José Carlos Toledo

A new inorganic vasodilator, trans-[Ru(NO)(NH3)4(POEt)3](PF6)3: hypotensive effect of endothelium-dependent and -independent vasodilators in different hypertensive animals models☆

The hypotensive effect of RuNO was investigated in acute and chronic hypertensive rats, as well as in normotensive rats. Acute hypertension rats were used with 30% increase on basal BP (phenylephrine, angiotensin II (Ang II), N(G)-nitro-L-arginine methyl ester (L-NAME), and adult spontaneously hypertensive rats (SHR) (basal BP 168 +/- 3 mm Hg) were used as models for chronic hypertension. Rats were implanted with catheters (iv/ia) for BP measurements and for in bolus administration of RuNO, sodium nitroprusside (SNP), and acetylcholine (Ach) (10, 20, 40 nmol/kg, iv). The principal findings of this study were: (i) The hypotensive response to RuNO was 150% higher in acutely (phenylephrine and Ang II) and chronically (SHR) hypertensive rats than in normotensive rats, except in the case of L-NAME-induced hypertension (deltaMAP = 10 +/- 1.4 mm Hg). Chronic SHR showed 60% increase (deltaMAP = 19 +/- 0.8 mm Hg) in the effect compared to normotensive rats. (ii) The hypotensive response to SNP was lower (60%) in hypertensive rats than in normotensive rats, when compared to RuNO. However, the responses were similar in L-NAME-induced hypertension (deltaMAP = 30 +/- 2 mm Hg). (iii) The vasodilator response to Ach was increased in rats with Ang II-induced hypertension (deltaMAP = 53 +/- 1 mm Hg) and in SHR (deltaMAP = 67 +/- 3 mm Hg). RuNO response was more potent than SNP in hypertensive models and the increment in relation to normotensive was observed in the phenylephrine- and L-NAME-treated rats. This response could be correlated to the different endothelial dysfunction present in each model.

Release of NO by a nitrosyl complex upon activation by the mitochondrial reducing power

The reaction of trans-[Ru(NH(3))(4)P(OEt)(3)NO](3+) and mitochondria was investigated through differential pulse polarography and fluorimetry. The nitrosyl complex undergoes one-electron reduction centered on the NO ligand site. The reaction between the mitochondrial reductor and trans-[Ru(NH(3))(4)P(OEt)(3)NO](3+) exhibits a second order specific rate constant calculated as k=2 x 10(1) M(-1) s(-1). The reduced species, trans-[Ru(NH(3))(4)P(OEt)(3)NO](2+), quickly releases NO, yielding trans-[Ru(NH(3))(4)P(OEt)(3)H(2)O](2+). The low toxicities of both trans-[Ru(NH(3))(4)P(OEt)(3)(NO)](2+) and trans-[Ru(NH(3))(4)P(OEt)(3)H(2)O](2+) and its ability to release NO after reductive activation in a biological medium make the nitrosyl compound a useful model of a hypotensive drug.

Gastric S-nitrosothiol formation drives the antihypertensive effects of oral sodium nitrite and nitrate in a rat model of renovascular hypertension

Many effects of nitrite and nitrate are attributed to increased circulating concentrations of nitrite, ultimately converted into nitric oxide (NO(•)) in the circulation or in tissues by mechanisms associated with nitrite reductase activity. However, nitrite generates NO(•) , nitrous anhydride, and other nitrosating species at low pH, and these reactions promote S-nitrosothiol formation when nitrites are in the stomach. We hypothesized that the antihypertensive effects of orally administered nitrite or nitrate involve the formation of S-nitrosothiols, and that those effects depend on gastric pH. The chronic effects of oral nitrite or nitrate were studied in two-kidney, one-clip (2K1C) hypertensive rats treated with omeprazole (or vehicle). Oral nitrite lowered blood pressure and increased plasma S-nitrosothiol concentrations independently of circulating nitrite levels. Increasing gastric pH with omeprazole did not affect the increases in plasma nitrite and nitrate levels found after treatment with nitrite. However, treatment with omeprazole severely attenuated the increases in plasma S-nitrosothiol concentrations and completely blunted the antihypertensive effects of nitrite. Confirming these findings, very similar results were found with oral nitrate. To further confirm the role of gastric S-nitrosothiol formation, we studied the effects of oral nitrite in hypertensive rats treated with the glutathione synthase inhibitor buthionine sulfoximine (BSO) to induce partial thiol depletion. BSO treatment attenuated the increases in S-nitrosothiol concentrations and antihypertensive effects of oral nitrite. These data show that gastric S-nitrosothiol formation drives the antihypertensive effects of oral nitrite or nitrate and has major implications, particularly to patients taking proton pump inhibitors.

Anodic oxidation of free nitric oxide at gold electrodes modified by a film of trans-[Ru(III)(NH3)4(SO4)4pic]+ and molybdenum oxide

Abstract Gold surfaces were modified with an electrochemically deposited layer of non-stoichiometric molybdenum oxides. At these surfaces, trans -[Ru(III)(NH 3 ) 4 (SO 4 )4pic] + complex was incorporated in a controlled way by cycling the potential consecutively in the range +0.50 to −0.25 V at pH 2.6. Very reproducible voltammetric curves corresponding to the electrochemical process of the ruthenium complex were obtained, confirming the immobilisation of the material into the molybdenum oxide film. The anodic oxidation of nitric oxide (NO) at pH 7.4 was investigated at the modified electrode containing the molybdenum oxide+ trans -[Ru(III)(NH 3 ) 4 (SO 4 )4pic] + complex and an enhancement in the current response was observed compared with the signal at a bare electrode. The rate for NO electrochemical oxidation was dependent on the amount of catalytic ruthenium sites dispersed into the molybdenum oxide film. A linear relationship between current signals measured by square wave voltammetry and NO concentration was obtained in the 0–10 μM range. The applicability of the modified electrode as a sensor for real-time NO monitoring was also demonstrated.

Electrochemical and spectrophotometric methods for evaluation of NO dissociation rate constants from nitrosyl metal complexes activated through reduction.

Electrochemical and spectrophotometric methods are described for measuring the rate of nitric oxide (NO) dissociation (k(NO)) from coordination compounds. Electrochemical methods based on double-potential step chronoamperometry and rotating ring-disc electrode voltammetry techniques proved to be suitable for measuring NO dissociation from 0.03 to 4.0 s(-1). The spectrophotometric method using an ancillary ligand as a colorimetric indicator is illustrated on measuring k(-NO)=0.002 s(-1). This methodology is limited only by the rate of the ancillary ligand substitution.