Left ventricular norepinephrine and epinephrine kinetics at birth in lambs

Little is known about the changes in the left ventricular (LV) kinetics of the catecholamines norepinephrine and epinephrine occurring at birth and their relationship to perinatal alterations in LV function and whole-body catecholamine kinetics. To address this issue, whole-body and LV catecholamine kinetics (radiotracer dilution methodology) and fetal LV output and myocardial blood flow (radioactive microspheres) were measured in chronically instrumented near-term fetuses and in the same animals 1 and 4 hours after birth. Between fetal and 1-hour lambs, LV external work increased 115% (P<.005); carotid arterial plasma norepinephrine concentration, 148% (P<.01); carotid arterial plasma epinephrine concentration, 546% (P<.005); LV norepinephrine spillover, a measure of LV sympathetic activity, 4.1-fold (P<.005); LV epinephrine spillover, 3-fold (P<.05); total-body spillover of norepinephrine, 52% (P<.025); and total-body spillover of epinephrine, 460% (P<.005). Arterial catecholamine concentrations and total-body catecholamine spillovers were unchanged between 1- and 4-hour lambs, but LV external work fell (P<.05) to a level still 77% greater than in fetal lambs (P<.005); LV norepinephrine spillover returned to near-fetal levels, and LV epinephrine spillover became undetectable. These results suggest that (1) a transient increase in LV sympathetic activity occurs at birth and may contribute to the immediate postnatal augmentation of LV performance, (2) organ differences in the pattern of sympathetic activation occur at birth, and (3) birth-related increases in LV sympathetic activity are accompanied by release of epinephrine from the heart.

Pulmonary clearance and release of norepinephrine and epinephrine in newborn lambs

To examine the pulmonary kinetics of the catecholamines norepinephrine and epinephrine immediately after birth, eight fetal lambs were instrumented with vascular catheters under general anesthesia at 133-134 days gestation (term = 147 days) and were delivered by cesarean section 1 wk later. Pulmonary norepinephrine and epinephrine kinetics were then studied 1 and 4 h after birth using radiotracer dilution methodology. The pulmonary fractional extraction of norepinephrine was similar in 1-h (0.111 +/- 0.021) and 4-h (0.117 +/- 0.023) lambs and constituted 24 +/- 5 and 32 +/- 9% of total body norepinephrine clearance, respectively. Pulmonary removal of epinephrine was less pronounced with a fractional extraction of 0.035 +/- 0.017 in 1-h and 0.036 +/- 0.013 in 4-h lambs, which corresponded to 8 +/- 4 and 9 +/- 3% of total body epinephrine clearance, respectively. Pulmonary spillover of norepinephrine into the circulation was similar in 1-h (79 +/- 26 ng.min-1.kg-1) and 4-h (82 +/- 18 ng.min-1.kg-1) lambs, and this comprised 27 +/- 8 and 42 +/- 8% of total body norepinephrine spillover, respectively. Pulmonary epinephrine spillover was not detectable at 1 h, but it occurred in all 4-h lambs, averaging 4.7 +/- 0.8 ng.min-1.kg-1 or 20 +/- 6% of epinephrine total body spillover. These findings indicate that the lungs of newborn lambs 1) are a major site for removal of norepinephrine and epinephrine from the circulation; 2) release a substantial quantity of norepinephrine into the circulation, consistent with the presence of tonic pulmonary sympathetic nerve activity; and 3) constitute a significant extra-adrenal source of plasma epinephrine.

Cerebral noradrenaline spillover and its relation to muscle sympathetic nervous activity in healthy human subjects

Studies using internal jugular vein blood sampling in human subjects have demonstrated the release of noradrenaline from the brain and have provided a link between central nervous system noradrenergic neuronal activity and renal, cardiac and total body sympathetic activity. The aim of this study was to further categorise the dependence of regional sympathetic nervous function on central nervous system noradrenergic neuronal processes by combining measures of internal jugular venous noradrenaline spillover, as an indicator of brain noradrenaline release, and cerebral blood flow scans with measures of the overall integrated neuronal firing rate for the body as a whole, the spillover of noradrenaline into the coronary sinus and with measurements of resting muscle sympathetic nerve activity. Positive veno-arterial plasma noradrenaline gradients were found across the brain, with the plasma concentration being 17 +/- 3% (p < 0.01) greater in the internal jugular vein. Linear regression analysis revealed a significant relationship between the degree of muscle sympathetic nerve activity and the spillover of noradrenaline from subcortical brain regions (y = 0.1 x + 16.0; r = 0.81, p < 0.02). The rate of spillover of noradrenaline for the body as a whole also bore a significant association with the rate of subcortical noradrenaline spillover (y = 0.01x + 2.33; r = 0.71, p < 0.05). Cortical noradrenaline spillover was not related to any of the sympathetic nervous system parameters measured in this study. The demonstration of a direct relationship between the rate of peroneal nerve firing and the spillover of noradrenaline from subcortical brain regions provides further support for the concept of central nervous system noradrenergic cell groups behaving in a sympathoexcitatory role.

