MIRABEGRON INDUCED RELAXATION OF ISOLATED BOVINE CORONARY SEGMENTS: ROLE OF NO AND K+ CHANNEL.

It was already known that mirabegron, a ß3-adrenoceptor agonist, affected cardiac muscle, data also demonstrated that mirabegron induced a relaxant effect in rat aortic vessels by a mechanism dependent on nitric oxide production. This study examined the possible effects of mirabegron on the coronary vascular tone. Results show that mirabegron induced an acute relaxant effect on coronary segments' contractility, and the relaxation is partly dependent on nitric oxide and K+ channel activation. These findings emphasize the need to consider these mechanisms when translating mirabegron's effects to clinical applications. Mirabegron, the first approved ß3-adrenoceptor agonist, has demonstrated positive effects in heart failure. Research indicates that ß3 agonists induce prompt relaxation in rat aortic and human coronary vessels through a pathway mediated by NO. This study examined mirabegron's influence on bovine coronary segments' contractility. Using isolated tissue baths, the impact of mirabegron on bovine coronary artery segments' contractility was assessed. The plasma level of NO was measured with a specialized kit. NO was determined by measuring plasma nitrite concentrations by spectrophotometric analysis at 540 nm. Mirabegron evoked relaxation in bovine coronary artery segments in a dose-dependent manner. However, this effect was inhibited by the presence of potassium chloride (KCl) (70mM) and methylene blue (30µM). Both potassium channel and NO pathways were found to play a role in the relaxations induced by mirabegron. Furthermore, mirabegron was observed to enhance in vivo nitric oxide (NO) levels, a crucial signaling molecule maintaining cardiovascular equilibrium. Our findings illustrate that mirabegron induces coronary vessel relaxation through the activation of both NO and K+ channels. These findings emphasize the need to consider these mechanisms when translating mirabegron's effects to clinical applications.

Effect of simvastatin on vascular tone in porcine coronary artery: Potential role of the mitochondria.

Statins induce acute vasorelaxation which may contribute to the overall benefits of statins in the treatment of cardiovascular disease. The mechanism underlying this relaxation is unknown. As statins have been shown to alter mitochondrial function, in this study we investigated the role of mitochondria in the relaxation to simvastatin. Relaxation of porcine coronary artery segments by statins was measured using isolated tissue baths. Mitochondrial activity was determined by measuring changes in rhodamine 123 fluorescence. Changes in intracellular calcium levels were determined in freshly isolated smooth muscle cells with Fluo-4 using standard epifluorescent imaging techniques. Simvastatin, but not pravastatin, produced a slow relaxation of the coronary artery, which was independent of the endothelium. The relaxation was attenuated by the mitochondrial complex I inhibitor rotenone (10µM) and the complex III inhibitor myxothiazol (10µM), or a combination of the two. The complex III inhibitor antimycin A (10µM) produced a similar time-dependent relaxation of the porcine coronary artery, which was attenuated by rotenone. Changes in rhodamine 123 fluorescence showed that simvastatin (10µM) depolarized the membrane potential of mitochondria in both isolated mitochondria and intact blood vessels. Simvastatin and antimycin A both inhibited calcium-induced contractions in isolated blood vessels and calcium influx in smooth muscle cells and this inhibition was prevented by rotenone. In conclusion, simvastatin produces an endothelium-independent relaxation of the porcine coronary artery which is dependent, in part, upon effects on the mitochondria. The effects on the mitochondria may lead to a reduction in calcium influx and hence relaxation of the blood vessel.