological features, which led to the development of artificial musk. The chemical ingredients, pharmacological activities, and mechanisms of action of natural and artificial musk are summarized and compared in this paper. Polypeptide and protein, muscone, musclide, steroids, muscopyridine, and other chemical constituents of musk demonstrated important therapeutic properties against inflammation, immune system disorders, neurological disorders, cardiovascular system disorders, and so on. The mechanism of action contributed to effect on mediators, acceptors and relative signal pathways. CONCLUSIONS: Natural and artificial musk were revealed having some activated compounds, and showed excellent pharmacological effect. Meantime, above two sides of natural and artificial musk ought to get further research.

Dopamine outside the brain: The eye, cardiovascular system and endocrine pancreas.

Dopamine (DA) and DA receptors (DR) have been extensively studied in the central nervous system (CNS), but their role in the periphery is still poorly understood. Here we summarize data on DA and DRs in the eye, cardiovascular system and endocrine pancreas, three districts where DA and DA-related drugs have been studied and the expression of DR documented. In the eye, DA modulates ciliary blood flow and aqueous production, which impacts on intraocular pressure and glaucoma. In the cardiovascular system, DA increases blood pressure and heart activity, mostly through a stimulation of adrenoceptors, and induces vasodilatation in the renal circulation, possibly through D1R stimulation. In pancreatic islets, beta cells store DA and co-release it with insulin. D1R is mainly expressed in beta cells, where it stimulates insulin release, while D2R is expressed in both beta and delta cells (in the latter at higher level), where it inhibits, respectively, insulin and somatostatin release. The formation of D2R-somatostatin receptor 5 heteromers (documented in the CNS), might add complexity to the system. DA may exert both direct autocrine effects on beta cells, and indirect paracrine effects through delta cells and somatostatin. Bromocriptine, an FDA approved drug for diabetes, endowed with both D1R (antagonistic) and D2R (agonistic) actions, may exert complex effects, resulting from the integration of direct effects on beta cells and paracrine effects from delta cells. A full comprehension of peripheral DA signaling deserves further studies that may generate innovative therapeutic drugs to manage conditions such as glaucoma, cardiovascular diseases and diabetes.

Therapeutic potential of quercetin as a cardiovascular agent.

Flavonoids are integral components of various vegetation and in foods; consequently, they represent an inevitable part of the diet. Historical and epidemiological proof recommend that diet plans consisting of flavonoids such as quercetin have positive health benefits, especially on the heart. Flavonoids have been proven to be active against hypertension, inflammation, diabetes and vascular diseases. Quercetin exhibits significant heart related benefits as inhibition of LDL oxidation, endothelium-independent vasodilator effects, reduction of adhesion molecules and other inflammatory markers, the protective effect on nitric oxide and endothelial function under conditions of oxidative stress, prevention of neuronal oxidative and inflammatory damage and platelet antiaggregant effects. Searching for experimental evidence to validate the cardioprotective effects of quercetin, we review here the recent detailed in vivo studies. Quercetin and its derivatives lead to an enhancement in heart features, indicating the prospective for quercetin to be used therapeutically in the treatment of cardiac diseases. Several evidence-based studies suggest mechanisms to observe cardiovascular diseases such as aging effects, hypertension, angiotensin-converting enzyme activity and endothelial-dependent and independent functions. Different animal models including human are also used to elucidate the in vivo role of quercetin in cardiovascular diseases. The role of quercetin and its derivatives may go beyond their existence in food and has potential as a lead molecule in drug development programs.