Region-specific neuropeptide Y overflows at rest and during sympathetic activation in humans

Neuropeptide Y coexists with norepinephrine in sympathetic nerves and is coreleased into the circulation on sympathetic activation. Little is known about the regional release of neuropeptide Y in humans under normal conditions or in pathophysiological situations of sympathetic activation or denervation. We measured plasma neuropeptide Y-like immunoreactivity and norepinephrine concentrations in samples taken from the brachial artery; coronary sinus; and internal jugular, antecubital, or hepatic veins in volunteers aged 20 to 64 years. Regional neuropeptide Y overflow at rest was calculated from venoarterial plasma concentration differences and plasma flow, and norepinephrine spillover was determined by [3H]norepinephrine infusion techniques. Cardiac release of neuropeptide Y and norepinephrine was examined in response to various stressors as well as in clinical models of sympathetic activation, cardiac failure, and denervation after cardiac transplantation. In healthy volunteers, cardiac, forearm, and jugular venous sample neuropeptide Y concentrations were similar to arterial levels. Hepatic vein plasma neuropeptide Y was greater than arterial both at rest (119 +/- 5% of arterial, n = 7) and after a meal (132 +/- 12%, n = 7), with neuropeptide Y overflows of 6 +/- 2 and 11 +/- 2 pmol/min, respectively. In contrast, hepatomesenteric norepinephrine spillover was not significantly increased by feeding. Although coronary sinus plasma norepinephrine concentrations increased significantly with the cardiac sympathetic activation accompanying mental arithmetic, coffee drinking, isotonic exercise, and bicycle exercise, only the latter powerful sympathetic stimulus increased neuropeptide Y overflow. Cardiac failure was associated with increased resting release of both norepinephrine and neuropeptide Y from the heart, whereas postcardiac transplant norepinephrine spillover from the heart was reduced. The net overflow of neuropeptide Y to plasma observed at rest across the hepatic circulation, but not the cardiac, forearm, or cerebral circulations, indicates that the gut, the liver, or both make a major contribution to systemic plasma neuropeptide Y levels in humans. Sympathetic activation by exercise produced a modest increase in cardiac neuropeptide Y overflow but to only approximately 25% of the resting input from the gut and without a change in arterial neuropeptide Y concentration. Plasma neuropeptide Y measurements are less sensitive than those of plasma norepinephrine concentrations as an index for quantifying sympathetic neural responses regulating the systemic circulation.

Oxygen consumption in the heart, hepatomesenteric bed, and brain in young and elderly human subjects, and accompanying sympathetic nervous activity

Although the reduction in whole-body energy expenditure with aging has been well documented, there is little information about the changes that individual organs undergo. We therefore measured oxygen consumption in the heart, hepatomesenteric bed, and brain in elderly subjects and young controls, using central venous catheter techniques and the application of Fick's principle. We also measured whole-body, cardiac, and hepatomesenteric sympathetic nervous activity using isotope dilution methodology. Cardiac, hepatomesenteric, and cerebral oxygen consumption was similar in both groups. Whole-body and hepatomesenteric sympathetic nervous activity was also similar in the study groups, whereas cardiac norepinephrine (NE) spillover was significantly higher in the elderly. In contrast to the young, cardiac sympathetic nervous activity as assessed from NE spillover was not related to either cardiac oxygen consumption or cardiac work in the elderly. The data suggest that although oxygen consumption in the heart, hepatomesenteric bed, and brain are not different between young and elderly individuals, the relationship between sympathetic nervous activity and oxygen consumption in individual organs may alter with aging.

Cerebral metabolism and its relationship with sympathetic nervous activity in essential hypertension: evaluation of the Dickinson hypothesis

OBJECTIVE

To examine Dickinson's hypothesis in mild essential hypertension, in which neurogenic mechanisms are believed to be particularly relevant, by combining measures of cerebral oxygen consumption with the concurrent assessment of sympathetic nervous activity.

DESIGN AND METHODS

Twenty-five untreated essential hypertensive subjects and 28 healthy age-matched volunteers underwent direct blood sampling using percutaneously inserted catheters advanced into the internal jugular vein, with cerebral blood flow scans to differentiate between cortical and subcortical venous drainage of the brain. Venoarterial blood gas measurements and internal jugular vein blood flows were used to calculate cerebral respiratory quotients and cerebral oxygen utilization. The total body rate of noradrenaline spillover into plasma was measured to assess relationships between cerebral oxidative metabolism and sympathetic nervous activity.

RESULTS

Compared with controls, the hypertensive subjects exhibited reductions in internal jugular vein blood flow (482 +/- 29 versus 410 +/- 15 ml/min), cerebral oxygen consumption (27 +/- 2 versus 23 +/- 1 ml/min) and cerebral oxygen supply (93 +/- 6 versus 78 +/- 3 ml/min). The cerebral respiratory quotients were identical (1.00 +/- 0.04 in normotensives and 0.98 +/- 0.03 in hypertensives). Technetium blood flow scans revealed that the reductions in internal jugular blood flow and cerebral oxygen consumption in the hypertensive patients were confined to cortical brain regions. Cortical blood flow was quantitatively linked to the matching respiratory quotient and oxygen consumption, neither of which bore any relation to the level of sympathetic nervous activity. The spillover of noradrenaline into the plasma for the body as a whole did not differ between the two groups.

CONCLUSIONS

In accord with Dickinson's hypothesis, we have established a reduction in internal jugular vein blood flow and cerebral oxygen utilization in hypertension. These reductions were confined to cortical brain regions. However, cerebral respiratory quotients in our hypertensive study group were no different from those in our controls, suggesting that glucose remained as the major cerebral metabolic substrate in hypertension. We were not able to establish a link between cerebral metabolism and blood pressure or sympathetic nervous activity in mildly hypertensive patients.

