Urs Scherrer

Nitric oxide release accounts for insulin's vascular effects in humans.

Insulin exerts effects on the vasculature that (a) may play a role in the regulation of blood pressure; and (b) by boosting its own delivery to target tissues, also have been proposed to play an integral part in its main action, the promotion of glucose disposal. To study the role of nitric oxide (NO) in the mediation of insulins effects on the peripheral vasculature, NG-monomethyl-L-arginine (L-NMMA), a specific inhibitor of the synthesis of endothelium-derived NO, was infused into the brachial arteries of healthy volunteers both before, and at the end of a 2-h hyperinsulinemic (6 pmol/kg per min) euglycemic clamp. L-NMMA (but not norepinephrine, an NO-independent vasoconstrictor) caused larger reductions in forearm blood flow during hyperinsulinemia than at baseline. Moreover, L-NMMA prevented insulin-induced vasodilation throughout the clamp. Prevention of vasodilation by L-NMMA led to significant increases in arterial pressure during insulin/glucose infusion but did not alter glucose uptake. These findings indicate that insulins vasodilatory effects are mediated by stimulation of NO release, and that they play a role in the regulation of arterial pressure during physiologic hyperinsulinemia. Abnormalities in insulin-induced NO release could contribute to altered vascular function and hypertension in insulin-resistant states.

Insulin Resistance, Hyperlipidemia, and Hypertension in Mice Lacking Endothelial Nitric Oxide Synthase

Background—Insulin resistance and arterial hypertension are related, but the underlying mechanism is unknown. Endothelial nitric oxide synthase (eNOS) is expressed in skeletal muscle, where it may govern metabolic processes, and in the vascular endothelium, where it regulates arterial pressure. Methods and Results—To study the role of eNOS in the control of the metabolic action of insulin, we assessed insulin sensitivity in conscious mice with disruption of the gene encoding for eNOS. eNOS−/− mice were hypertensive and had fasting hyperinsulinemia, hyperlipidemia, and a 40% lower insulin-stimulated glucose uptake than control mice. Insulin resistance in eNOS−/− mice was related specifically to impaired NO synthesis, because in equally hypertensive 1-kidney/1-clip mice (a model of renovascular hypertension), insulin-stimulated glucose uptake was normal. Conclusions—These results indicate that eNOS is important for the control not only of arterial pressure but also of glucose and lipid homeostasis. A single gene defect, eNOS deficiency, may represent the link between metabolic and cardiovascular disease.

Body fat and sympathetic nerve activity in healthy subjects.

BACKGROUND Obesity is associated with an increased incidence of cardiovascular complications, but the underlying mechanism is unknown. In experimental animals, overfeeding is associated with sympathetic activation, and there is evidence that adrenergic mechanisms contribute to cardiovascular complications. METHODS AND RESULTS We recorded resting postganglionic sympathetic nerve discharge (using intraneural microelectrodes) to skeletal muscle blood vessels in 37 healthy subjects covering a broad spectrum of percent body fat. To assess potential functional consequences of sympathetic nerve discharge, we simultaneously measured calf vascular resistance and energy expenditure. The resting rate of sympathetic nerve discharge to skeletal muscle was directly correlated with body mass index (r = .67, P < .0001) and percent body fat (r = .64, P < .0001). In addition to body fat, muscle sympathetic nerve activity was correlated with age (r = .40, P < .02), plasma insulin concentration (r = .34, P < .04), and plasma lactate concentration (r = .35, P < .04). Together, these four covariates accounted for 58% of the variance of muscle sympathetic nerve activity (P < .0001). The rate of sympathetic nerve discharge to calf blood vessels was directly correlated with calf vascular resistance (r = .40, P < .02) but did not predict energy expenditure (r = .22, P = .19). CONCLUSIONS In healthy humans, body fat is a major determinant of the resting rate of muscle sympathetic nerve discharge. Overweight-associated sympathetic activation could represent one potential mechanism contributing to the increased incidence of cardiovascular complications in overweight subjects.

High-Altitude Pulmonary Edema Is Initially Caused by an Increase in Capillary Pressure

BackgroundHigh-altitude pulmonary edema (HAPE) is characterized by severe pulmonary hypertension and bronchoalveolar lavage fluid changes indicative of inflammation. It is not known, however, whether the primary event is an increase in pressure or an increase in permeability of the pulmonary capillaries. Methods and ResultsWe studied pulmonary hemodynamics, including capillary pressure determined by the occlusion method, and capillary permeability evaluated by the pulmonary transvascular escape of 67Ga-labeled transferrin, in 16 subjects with a previous HAPE and in 14 control subjects, first at low altitude (490 m) and then within the first 48 hours of ascent to a high-altitude laboratory (4559 m). The HAPE-susceptible subjects, compared with the control subjects, had an enhanced pulmonary vasoreactivity to inspiratory hypoxia at low altitude and higher mean pulmonary artery pressures (37±2 versus 26±1 mm Hg, P <0.001) and pulmonary capillary pressures (19±1 versus 13±1 mm Hg, P <0.001) at high altitude. Nine of the susceptible subjects developed HAPE. All of them had a pulmonary capillary pressure >19 mm Hg (range 20 to 26 mm Hg), whereas all 7 susceptible subjects without HAPE had a pulmonary capillary pressure <19 mm Hg (range 14 to 18 mm Hg). The pulmonary transcapillary escape of radiolabeled transferrin increased slightly from low to high altitude in the HAPE-susceptible subjects but remained within the limits of normal and did not differ significantly from the control subjects. ConclusionsHAPE is initially caused by an increase in pulmonary capillary pressure.

