Mariko Himeno

Increased basal levels of plasma nitric oxide in Type 2 diabetic subjects Relationship to microvascular complications

To assess the underlying mechanisms of decreased endothelial function and advanced vascular complications in patients with Type 2 diabetes, we determined basal levels of plasma nitric oxide (NO(x): NO(2)(-) and NO(3)(-)) using a newly developed high-performance liquid chromatography (HPLC)-Griess method in hospitalized 129 diabetic and 76 nondiabetic subjects, and examined their clinical characteristics. Serum lipid peroxide and advanced glycation end products (AGEs) as markers of oxidative stress were also measured, and intima-media thickness (IMT) of the carotid artery was evaluated as a marker of atherosclerosis. In diabetic subjects, microvascular complications were newly evaluated during their admission. There were no differences in age or sex between the diabetic and nondiabetic subjects. Although there was no difference in basal plasma NO(2)(-) levels between the two groups, the basal levels of plasma NO(3)(-) in diabetic subjects were significantly higher than those in nondiabetic subjects. Plasma NO(x) levels in neither diabetic nor nondiabetic subjects correlated with serum lipids, HbA1c, or IMT. In diabetic subjects, plasma NO(3)(-) levels were related not only to the presence of hypertension but also to advanced microvascular complications. Moreover, plasma NO(3)(-) levels were positively correlated with both serum lipid peroxide and AGEs. Multiple regression analysis revealed that serum AGEs level was strongly associated with plasma NO(3)(-) level. Thus, the findings are consistent with the hypothesis that decreased endothelium-dependent vasodilation in diabetic subjects is associated with the impaired action of NO secondary to its inactivation resulting from increased oxidative stress, rather than decreased NO production from vascular endothelium, and that abnormal NO metabolism is related to advanced diabetic microvascular complications.

Insulin resistance is associated with reduced nocturnal falls of blood pressure in normotensive, nonobese type 2 diabetic subjects.

To assess the relationship between insulin resistance and ambulatory blood pressure (BP) pattern, we determined glucose infusion rate (GIR) as a marker of insulin resistance using a glucose clamp method, and measured 24-h BPs in 25 normotensive, nonobese type 2 diabetic subjects. They were divided into two groups: 11 dippers and 14 nondippers. Clinical characteristics were similar in the two groups except for orthostatic fall in systolic BP. The median GIR level was significantly lower in nondippers than in dippers (P < 0.05). Spearmans rank correlation revealed that the GIRs were negatively correlated with the systolic, diastolic and mean BPs during nighttime (P < 0.05 or less), but not with daytime or whole day BPs. Moreover, based on a logistic regression analysis, the GIR as well as orthostatic fall in systolic BP discriminated independently between dippers and nondippers. Thus, our results suggest that insulin resistance is associated with decreased nocturnal BP fall in type 2 diabetic subjects.

Implication of steady state concentrations of nitrite and nitrate metabolites of nitric oxide in plasma and whole blood in healthy human subjects

1. The aim of the present study was to determine whether the steady state NOx concentration reflects NOx formation in vivo.

Decrease in plasma NOx concentration by isosorbide dinitrate, an organic nitrate ester.

It has been suggested that isosorbide dinitrate (ISDN)–induced venodilation could be ascribed to preferential accumulation of the agent in venous tissues, resulting in higher concentrations of nitric oxide (NO). Here, the authors investigated whether the venodilating effect of ISDN is associated with a preferential increase in plasma concentrations of NOx (NO2− and NO3−, stable end-products of NO) in venous blood than arterial blood. Plasma NOx was measured by high-performance liquid chromatography–Griess system with a sensitivity of 0.01 &mgr;M for NO2− and 0.1 &mgr;M for NO3−. Arterial and venous blood samples were obtained after coronary angiography from the aorta and right atrium of patients with or without ischemic heart disease. Nicardipine, a calcium channel blocker, was used as a non–NO-related arteriovasodilator. At 1 mg i.v., it did not cause any changes in NOx concentration in arterial and venous blood irrespective of hemodynamic changes. However, ISDN (3 mg i.v.) increased NO2− and decreased NO3− in both arterial and venous blood, with concomitant venodilation. Further analysis revealed that plasma NO2− increased in the pulmonary circulation and this increase was preserved after nicardipine and ISDN, and that ISDN, but not nicardipine, increased plasma NO3− in the pulmonary circulation. The authors did not detect higher concentrations of NOx in venous blood relative to their level in arterial blood. Further studies are necessary to clarify the kinetics of NO and NO-related compounds in the whole body.

Paradoxical decrease in plasma NOx by L-arginine load in diabetic and non-diabetic subjects

L-arginine, a substrate of nitric oxide synthase, was infused (30 g/300 ml/30 min) to patients with or without type 2 diabetes to examine whether or not endothelial dysfunction expressed as attenuated depressor response to the substrate in diabetic patients may accompany attenuated plasma NOx (NO2− and NO3−; an index of NO formation) elevation. Decrease in blood pressure by L-arginine was significantly smaller in diabetic patients than that in non-diabetic patients, and increase in plasma cGMP level in diabetic patients tended to be smaller and retarded than non-diabetic patients. However, plasma NOx decreased in both groups in a similar degree without changes in urinary NOx excretion, implying that NOx in plasma moved to other compartments. These results indicate that plasma NOx could not be solely used as an index of NO formation by L-arginine load and that this paradoxical decrease in plasma NOx would require further examination extending to other NOx compartments.