Increased spillover and reduced clearance both contribute to rise in plasma catecholamines after birth in lambs

We studied the relationship between changes in norepinephrine (NE) and epinephrine (Epi) levels, total body spillover, and total body clearance at birth. Near-term fetal lambs were chronically instrumented under general anesthesia with arterial, venous, and left atrial catheters. One week later, NE and Epi kinetics (isotope dilution methodology) and systemic blood flows (radioactive microspheres) were measured in fetuses and then in the same animals 1 and 4 h after cesarean section delivery. Comparing fetal and 1-h lambs 1) systemic output fell by 33% (P < 0.005); 2) systemic plasma NE increased by 144% (P < 0.005), and plasma Epi increased sevenfold (P < 0.005); 3) total body NE spillover rose by 63% (P < 0.01) and Epi spillover by fivefold (P < 0.005); and 4) total body NE clearance decreased by 34% (P < 0.005) and Epi clearance by 37% (P < 0.005). Systemic blood flow and kinetic data were similar in 1- and 4-h lambs and were therefore pooled to define the interrelationship among perinatal changes in NE and Epi plasma levels, spillover, and clearance. Between fetal and newborn lambs, plasma NE rose by 1,375 +/- 207 pg/ml, of which 604 +/- 119 pg/ml (approximately 44%) resulted from increased NE total body spillover and 771 +/- 160 pg/ml from reduced NE total body clearance. In the same interval, plasma Epi rose by 292 +/- 30 pg/ml, of which 123 +/- 18 pg/ml (approximately 42%) was due to Epi total body spillover and 169 +/- 19 pg/ml to reduced Epi total body clearance. These findings indicate that 1) sympathoadrenal activity increases with birth, and 2) increased total body spillover and reduced total body clearance contribute a similar portion of the plasma NE and Epi surge at birth.

Fallibility of plasma noradrenaline measurements in studying postprandial sympathetic nervous responses

The use of the plasma noradrenaline (NA) concentration as an index of sympathetic nervous system (SNS) activity in the postprandial state is associated with several problems: (i) It does not take into account the contribution of alterations in clearance to the plasma NA level, (ii) when antecubital venous blood is sampled, it reflects regional forearm rather than whole body SNS activity and (iii) no insight is gained into the regional pattern of SNS activation. These potential confounders were addressed in this study performed in 17 healthy young men. The validity of plasma NA measurements in assessing postprandial changes in sympathetic nervous activation was evaluated in relation to that of whole body and regional plasma NA spillover, derived using isotope dilution methodology. Plasma clearance of NA is significantly altered following a meal, with a transient elevation in the early postprandial phase which may lead to an underestimation of SNS activation when assessed from arterial plasma NA levels. Forearm plasma NA spillover increases postprandially, such that despite significant postprandial elevations in arterial plasma NA, the plasma arterial contribution to antecubital venous plasma NA levels is maintained at less than 40%, the rest being derived locally from the forearm. This makes venous plasma samples unsuitable for the assessment of SNS activation in organs and vascular sites distant from the sampling site. The kidneys and skeletal muscle are the major regional sites of postprandial sympathetic nervous activation, while cardiac plasma NE spillover is unaltered postprandially. This regional pattern of SNS activation postprandially must be taken into account when relating increments in plasma NA levels to specific physiological events.

Regional origins of 3-methoxy-4-hydroxyphenylglycol in plasma: effects of chronic sympathetic nervous activation and denervation, and acute reflex sympathetic stimulation

The plasma level and urinary excretion of 3-methoxy-4-hydroxyphenylglycol (MHPG), the principal metabolite of noradrenaline in the brain, are often used as indicators of central nervous system noradrenergic activity. Using percutaneously placed catheters, we studied the regional inputs into the plasma MHPG pool in 62 healthy volunteers. Veno-arterial plasma concentration differences and regional organ blood flows were used to quantify the relative amounts of MHPG contributed by various sites into plasma. Positive veno-arterial concentration gradients were found across the forearm, cardiac and jugular vessels in the healthy subjects. By far the majority of MHPG in plasma was derived from skeletal muscle, 5.3 +/- 1.8 nmol/min, with only minimal contribution (0.9 +/- 0.2 nmol/min) from the brain. Thus, to obtain an accurate indication of central nervous system noradrenergic activity the confounding influences of regional MHPG production must be excluded. 34 patients with chronic congestive heart failure, 6 patients with pure autonomic failure and 9 recent heart transplant recipients were used to investigate the possible effects of chronic sympathetic nervous system overactivity and sympathetic underactivity and denervation on peripheral MHPG production and plasma MHPG concentration. To examine the utility of plasma MHPG determinations as an indicator of acute alterations in sympathetic nervous activity we examined the influence of a variety of laboratory stressors on the arterial level and cardiac production of MHPG. The resting arterial plasma MHPG concentration mirrored sympathetic function in the patients with cardiac failure (sympathetic activation) and pure autonomic failure (sympathetic denervation), with mean MHPG plasma concentrations being 180 and 40% of those in healthy subjects. Cardiac MHPG production was increased in heart failure patients, and near zero with the cardiac sympathetic denervation accompanying transplantation and pure autonomic failure. In contrast, acute reflex stimulation of sympathetic nervous activity was not associated with parallel changes in the arterial level or cardiac production of MHPG. Measurements of peripheral plasma MHPG levels provide an index of prevailing sympathetic nervous function in clinical models of sympathetic overactivity and denervation, but are insensitive to acute sympathetic nervous system responses.