Insulin as a Vascular and Sympathoexcitatory Hormone Implications for Blood Pressure Regulation, Insulin Sensitivity, and Cardiovascular Morbidity

The past several years have witnessed a major surge of interest in the cardiovascular actions of insulin. This interest has stemmed on the one hand from epidemiological studies that demonstrated an association between obesity, insulin resistance, and hypertension, leading to the so-called insulin hypothesis of hypertension. On the other hand, this interest has been stimulated by experimental evidence suggesting that the vascular actions of insulin may play a role in its main action, namely the promotion of glucose uptake in skeletal muscle tissue. Two tenets have emerged about how insulin may exert its cardiovascular actions. First, it is now firmly established that acute insulin administration stimulates sympathetic nerve activity in both animals and humans. Second, there is increasing evidence that insulin stimulates muscle blood flow, an effect that appears to be mediated at least in part by an endothelium-dependent mechanism. This review summarizes the current understanding and gaps in knowledge on cardiovascular actions of insulin in humans and pathophysiological consequences of derangements of such actions.

Differential effects of hyperinsulinemia and carbohydrate metabolism on sympathetic nerve activity and muscle blood flow in humans.

Euglycemic hyperinsulinemia evokes both sympathetic activation and vasodilation in skeletal muscle, but the mechanism remains unknown. To determine whether insulin per se or insulin-induced stimulation of carbohydrate metabolism is the main excitatory stimulus, we performed, in six healthy lean subjects, simultaneous microneurographic recordings of muscle sympathetic nerve activity, plethysmographic measurements of calf blood flow, and calorimetric determinations of carbohydrate oxidation rate. Measurements were made during 2 h of: (a) insulin/glucose infusion (hyperinsulinemic [6 pmol/kg per min] euglycemic clamp), (b) exogenous glucose infusion at a rate matched to that attained during protocol a, and (c) exogenous fructose infusion at the same rate as for glucose infusion in protocol b. For a comparable rise in carbohydrate oxidation, insulin/glucose infusion that resulted in twofold greater increases in plasma insulin concentrations than did glucose infusion alone, evoked twofold greater increases in both muscle sympathetic nerve activity and calf blood flow. Fructose infusion, which increased carbohydrate oxidation comparably, but had only a minor effect on insulinemia, did not stimulate either muscle sympathetic nerve activity or calf blood flow. These observations suggest that in humans hyperinsulinemia per se, rather than insulin-induced stimulation of carbohydrate metabolism, is the main mechanism that triggers both sympathetic activation and vasodilation in skeletal muscle.

Inhaled Nitric Oxide for High-Altitude Pulmonary Edema

BACKGROUND Pulmonary hypertension is a hallmark of high-altitude pulmonary edema and may contribute to its pathogenesis. When administered by inhalation, nitric oxide, an endothelium-derived relaxing factor, attenuates the pulmonary vasoconstriction produced by short-term hypoxia. METHODS We studied the effects of inhaled nitric oxide on pulmonary-artery pressure and arterial oxygenation in 18 mountaineers prone to high-altitude pulmonary edema and 18 mountaineers resistant to this condition in a high altitude laboratory (altitude, 4559 m). We also obtained lung-perfusion scans before and during nitric oxide inhalation to gain further insight into the mechanism of action of nitric oxide. RESULTS In the high-altitude laboratory, subjects prone to high-altitude pulmonary edema had more pronounced pulmonary hypertension and hypoxemia than subjects resistant to high-altitude pulmonary edema. Arterial oxygen saturation was inversely related to the severity of pulmonary hypertension (r=-0.50, P=0.002). In subjects prone to high-altitude pulmonary edema, the inhalation of nitric oxide (40 ppm for 15 minutes) produced a decrease in mean (+/-SD) systolic pulmonary-artery pressure that was three times larger than the decrease in subjects resistant to such edema (25.9+/-8.9 vs. 8.7+/-4.8 mm Hg, P<0.001). Inhaled nitric oxide improved arterial oxygenation in the 10 subjects who had radiographic evidence of pulmonary edema (arterial oxygen saturation increased from 67+/-10 to 73+/-12 percent, P=0.047), whereas it worsened oxygenation in subjects resistant to high-altitude pulmonary edema. The nitric oxide-induced improvement in arterial oxygenation in subjects with high-altitude pulmonary edema was accompanied by a shift in blood flow in the lung away from edematous segments and toward nonedematous segments. CONCLUSIONS The inhalation of nitric oxide improves arterial oxygenation in high-altitude pulmonary edema, and this beneficial effect may be related to its favorable action on the distribution of blood flow in the lungs. A defect in nitric nitric oxide synthesis may contribute to high-altitude pulmonary edema.

