Meal-induced enhancement in insulin sensitivity is not triggered by hyperinsulinemia in rats.

Several reports confirmed the phenomenon of postprandial increase in whole-body insulin sensitivity. Although the initial step of this process is unknown, the pivotal role of postprandial hyperinsulinemia has strongly been suggested. The aim of the present study was to determine whether hyperinsulinemia per se induces insulin sensitization in healthy male Wistar rats. Rapid insulin sensitivity test (RIST) were performed in fasted, anesthetized rats before and during stable hyperinsulinemia achieved by hyperinsulinemic euglycemic glucose clamping (HEGC) with insulin infused either through the jugular vein (systemic HEGC) or into the portal circulation (portal HEGC) at a rate of 3 mU/(kg min). Insulin sensitivity expressed by the rapid insulin sensitivity (RIST) index (in milligrams per kilogram) was characterized by the total amount of glucose needed to maintain prestudy blood glucose level succeeding an intravenous bolus infusion of 50 mU/kg insulin over 5 minutes. In fasted animals, the RIST index was 37.4 +/- 3.1 mg/kg. When hyperinsulinemia mimicking the postprandial state was achieved by systemic HEGC, the RIST index (39.7 +/- 10.6 mg/kg) showed no significant changes as compared with the pre-HEGC values. Hyperinsulinemia achieved by portal insulin infusion also failed to modify the RIST index (35.7 +/- 4.3 mg/kg). The results demonstrate that acute hyperinsulinemia, no matter how induced, does not yield any sensitization to the hypoglycemic effect of insulin.

Insulin sensitization induced by oral cicletanine in conscious rabbits.

The endogenous insulin sensitizing machinery termed the hepatic insulin sensitizing substance (HISS) mechanism has been shown to be nitrergic and linked to sensory fibers in the anterior hepatic plexus. We studied whether this mechanism could pharmacologically be exploited by cicletanine, a cGMP-PDE inhibitor antihypertensive drug, in conscious rabbits. Whole body insulin sensitivity and peripheral glucose uptake were determined by hyperinsulinaemic euglycaemic glucose clamping, and cardiac radiolabelled deoxyglucose (DOG) uptake in neurogenic, achieved by perineurial capsaicin treatment of the anterior hepatic plexus through defunctionalization of hepatic sensory fibers, and metabolic, induced by dietary hypercholesterolemia, insulin resistance models after single oral doses of cicletanine (3, 10 and 30 mg kg(-1)) or rosiglitazone (3 mg kg(-1)). The effect of cicletanine on cardiac and vascular tissue NO, cGMP, cAMP was measured by means of spin trapping technique and radioimmunoassay, respectively. Insulin sensitivity and peripheral DOG uptake were significantly increased by 10 and 30 mg kg(-1) cicletanine in both healthy and hypercholesterolaemic rabbits, but not in those with neurogenic insulin resistance. Rosiglitazone had no effect in healthy and neurogenic insulin resistant rabbits although it improved insulin sensitivity in hypercholesterolemic animals. The 10 mg kg(-1) cicletanine dose induced no change in either cardiac or vascular tissue NO, cGMP or cAMP concentrations. Nevertheless, at a dose of 30 mg kg(-1) producing an insulin sensitizing effect of approximately the same amplitude as seen with 10 mg kg(-1), the drug significantly increased tissue NO and cGMP concentrations. Oral cicletanine attains its insulin sensitizing effect at doses lower than those necessary to activate the NO-cGMP pathway in the cardiovascular system. This metabolic effect requires functional integrity of hepatic sensory nerves.

Differential effects of fluoxetine enantiomers in mammalian neural and cardiac tissues.

Racemic fluoxetine is a widely used SSRI antidepressant compound having also anticonvulsant effect. In addition, it was shown that it blocked several types of voltage gated ion channels including neural and cardiac calcium channels. In the present study the effects of enantiomers of fluoxetine (R(-)-fluoxetine and S(+)-fluoxetine) were compared on neuronal and cardiac voltage-gated Ca2+ channels using the whole cell configuration of patch clamp techniques, and the anticonvulsant action of these enantiomers was also evaluated in a mouse epilepsy model. In isolated pyramidal neurons of the dorsal cochlear nucleus of the rat the effect of fluoxetine (S(+), R(-) and racemic) was studied on the Ca2+ channels by measuring peak Ba2+ current during ramp depolarizations. All forms of fluoxetine reduced the Ba2+ current of the pyramidal cells in a concentration-dependent manner, with a Kd value of 22.3+/-3.6 microM for racemic fluoxetine. This value of Kd was higher by one order of magnitude than found in cardiac myocytes with fluoxetine enantiomers (2.4+/-0.1 and 2.8+/-0.2 microM). Difference between the effects of the two enantiomers on neuronal Ba2+ current was observed only at 5 microM concentration: R(-)-fluoxetine inhibited 28+/-3% of the peak current, while S(+)-fluoxetine reduced the current by 18+/-2% (n=13, P<0.05). In voltage clamped canine ventricular cardiomyocytes both enantiomers of fluoxetine caused a reversible concentration-dependent block of the peak Ca2+ current measured at 0 mV. Significant differences between the two enantiomers in this blocking effect was observed at low concentrations only: S(+)-fluoxetine caused a higher degree of block than R(-)-fluoxetine (56.3+/-2.2% versus 49.1+/-2.2% and 95.5+/-0.9% versus 84.5+/-3.1% block with 3 and 10 microM S(+) and R(-)-fluoxetine, respectively, P<0.05, n=5). Studied in current clamp mode, micromolar concentrations of fluoxetine shortened action potential duration of isolated ventricular cells, while higher concentrations also suppressed maximum velocity of depolarization and action potential amplitude. This shortening effect was significantly greater in the case of S(+) than R(-)-fluoxetine at 1 and 3 microM concentrations, whereas no differences in their effects on depolarization were observed. In pentylenetetrazole-induced mouse epilepsy model fluoxetine pretreatment significantly increased the 60 min survival rate, survival duration and seizure latency. These effects were more pronounced with the R(-) than the S(+) enantiomer. The results indicate that fluoxetine exerts much stronger suppressive effect on cardiac than neuronal calcium channels. At micromolar concentrations (between 1 and 10 microM) R(-)-fluoxetine is more effective than the S(+) enantiomer on neuronal, while less effective on cardiac calcium channels. The stronger anticonvulsant effect of the R(-) enantiomer may, at least partially, be explained by these differences. Used as an antidepressant or anticonvulsant drug, less severe cardiac side-effects are anticipated with the R(-) enantiomer.