Increased central nervous system monoamine neurotransmitter turnover and its association with sympathetic nervous activity in treated heart failure patients

BACKGROUND

Congestive heart failure is a debilitating disease characterized by impaired cardiac function with accompanying activation of a variety of neural and hormonal counter-regulatory systems. Abnormal activity of the sympathetic nervous system and renin-angiotensin-aldosterone axis and a predisposition to the generation of fatal ventricular arrhythmias are often associated with the development of the disease. Although the underlying cause of sudden death in these patients remains to be unequivocally elucidated, abnormally increased cardiac sympathetic nervous activity may be involved.

METHODS AND RESULTS

Twenty-two patients with severe congestive heart failure (New York Heart Association functional class III or IV with left ventricular ejection fraction of 18 +/- 1%) and 29 healthy male volunteers participated in this study. By combining direct sampling of internal jugular venous blood via a percutaneously placed catheter with a norepinephrine and epinephrine isotope dilution method for examining neuronal transmitter release, we were able to quantify the release of central nervous system monoamine and indoleamine neurotransmitters and investigate their association with the increased efferent sympathetic outflow that is variably present in treated patients with this condition. Mean cardiac norepinephrine spillover was 145% higher in treated heart failure patients than in healthy subjects (P < .05), with norepinephrine release from the heart in 6 of 22 patients being more than the highest control value. Raised internal jugular venous spillover of epinephrine (26 +/- 12 versus 2 +/- 4 pmol/min, P < .05) and of norepinephrine and its metabolites (2740 +/- 480 versus 875 +/- 338 pmol/min, P < .05), indicative of increased central nervous system turnover of both catecholamines, occurred in cardiac failure and was quantitatively linked to the degree of activation of the cardiac sympathetic nervous outflow, as was the jugular overflow of the principal serotonin metabolite, 5-hydroxyindoleacetic acid.

CONCLUSIONS

An association between the degree of activation of central monoaminergic neurons and the level of sympathetic nervous tone in the heart was identified in treated patients with heart failure. Epinephrine neurons in the brain may contribute to the sympathoexcitation that is seen in this condition, with the activation of sympathoexcitatory noradrenergic neurons, most likely those of the forebrain, playing an accessory role.

Regional sympathetic nervous activation after a large meal in humans

1. To investigate the link between post-prandial thermogenesis and sympathetic nervous activation we have studied the effects of a single large meal on regional sympathetic nervous activity in healthy, lean subjects. 2. In nine male subjects, noradrenaline spillover was measured from the heart, kidney and liver using isotope dilution, both while fasting and after consumption of a high-energy liquid meal of composition 53% carbohydrate, 32% fat and 15% protein (energy value 2.64-3.51 MJ). Regional oxygen consumption, whole-body oxygen consumption and, in a subset of subjects, muscle sympathetic nerve firing (microneurography) were also measured. 3. Both whole-body oxygen consumption (P < 0.03) and total body spillover of noradrenaline (P < 0.01) rose after the meal, with peak increases of 24% and 56% respectively. Spillover of noradrenaline from the heart was unchanged, that from the hepatosplanchnic circulation increased marginally (0.377 nmol/min to 0.480 nmol/min, P = 0.09), while renal noradrenaline spillover more than doubled (0.440 nmol/min to 0.937 nmol/min, P < 0.05). Skeletal muscle sympathetic nerve activity (peroneal nerve) increased from 7.7 bursts/min at rest to peak at 17.9 bursts/min 60 min after the meal in the three subjects in whom stable recordings were obtained. 4. The meal increased oxygen consumption in the kidneys and liver significantly, from 11.5 +/- 1.6 ml/min to 14.5 +/- 1.1 ml/min and from 46 +/- 7 ml/min to 57 +/- 6 ml/min respectively (P < 0.05), but not in the heart. 5. Consumption of a large meal produces a substantial and relatively selective increase in sympathetic outflow to the kidneys and skeletal muscle. While resting regional oxygen consumptions and noradrenaline spillovers were related, the changes that occurred in each were unrelated, so that no direct relationship could be demonstrated between postprandial thermogenesis and sympathetic activity.

Regional 5-hydroxyindoleacetic acid production in humans

Veno-arterial plasma concentration differences and regional organ plasma flows were used to quantify the relative amounts of 5-hydroxyindoleacetic acid (5-HIAA) contributed by various sites into the peripheral circulation. Positive venoarterial concentration gradients were found in the hepatosplanchnic, forearm, cardiac and jugular vessels in the healthy subjects. The renal circulation was determined to be the principal site of 5-HIAA clearance, extracting 18 +/- 2 nmol/min. The gut was the greatest contributor to the total 5-HIAA plasma pool with the relative contributions of the various organs being as follows: hepatosplanchnic organs 58%, skeletal muscle 26%, brain 6% and the heart 3%. The source of 5-HIAA stemming from these regional beds remains unknown, it may derive from serotonin taken up by and deaminated in ubiquitous endothelial cells, enterochromaffin cells of the gut, peripheral serotonergic nerves, serotonin turnover in platelets or perhaps the metabolism of serotonin taken up by sympathetic nerves. To test the latter hypothesis we examined 23 patients with chronic congestive heart failure and 9 patients with pure autonomic failure to investigate the possible effects of sympathetic nervous system overactivity and underactivity on peripheral 5-HIAA production and plasma 5-HIAA concentration. The resting arterial plasma 5-HIAA concentration in the heart failure patients was increased three-fold. This elevated plasma 5-HIAA concentration was attributable to an increased rate of whole body 5-HIAA production. The arterial 5-HIAA plasma concentration in the autonomic failure patients was paradoxically elevated, being 70% greater than that of the healthy subjects. The increased 5-HIAA plasma concentration in these patients was accounted for by a reduction in 5-HIAA plasma clearance. In all subjects studied there was a weak relationship only between total body norepinephrine spillover to plasma and the arterial 5-HIAA plasma concentration. We found that in healthy subjects the overflow of 5-HIAA into the hepatic vein was significantly related to the underlying degree of sympathetic activity. It can be concluded that 5-HIAA is produced at a number of sites throughout the body with the arterial plasma concentration being dependent on both the level of production and plasma clearance. By far the majority of 5-HIAA in plasma is derived from the gut with only minimal contribution from the brain.