Impaired insulin-induced sympathetic neural activation and vasodilation in skeletal muscle in obese humans.

The sympathetic nervous system is an important regulatory mechanism of both metabolic and cardiovascular function, and altered sympathetic activity may play a role in the etiology and/or complications of obesity. In lean subjects, insulin evokes sympathetic activation and vasodilation in skeletal muscle. In obese subjects such vasodilation is impaired and, in turn, may contribute to insulin resistance. To examine the relationship between sympathetic and vasodilatory responses in skeletal muscle to hyperinsulinemia, we simultaneously measured muscle sympathetic nerve activity (MSNA) and calf blood flow at basal and during a 2-h hyperinsulinemic (6 pmol/kg per min) euglycemic clamp in eight lean and eight obese subjects. The major findings of this study are twofold: obese subjects had a 2.2 times higher fasting rate of MSNA, and euglycemic hyperinsulinemia, which more than doubled MSNA and increased calf blood flow by roughly 30% in lean subjects, had only a minor vasodilatory and sympathoexcitatory effect in obese subjects. In contrast, two non-insulin-sympathetic stimuli evoked comparably large increases in MSNA in lean and obese subjects. We conclude that insulin resistance in obese subjects is associated with increased fasting MSNA and a specific impairment of sympathetic neural responsiveness to physiological hyperinsulinemia in skeletal muscle tissue.

Augmented Sympathetic Activation During Short-Term Hypoxia and High-Altitude Exposure in Subjects Susceptible to High-Altitude Pulmonary Edema

BACKGROUND Pulmonary hypertension is a hallmark of high-altitude pulmonary edema and may contribute to its pathogenesis. Cardiovascular adjustments to hypoxia are mediated, at least in part, by the sympathetic nervous system, and sympathetic activation promotes pulmonary vasoconstriction and alveolar fluid flooding in experimental animals. METHODS AND RESULTS We measured sympathetic nerve activity (using intraneural microelectrodes) in 8 mountaineers susceptible to high-altitude pulmonary edema and 7 mountaineers resistant to this condition during short-term hypoxic breathing at low altitude and at rest at a high-altitude laboratory (4559 m). We also measured systolic pulmonary artery pressure to examine the relationship between sympathetic activation and pulmonary vasoconstriction. In subjects prone to pulmonary edema, short-term hypoxic breathing at low altitude evoked comparable hypoxemia but a 2- to 3-times-larger increase in the rate of the sympathetic nerve discharge than in subjects resistant to edema (P<0.001). At high altitude, in subjects prone to edema, the increase in the mean+/-SE sympathetic firing rate was >2 times larger than in those resistant to edema (36+/-7 versus 15+/-4 bursts per minute, P<0.001) and preceded the development of lung edema. We observed a direct relationship between sympathetic nerve activity and pulmonary artery pressure measured at low and high altitude in the 2 groups (r=0.83, P<0.0001). CONCLUSIONS With the use of direct measurements of postganglionic sympathetic nerve discharge, these data provide the first evidence for an exaggerated sympathetic activation in subjects prone to high-altitude pulmonary edema both during short-term hypoxic breathing at low altitude and during actual high-altitude exposure. Sympathetic overactivation may contribute to high-altitude pulmonary edema.

Pulmonary and Systemic Vascular Dysfunction in Young Offspring of Mothers With Preeclampsia

Background— Adverse events in utero may predispose to cardiovascular disease in adulthood. The underlying mechanisms are unknown. During preeclampsia, vasculotoxic factors are released into the maternal circulation by the diseased placenta. We speculated that these factors pass the placental barrier and leave a defect in the circulation of the offspring that predisposes to a pathological response later in life. The hypoxia associated with high-altitude exposure is expected to facilitate the detection of this problem. Methods and Results— We assessed pulmonary artery pressure (by Doppler echocardiography) and flow-mediated dilation of the brachial artery in 48 offspring of women with preeclampsia and 90 offspring of women with normal pregnancies born and permanently living at the same high-altitude location (3600 m). Pulmonary artery pressure was roughly 30% higher (mean±SD, 32.1±5.6 versus 25.3±4.7 mm Hg; P<0.001) and flow-mediated dilation was 30% smaller (6.3±1.2% versus 8.3±1.4%; P<0.0001) in offspring of mothers with preeclampsia than in control subjects. A strong inverse relationship existed between flow-mediated dilation and pulmonary artery pressure (r=−0.61, P<0.001). The vascular dysfunction was related to preeclampsia itself because siblings of offspring of mothers with preeclampsia who were born after a normal pregnancy had normal vascular function. Augmented oxidative stress may represent an underlying mechanism because thiobarbituric acid–reactive substances plasma concentration was increased in offspring of mothers with preeclampsia. Conclusions— Preeclampsia leaves a persistent defect in the systemic and the pulmonary circulation of the offspring. This defect predisposes to exaggerated hypoxic pulmonary hypertension already during childhood and may contribute to premature cardiovascular disease in the systemic circulation later in life.