Browsing by Author "Duarte, AI"
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- Carvedilol improves energy production during acute global myocardial ischaemiaPublication . Monteiro, P; Duarte, AI; Moreno, AJ; Gonçalves, L; Providência, LACardiac mitochondria may become dysfunctional during ischaemia, thus compromising cardiomyocyte function. Carvedilol is an alpha(1)/beta-adrenoceptor antagonist with antioxidant, neuroprotective, cardioprotective and vascularprotective properties, and is used to treat hypertension, myocardial ischaemia and congestive heart failure. However, its impact on mitochondrial function during acute prolonged ischaemia is unknown. We aimed to study the effect of carvedilol on cardiac mitochondrial function during acute ischaemia, using Wistar rat hearts perfused with a Langendorff system, and then submitted to ischaemia in the presence and absence of carvedilol. We determined the electrical potential of the mitochondrial membrane, O(2) consumption by the respiratory chain, energy charge and the activity of the mitochondrial respiratory chain complexes. In our model, carvedilol had a preferential action on phosphorylation, increasing the mitochondrial energy charge (0.76+/-0.03 vs. 0.65+/-0.01 arbitrary units; P<0.05) and decreasing the phosphorylation lag phase (28.64+/-4.23 vs. 62.4+/-11.63 s; P<0.05) during ischaemia. The larger amount of energy available allowed the preservation of the electrical potential (201.2+/-2.45 vs. 186.66+/-3.36 mV;P<0.05), thus improving mitochondrial function during acute prolonged ischaemia
- O Carvedilol Protege Mitocôndrias Cardíacas Isquémicas de Lesões Induzidas Por Stress OxidativoPublication . Carreira, R; Duarte, AI; Monteiro, P; Santos, MS; Rego, AC; Oliveira, CR; Gonçalves, L; Providência, LAIschemia negatively affects mitochondrial function by inducing the mitochondrial permeability transition (MPT). The MPT is triggered by oxidative stress, which occurs in mitochondria during ischemia as a result of diminished antioxidant defenses and increased reactive oxygen species production. It causes mitochondrial dysfunction and can ultimately lead to cell death. Therefore, drugs able to minimize mitochondrial damage induced by ischemia may prove to be clinically effective. We analyzed the effect of carvedilol, a beta-blocker with antioxidant properties, on mitochondrial dysfunction. Carvedilol decreased levels of TBARS (thiobarbituric acid reactive substances), an indicator of oxidative stress, which is consistent with its antioxidant properties. Regarding cell death by apoptosis, although ischemia did increase caspase-8-like activity, there were no changes in caspase-3-like activity, which is activated downstream of caspase-8; this may indicate that the apoptotic cascade is not activated by 60 minutes of ischemia. We conclude that carvedilol protects ischemic mitochondria by preventing oxidative mitochondrial damage, and, by so doing, it may also inhibit the formation of the MPT pore.
- O Piruvato Melhora A Energética Mitocondrial Num Modelo Animal Ex-vivo de Isquemia Miocárdica GlobalPublication . Monteiro, P; Duarte, AI; Moreno, AJ; Gonçalves, L; Providência, LAPyruvate is an energy substrate with known cardioprotective activity. We know now that this is due not only to its antioxidant activity, but also to its reduction of intracellular acidosis, modulation of intracytosolic calcium and improvement of cardiomyocyte contractility. However, the role of cardiac mitochondria in such positive effects has only recently begun to be understood and the exact mechanisms of the effect of pyruvate on mitochondria are still largely unknown. Aiming to study the effect of pyruvate on cardiac mitochondrial function during acute ischemia, we used an ex-vivo animal model, perfused in a Langendorff system and then subjected to ischemia in the presence and absence of pyruvate. We evaluated the mitochondrial membrane electrical potential, the respiratory chain O2 consumption (and respiratory control ratio) and the energy charges generated with different energy substrates. We conclude that pyruvate has some effect on the mitochondrial oxidative system (by non-significantly improving the respiratory control ratio), but its main action is on the phosphorylation system, significantly decreasing the time taken to complete a phosphorylation cycle (lag phase) and improving ATP production (increase in energy charge), thus allowing better maintenance of mitochondrial membrane structure, with consequent improvement of the electrical potential after a phosphorylation cycle. These findings have enabled better understanding of the mechanisms behind pyruvate cytoprotection in ischemic cardiomyopathy, clearly highlighting the essential role of cardiac mitochondria in this process.
- Protective effect of trimetazidine on myocardial mitochondrial function in an ex-vivo model of global myocardial ischemiaPublication . Monteiro, P; Duarte, AI; Gonçalves, L; Moreno, AJ; Providência, LATrimetazidine is an anti-ischemic drug whose cytoprotective mechanisms are not yet fully understood (but until now mainly related to the trimetazidine-induced "metabolic shift" from lipid beta-oxidation to glucose aerobic oxidation). We studied the effect of trimetazidine on the mitochondrial function of ischemic Wistar rat hearts perfused with glucose, using a model of ex-vivo perfusion (Langendorff system). We measured the electrical potential of the mitochondrial membrane, O2 consumption by the respiratory chain, energy charges generated and the enzyme activities of the respiratory chain complexes. In this model, trimetazidine had a preferential action on the oxidative system (mainly on complex I), increasing its enzyme activity and decreasing O2 consumption after phosphorylation; this could decrease oxygen free radical production and increase mitochondrial integrity, thus allowing the maintenance of the electrical potential. These results allow us to better understand the cytoprotective effects of trimetazidine in coronary artery disease.
- Valsartan improves mitochondrial function in hearts submitted to acute ischemiaPublication . Monteiro, P; Duarte, AI; Gonçalves, L; Providência, LAThe effect of valsartan, an angiotensin II-type I receptor blocker, on the mitochondrial function, was studied using an ex vivo animal model (hearts from Wistar rats), perfused in a Langendorff system and then submitted to global acute ischemia. Parameters evaluated were: membrane electrical potential (DeltaPsi, using a tetraphenylphosphonium-TPP+-electrode), oxygen consumption by the respiratory chain (Clark-type O2 electrode), phosphorylation lag phase (time necessary to phosphorylate a fixed amount of ADP) and ATP/ADP ratio (adenine nucleotides quantified by high-pressure liquid chromatography-HPLC). Valsartan acts preferentially in the phosphorylation, increasing ATP/ADP ratios (succinate: 1.6+/-0.4 versus 0.5+/-0.1--P<0.05; ascorbate/N,N,N',N'-tetramethyl-P-phenylenodiamine-TMPD: 1.1+/-0.2 versus 0.4+/-0.1--p<0.05 versus ischemia in the absence of valsartan) and decreasing lag phase (glutamate/malate: 50.0+/-9.6 s versus 127.2+/-19.03 s-84.6+/-16.2% versus 215.3+/-32.2%; P=0.01; succinate: 111.8+/-33.1 s versus 275.73+/-45.99 s-168.2+/-49.8% versus 414.9+/-69.2%; P=0.02 or ascorbate/TMPD: 11.0+/-3.9 s versus 62.4+/-11.63 s-34.9+/-12.4% versus 198.1+/-36.9%; P=0.001 versus ischemia in the absence of valsartan). This enables a higher energy production in hearts submitted to acute ischemia, for which having energy becomes critical to preserve mitochondrial function. These mechanisms allow us to better understand valsartan cytoprotection in ischemic cardiomyopathy.