Central nervous system noradrenergic and dopaminergic turnover in response to acute neuroleptic challenge

The objective of this study was to obtain direct neurochemical measures of the central nervous system's response to a typical neuroleptic, haloperidol, in human subjects. Nine healthy volunteers participated in this study. Central nervous system neuronal activity was assessed by measuring the plasma concentration and overflow from the brain of dopamine, norepinephrine, and their lipophilic and acidic metabolites after acute intravenous administration of haloperidol. By combining bilateral internal jugular vein blood sampling with cerebral blood flow scans we were able to differentiate between cortical and subcortical responses to haloperidol. The central nervous system response to haloperidol administration displayed a degree of regional specificity. Dopamine release, estimated from the overflow of homovanillic and dihydroxyphenylacetic acids, was reduced in cortical but not subcortical brain regions. Norepinephrine turnover was increased in cortical and subcortical brain regions. The overflow of homovanillic acid from the brain into the internal jugular veins was not related quantitatively to the arterial plasma concentrations of the catecholamines examined, homovanillic and dihydroxyphenylacetic acids or prolactin. Measurements of catecholamines and their metabolites in arterial plasma gave little indication as to monoaminergic neuronal activity in the brain.

Effects of aging on the responsiveness of the human cardiac sympathetic nerves to stressors

BACKGROUND

Aging increases human sympathetic nervous activity at rest. Beause of the probable importance of neural stress responses in the heart as triggers for clinical end points of coronary artery disease, it is pertinent to investigate whether sympathetic nervous responses to stresses are increased by aging.

METHODS AND RESULTS

We applied kinetic methods for measuring the fluxes to plasma of neurochemicals relevant to sympathetic neurotransmission in younger (aged 20 to 30 years) and older (aged 60 to 75 years) healthy men during mental stress (difficult mental arithmetic), isometric exercise (sustained handgrip), and dynamic exercise (supine cycling). The increase in total norepinephrine spillover to plasma with mental stress was unaffected by age. In contrast, the increase in cardiac norepinephrine spillover was two to three times higher in the older subjects (P < .05). The probable mechanism of this higher cardiac norepinephrine spillover was reduced neuronal reuptake of the transmitter, because age had no influence on the overflow of the norepinephrine precursor, dihydroxyphenylalanine, or intraneuronal metabolite, dihydroxyphenylglycol (levels of these two substances reflect rates of cardiac norepinephrine synthesis and intraneuronal metabolism), and the transcardiac extraction of plasma radiolabeled norepinephrine was lower in the older subjects (P < .05). An almost identical pattern of neurochemical response was seen with isometric exercise. During cycling, total norepinephrine spillover was 16% lower in the older men, but cardiac norepinephrine spillover was 53% higher.

CONCLUSIONS

Reduced norepinephrine reuptake increases the overflow of the neurotransmitter to plasma from the aging heart during stimulation of the cardiac sympathetic outflow. Failure of transmitter inactivation at postjunctional receptors with aging would amplify the neural signal, and in the presence of myocardial disease could trigger adverse stress-induced cardiovascular events, particularly when accompanied by an age-dependent reduction in vagal tone. Reduction of postsynaptic adrenergic responsiveness with aging, however, might protect against this, as indicated by our finding that in no case was the heart rate increase during stress greater in older men, despite their having larger increases in cardiac norepinephrine spillover.

Aging effects on human sympathetic neuronal function

To study the effect of aging on human sympathetic nervous function, we applied kinetic methods for measuring the fluxes to plasma of neurochemicals relevant to sympathetic neurotransmission in younger (aged 20-30 yr) and older (aged 60-75 yr) healthy men. Mean plasma norepinephrine concentration was 66% higher in older men, attributable to 22% lower norepinephrine plasma clearance (P < 0.05) and 29% higher norepinephrine spillover to plasma (difference not statistically significant). Regional venous sampling disclosed that sympathetic outflow to all organs was not activated by aging. Renal norepinephrine spillover was normal in older men. Although spillover of norepinephrine from the heart was increased in older men, 21.1 +/- 11.4 ng/min compared with 11.4 +/- 8.6 ng/min (P < 0.05), diminished norepinephrine reuptake rather than increased cardiac sympathetic nerve firing was the most likely cause, although somewhat reduced intracardiac methylation of norepinephrine with aging also possibly contributed. The extraction of tritiated norepinephrine from plasma during transit through the heart was reduced, suggesting neuronal norepinephrine reuptake was lowered and overflow of the norepinephrine precursor dihydroxyphenylalanine and metabolites dihydroxyphenylglycol and 3-methoxy-4-hydroxy phenylglycol was normal, indicating that norepinephrine synthesis and release were not increased.

