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Target Concepts:
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Query: UMLS:C0002962 (
angina
)
21,142
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
EDRF is a potent, endogenous vasodilator that is produced and released from endothelial cells and subsequently causes the relaxation of VSM through the activation of soluble guanylate cyclase and an increase in VSM cyclic GMP. Structurally, EDRF is likely to be NO or a related nitrogen oxide-containing compound. It is synthesized in endothelial and other cell types from L-arginine by a calcium-
calmodulin
and NADPH-dependent enzyme. Its action is very similar to the nitrovasodilators that act directly on VSM. EDRF is present in all vascular beds, large and small vessels, and in a wide range of species. Its role in human vascular physiology and pathophysiology is just beginning to be understood. EDRF is a potent endogenous vasodilator and inhibitor of platelet aggregation and adhesion. Its activity is impaired in hypertension and atherosclerosis, and its absence due to endothelial damage may play a role in cerebral and coronary vasospasm. It is a mediator of flow-dependent vasodilation, and its inhibition by hypoxia may contribute to the hypoxic pulmonary vasoconstrictor response. Endothelial cell damage and impairment of EDRF production may also contribute to acute and chronic pulmonary hypertension. A further understanding of the chemical nature and synthetic pathways of EDRF should lead to the production of analogs and antagonists, which may play an important role in future treatments for atherosclerosis, myocardial infarction,
angina
, hypertension, and other vascular diseases. The recent realization that EDRF serves as the second messenger for guanylate cyclase activation and cyclic GMP production in a variety of cell types outside of the cardiovascular system, including renal and respiratory epithelium, cerebellar neurons, macrophages, and adrenocytes, suggests even broader implications. The importance of EDRF to the anesthesiologist may go beyond an understanding of its role in cardiovascular physiological and pathophysiological states. Initial studies have shown that the endothelium may play a role in mediating the vascular actions of anesthetics, and that anesthetics can inhibit the production, release, or action of EDRF. How are these interactions mediated? Are there significant differences between anesthetics with regard to their effects on EDRF? Is there a clinically significant effect of anesthetics on basal activity of EDRF, or only in response to exogenous stimulation? Conversely, it is important to determine if alterations in endothelial cell function by various disease states such as hypertension, atherosclerosis, adult respiratory distress syndrome, cerebral vasospasm, and others cause changes in the vascular actions of anesthetics. The potential interactions of anesthetics with EDRF production and action in cell types other than the endothelium have not yet been explored.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:Endothelium-derived relaxing factor: basic review and clinical implications. 186 89
Nisoldipine is a calcium antagonist that specifically blocks the slow or voltage-dependent calcium channel up to the highest concentrations. This mode of action has been confirmed in pharmacological studies on isolated organs, electrophysiological and binding studies, and by the measurement of transmembrane calcium transport. As with other dihydropyridine calcium antagonists, an interaction with intracellular calcium reservoirs and
calmodulin
seems to be of minor importance. The drug exhibits higher potency, longer duration of action, and a higher binding affinity in vitro and in vivo than nifedipine. In contrast to its vasodilating and spasmolytic activity, its negative inotropic effect occurs in vitro only after higher concentrations than after nifedipine. In whole animals a secondary positive inotropic effect occurs regularly owing to sympathetic counter-regulation. The influence of nisoldipine on cardiac stimulus formation and conduction is also very slight in anesthetized animals, and is completely eliminated in awake animals and humans by counter-regulation up to very high doses. The cardiac anti-ischemic action of nisoldipine has been demonstrated in various ischemia models and is probably based predominantly on its afterload-reducing properties in addition to its spasmolytic effect on the coronary arteries. Various other suspected effects, for which there are isolated indications, e.g., inhibition of thromboxane synthesis, preload reduction, interaction with the transport of adenosine, and normalization of the sarcolemmal Na+, K(+)-ATPase activity, are probably of subordinate importance. Its antihypertensive effect is explained primarily by lowering of the peripheral resistance. There are, however, some indications that nisoldipine exerts certain effects over and above pure vasodilation. The prevention of postischemic calcium overloading in the renal tubule epithelium and the natriuretic effect are probably of importance in the therapeutic action. Clinically, nisoldipine was found more potent and prolonged in its action in comparison with nifedipine. In comparative studies, nisoldipine, 10 mg once a day, was found equieffective with nifedipine 10 mg three times or 20 mg twice a day in
angina
or hypertension, respectively.
...
PMID:The pharmacology of nisoldipine. 315 74
Carvedilol is a third-generation beta-blocker, with the S-enantiomer being more active than the R-enantiomer. Clinically, it has been used in the treatment of hypertension, congestive heart failure and
angina pectoris
. Each enantiomer of Carvedilol exhibits differential pharmacological effects. However, the cellular effects of individual enantiomer are not well understood. To gain insights into how each enantiomer affects cells, we analysed differential protein expression levels in vascular smooth muscle cells (A7r5) incubated separately with S- and R-Carvedilol by iTRAQ-coupled 2-D LC-MS/MS approach. Thirteen proteins were identified with statistically significant changes in cells incubated with S-Carvedilol, while the changes of most proteins incubated with R-Carvedilol were less significant. Among these proteins, actin in aortic smooth muscle (ACTA2),
calmodulin
, S100-A6, S100-A10, S100-A11, thioredoxin, lactadherin and heat-shock protein 105 kDa were found to be closely relevant with the clinical effects of Carvedilol. Furthermore, the changes in protein levels were validated by Western blot. Our findings thus provided molecular evidence on a comprehensive protein profile on Carvedilol-cell interaction, which may shed new light in molecular events underlying Carvedilol treatment.
...
PMID:Proteomic profiling of cellular responses to Carvedilol enantiomers in vascular smooth muscle cells by iTRAQ-coupled 2-D LC-MS/MS. 2040 66