Monoaminergic neuronal activity in subcortical brain regions in essential hypertension

In this study we aimed to elucidate the role of central noradrenergic, dopaminergic, adrenergic and serotonergic neuronal systems in the development of essential hypertension. Fifteen untreated essential hypertensive subjects (aged 44 +/- 3 years) and 32 healthy volunteers (aged 38 +/- 3 years) participated in this study. By combining direct blood sampling techniques with cerebral blood flow scans we were able to differentiate between cortical and subcortical venous drainage of the brain. Veno-arterial MHPG, HVA and 5-HIAA plasma concentration gradients combined with internal jugular vein plasma flows were used, according to the Fick Principle, to derive metabolite spillovers which in turn were used as indicators of central noradrenergic, dopaminergic and serotonergic neuronal activity, respectively. These amine systems, in both the brainstem and forebrain, have been implicated in the regulation of sympathetic outflow and blood pressure. Total body noradrenaline spillover to plasma was concurrently measured to assess the relationship between central monoamine turnover and sympathetic activity. Compared to their healthy counterparts the hypertensive subjects had an elevated release of MHPG from subcortical brain regions (1.4 +/- 0.3 v 0.5 +/- 0.2 nmol/min, p < 0.05). An inverse relationship between blood pressure and subcortical HVA overflow existed, with the HVA overflow being significantly lower in the hypertensives (0.5 +/- 0.2 v 2.1 +/- 0.5 nmol/min, p < 0.05). Subcortical 5-HUAA overflow did not differ between the two groups, and adrenaline spillover from the brain was not detected in either group. Subcortical MHPG overflow was significantly correlated with total body NA spillover to plasma (p < 0.05). These results indicate that reciprocal aberrations in subcortical noradrenaline and dopamine turnover exist in essential hypertension. Although the physiological significance of this remains to be unequivocally elucidated we postulate that elevated subcortical noradrenergic activity, presumably in the forebrain where noradrenergic neurons are pressor, may cause sympathoexcitation and play a role in the development of essential hypertension.

Evidence for increased noradrenaline release from subcortical brain regions in essential hypertension

OBJECTIVE

To test whether the activation of the sympathetic nervous system that is common in essential hypertension derives from subcortical noradrenergic neuronal excitation.

DESIGN AND METHODS

We performed a radionuclide cerebral venous sinus scan, using technetium-99m, to establish which internal jugular vein predominantly drained the cortical (the major jugular vein) and which the subcortical (minor jugular vein) brain regions. Blood samples were then collected simultaneously from catheters placed percutaneously in the brachial artery or radial artery and high in the internal jugular vein in 11 untreated hypertensive patients and 18 normotensive subjects, for determination of the plasma concentrations of noradrenaline, its precursor dihydroxyphenylalanine (DOPA) and its metabolite dihydroxyphenylglycol (DHPG) to calculate their rates of overflow into the cerebrovascular circulation.

RESULTS

In normotensive subjects blood flow determined by thermodilution was significantly higher in the major than in the minor jugular vein. The noradrenaline spillovers into the major and minor jugular veins calculated during infusions of L-[3H]-7-noradrenaline were similar in healthy subjects. The noradrenaline spillover from subcortical regions into the minor jugular vein was significantly higher in the hypertensives than in the normal subjects, as was the overflow of DHPG. In contrast, cortical noradrenaline and DHPG overflows into the major jugular vein were similar in hypertensive and normotensive subjects. Overflow of DOPA into the minor jugular vein, which derives largely from precursor turnover in dopaminergic neurons, was similar in hypertensive and normotensive subjects. Subcortical noradrenaline spillover correlated with neurochemical indices of sympathetic nervous system activity, with total body noradrenaline spillover (r = 0.56, P < 0.05) in normal and hypertensive subjects combined, and with renal noradrenaline spillover in the six hypertensive patients tested (r = 0.91, P < 0.05).

CONCLUSION

These results suggest that increased subcortical noradrenaline release is a possible cause of peripheral sympathetic activation in essential hypertension.

Increased norepinephrine spillover into the jugular veins in essential hypertension

In essential hypertension sympathetic nerve firing is commonly increased. A central nervous system origin has been presumed but not tested directly. To estimate cerebral norepinephrine release in essential hypertension, spillover of norepinephrine into the cerebrovascular circulation was measured by isotope dilution, with high internal jugular venous sampling. Norepinephrine was released into the cerebrovascular circulation in both hypertensive patients and healthy volunteers and was present after administration of the ganglion blocker trimethaphan and in patients with sympathetic nervous failure, indicating that brain neurons and not cerebrovascular sympathetic nerves were the probable source. Although differing among hypertensive patients, norepinephrine spillover on average was higher in the hypertensive patients (153 +/- 41 pmol/min) than in healthy subjects (59 +/- 12 pmol/min; p less than 0.05), and was elevated in six of 17 patients, in whom the accompanying whole body norepinephrine spillover rate was higher than in the remaining 11 patients (p less than 0.01). To test for a possible link between brain norepinephrine release and human sympathetic nervous function, the effect of the tricyclic antidepressant desipramine (0.3 mg/kg i.v.) on both brain and whole body norepinephrine spillover was measured in healthy volunteers. Desipramine lowered the cerebrovascular spillover of norepinephrine, its precursor dihydroxyphenylalanine, and its metabolite dihydroxyphenylglycol by 50-80% and produced a mean fall of 35% in whole body norepinephrine spillover. One interpretation of these results is that human sympathetic nerve firing is dependent on norepinephrine release within the brain and that increased cerebral norepinephrine release may possibly be present in some patients with essential hypertension, underlying their higher sympathetic nerve firing rates.

Neuronal reuptake of norepinephrine and production of dihydroxyphenylglycol by cardiac sympathetic nerves in the anesthetized dog

BACKGROUND

Reuptake of norepinephrine by cardiac sympathetic nerves before and during two levels of electrical stimulation of the left ansa subclavia was estimated in anesthetized dogs from the cardiac production of dihydroxyphenylglycol (DHPG), the intraneuronal metabolite of norepinephrine.

METHODS AND RESULTS

The method depended on the effects of neuronal uptake blockade with desipramine on the cardiac production of [3H]DHPG from intravenously infused [3H]norepinephrine. The ratio of the desipramine-induced decrease in the cardiac extraction of [3H]norepinephrine to the production of [3H]DHPG was used to transform the cardiac production of DHPG from recaptured norepinephrine into a rate for norepinephrine reuptake. Cardiac spillover of norepinephrine into plasma increased from 49 +/- 12 to 205 +/- 40 and 451 +/- 118 pmol/min during sympathetic activation. Cardiac DHPG production increased from 108 +/- 18 to 166 +/- 34 and 240 +/- 47 pmol/min. Desipramine decreased resting cardiac DHPG production by 20% and completely blocked the stimulation-induced increase. Thus, most (80%) cardiac DHPG produced at rest was derived from norepinephrine leaking from storage vesicles. This amount remained constant, and that derived from recaptured norepinephrine increased during sympathetic activation. The cardiac extraction of [3H]norepinephrine (126,000 dpm/min) and production of [3H]DHPG (3,790 dpm/min) were decreased by 55-57% after desipramine. Thus, only 3% of the norepinephrine recaptured by cardiac sympathetic nerves appeared in plasma as DHPG. The remainder was sequestered into storage vesicles (more than 94%) or ultimately formed metabolites other than DHPG (less than 3%). Reuptake of norepinephrine by cardiac sympathetic nerves was 1,188 +/- 476 pmol/min and increased in parallel with cardiac norepinephrine spillover to 4,182 +/- 1,982 and 6,594 +/- 2,241 pmol/min during sympathetic stimulation.

CONCLUSIONS

Of the norepinephrine released by cardiac sympathetic nerves, 16-fold more was recaptured than entered plasma. Combined estimation of norepinephrine reuptake and spillover offers an approach to assess the efficiency of neuronal reuptake in disorders of cardiac function.

Biochemical evidence of sympathetic denervation of the heart in pure autonomic failure

Primary autonomic failure is a heterogenous group of diseases with evidence for lesions in both the central and peripheral elements of the autonomic nervous system. We determined the extent of peripheral sympathetic dysfunction in six patients with primary autonomic failure without clinical evidence of central nervous system involvement (pure autonomic failure) using biochemical methods for studying regional noradrenaline spillover and removal. The results were compared with those from 14 age-matched normal subjects, seven of whom were studied before and after pharmacological neuronal uptake-blockade with desipramine. Total, cardiac and renal noradrenaline spillover to plasma were 78%, 98% and 66% lower respectively in pure autonomic failure than in normal subjects (p less than 0.001). Total noradrenaline plasma clearance was 20% lower in pure autonomic failure (p less than 0.005) than in normal subjects and similar to the level observed in normal subjects following neuronal noradrenaline uptake-blockade with desipramine, mean transcardiac extraction of tritiated noradrenaline was 74% in normal subjects and 20% in pure autonomic failure, identical to the value post-desipramine in normal subjects. Cardiac spillover of the noradrenaline precursor, dihydroxyphenylanine, and the primary intra-neuronal metabolite dihydroxyphenylglycol, were 78% and 94% lower respectively in pure autonomic failure than in normal subjects (p less than 0.001). These data indicate a marked reduction in the apparent release rate and neuronal uptake of noradrenaline in the hearts of patients with pure autonomic failure, and provide biochemical evidence of almost total postganglionic sympathetic denervation in this condition.

Increased plasma dihydroxyphenylalanine during sympathetic activation in humans is related to increased norepinephrine turnover

Plasma concentrations of dihydroxyphenylalanine (DOPA) were measured before and during isometric handgrip exercise or mental stress and after coffee drinking or intravenous infusion of desipramine to examine the influence of sympathetic nervous activity on DOPA formation. Sympathetic activity was assessed by the spillover of norepinephrine into plasma. Turnover of norepinephrine was assessed by the plasma concentration of its intraneuronal metabolite, dihydroxyphenylglycol (DHPG). In normal subjects the resting plasma concentration of DOPA was 6.05 +/- 0.16 nmol/L (n = 42). Plasma DOPA level was increased by stimulation of the sympathetic nervous system; handgrip exercise caused a 0.49 +/- 0.07 nmol/L increase (n = 15), mental stress a 0.25 +/- 0.10 nmol/L increase (n = 34), and coffee drinking a 0.85 +/- 0.19 nmol/L increase (n = 9). Desipramine decreased plasma DOPA level by 0.25 +/- 0.06 nmol/L (n = 23). The small but consistent changes in plasma DOPA level during manipulations of sympathetic activity were positively correlated with changes in norepinephrine spillover (r = 0.55, n = 81) and plasma DHPG level (r = 0.66, n = 81). Percentage increases in plasma DOPA level during sympathetic activation were similar to those in plasma DHPG but were a sixth of the percentage increases in norepinephrine spillover. The similar increases in plasma DOPA and DHPG levels indicated that production of DOPA was related to the turnover of norepinephrine in sympathetic nerves. The smaller percentage increases in plasma DOPA (smaller than those in norepinephrine spillover) were consistent with the partial contribution of exocytotic neurotransmitter release to the turnover of norepinephrine in sympathetic nerves.

Central sympathoinhibition and peripheral neuronal uptake blockade after desipramine in rabbits

Peripheral- and central nervous system (CNS)-mediated effects of desipramine (Des) on sympathetic nerves and the contribution of alpha 2-adrenoceptors to these effects were studied in conscious rabbits. Blood pressure, renal sympathetic nerve activity (SNA), and norepinephrine (NE) reuptake and spillover into plasma were measured before and after intracisternal (ic) or intravenous (i.v.) administration of Des. In other animals, NE spillover responses to i.v. Des were examined before and after alpha 2-adrenoceptor blockade with i.v. idazoxan. Treatment with i.v. Des blocked neuronal reuptake and decreased renal SNA but did not alter blood pressure or NE spillover. Decreased NE release by sympathetic nerves after i.v. Des was reflected by a decrease in the combined rate of NE reuptake and spillover. Treatment with ic Des (at 1.7% of the i.v. dose) decreased blood pressure and renal SNA and produced equivalent falls in NE reuptake and spillover, indicating little peripheral effect of centrally administered Des on the efficiency of neuronal reuptake. Thus Des had two distinct actions: the drug blocked neuronal reuptake by direct actions on nerve endings and reduced SNA by actions within the CNS. After ic Des, decreased SNA produced parallel falls in NE reuptake, spillover, and blood pressure. After i.v. Des, blockade of neurotransmitter reuptake increased NE concentrations at sympathoeffector junctions offsetting the fall in SNA, so that there was little change in NE spillover or blood pressure. However, after alpha 2-adrenoceptor blockade with i.v. idazoxan, NE spillover increased in response to i.v. Des. Thus the Des-induced decrease in NE release was partly mediated by an action of raised intrasynaptic NE concentrations on inhibitory alpha 2-adrenoceptors.

Effects of desipramine on sympathetic nerve firing and norepinephrine spillover to plasma in humans

In isolated organs, or when given in low dose intra-arterially, tricyclic antidepressant drugs are known to block reuptake of norepinephrine into sympathetic nerve varicosities, with a resultant increased norepinephrine washout. On the other hand, systemic administration of such drugs in humans reduces norepinephrine spillover to plasma. To clarify these seemingly contradictory findings, we have measured concurrently muscle sympathetic activity in the peroneal nerve (microneurography) and rates of norepinephrine spillover to plasma for the body as a whole and for the heart, the kidneys, and the forearm (radiotracer technique), both before and after intravenous infusion of desipramine, 0.5 mg/kg. Desipramine lowered the overflow of norepinephrine to plasma for the body as a whole and from the forearm and the kidneys (by 30-50%) but increased cardiac norepinephrine spillover by 25%. Both the number of sympathetic bursts per min in the peroneal nerve and their mean voltage amplitudes were markedly reduced after desipramine; total activity (bursts/min x mean burst amplitude) fell by approximately 90%. The effects of desipramine on norepinephrine spillover are explicable in terms of inhibition of central sympathetic outflow, balanced against the local blockade of transmitter reuptake. In most sites, the predominant effect is a reduction of norepinephrine overflow. For the heart, where reuptake is so important in transmitter disposition, the net effect is increased overflow.

Noradrenaline reuptake and plasma dihydroxyphenylglycol during sustained changes in sympathetic activity in rabbits

The effects of sustained changes in sympathetic activity, produced by intracisternal (i.c.) infusion of yohimbine or clonidine, on the formation of the intraneuronal noradrenaline metabolite, dihydroxyphenylglycol (DHPG), and on the efficiency of noradrenaline reuptake were examined in conscious rabbits. Noradrenaline spillover was estimated by radiotracer dilution analysis of i.v. infused [3H]noradrenaline. Noradrenaline reuptake was estimated from the amount of DHPG derived from recaptured neurotransmitter and the effects of desipramine-induced neuronal uptake blockade on noradrenaline clearance and plasma [3H]DHPG. The efficiency of neuronal reuptake was assessed from relationships between noradrenaline reuptake and spillover. Sustained sympathetic activation with i.c. yohimbine increased the amount of plasma DHPG that was derived from recaptured noradrenaline as well as that derived from other sources. Acute administration of desipramine decreased both components so that the decrease in plasma DHPG overestimated the amount derived from recaptured noradrenaline. Thus, estimation of the component of plasma DHPG that was derived from recaptured noradrenaline was most accurately achieved by examination of relationships between plasma noradrenaline and DHPG. Noradrenaline reuptake and spillover into plasma were decreased by i.c. infusion of clonidine and increased by i.c. infusion of yohimbine. Neither i.c. infusion of clonidine nor yohimbine altered relationships between noradrenaline reuptake and spillover indicating that the efficiency of neuronal reuptake was unaltered by sustained changes in sympathetic activity.