Jacqueline Hastings

Effects of intravenous brain natriuretic peptide on regional sympathetic activity in patients with chronic heart failure as compared with healthy control subjects.

OBJECTIVES We sought to assess the effects of brain natriuretic peptide (BNP) on systemic and regional sympathetic nervous activity (SNA) in both patients with congestive heart failure (CHF) and healthy control subjects. BACKGROUND Although the response of SNA to atrial natriuretic peptide (ANP) has been well documented, the response of SNA to BNP is largely unknown. METHODS We assessed cardiac and whole-body SNA using the norepinephrine (NE) tracer dilution method before and after infusion of two doses of BNP (3 and 15 ng/kg body weight per min) in 11 patients with stable CHF (ejection fraction 24 +/- 2%) and 12 age-matched healthy control subjects. In addition, renal SNA and hemodynamic variables were assessed at baseline and after the higher BNP dose. RESULTS Low dose BNP did not change blood pressure or whole-body NE spillover, but reduced cardiac NE spillover in both groups by 32 +/- 13 pmol/min (p < 0.05). In both groups, high dose BNP reduced pulmonary capillary pressure by 5 +/- 1 mm Hg (p < 0.001) and mean arterial pressure by 6 +/- 3 mm Hg (p < 0.05), without a concomitant increase in whole-body NE spillover; however, cardiac NE spillover returned to baseline levels. Renal NE spillover remained virtually unchanged in healthy control subjects (501 +/- 120 to 564 +/- 115 pmol/min), but was reduced in patients with CHF (976 +/- 133 to 656 +/- 127 pmol/min, p < 0.01). CONCLUSIONS Our results demonstrate a sympathoinhibitory effect of BNP. Cardiac sympathetic inhibition was observed at BNP concentrations within the physiologic range, whereas high dose BNP, when arterial and filling pressures fell and reflex sympathetic stimulation was expected, systemic and cardiac SNA equated to baseline values. There was inhibition of renal SNA in patients with CHF, but not in healthy control subjects. Whether this effect is specific to BNP or related to reduced filling pressure remains to be determined.

Elevated brain serotonin turnover in patients with depression : effect of genotype and therapy

CONTEXT The biological basis for the development of major depressive disorder (MDD) remains incompletely understood. OBJECTIVE To quantify brain serotonin (5-hydroxytryptamine [5-HT]) turnover in patients with MDD. DESIGN Patients with depression were studied both untreated and during administration of a selective serotonin reuptake inhibitor (SSRI) in an unblinded study of sequential design. Healthy volunteers were examined on only 1 occasion. Direct internal jugular venous blood sampling was used to directly quantify brain serotonin turnover. The effect of serotonin transporter (5-HTT) genotype on brain serotonin turnover was evaluated and the influence of SSRI therapy on serotonin turnover was investigated. SETTING Participants were recruited from the general community following media advertisement. Experimental procedures were performed in the research catheterization laboratory of a major training hospital and medical research institute. PARTICIPANTS Studies were performed in 21 patients fulfilling the DSM-IV and International Statistical Classification of Diseases, 10th Revision diagnostic criteria for MDD and in 40 healthy volunteers. INTERVENTIONS Treatment for patients consisted of SSRI administration for approximately 12 weeks. MAIN OUTCOME MEASURES Brain serotonin turnover before and after SSRI therapy. RESULTS Brain serotonin turnover was significantly elevated in unmedicated patients with MDD compared with healthy subjects (mean [SD] internal jugular venoarterial 5-hydroxyindoleacetic acid plasma concentration difference, 4.4 [4.3] vs 1.6 [2.4] nmol/L, respectively; P = .003). Analysis of the influence of the 5-HTT genotype in MDD indicated that carriage of the s allele compared with the l allele was associated with greater than a 2-fold increase in brain serotonin turnover (mean [SD] internal jugular venoarterial 5-hydroxyindoleacetic acid plasma concentration difference, 6.5 [4.7] vs 2.7 [2.9] nmol/L, respectively; P = .04). Following SSRI therapy, brain serotonin turnover was substantially reduced (mean [SD] internal jugular venoarterial 5-hydroxyindoleacetic acid plasma concentration difference, 6.0 [4.0] nmol/L prior to treatment vs 2.0 [3.3] nmol/L following therapy; P = .008). CONCLUSIONS Brain serotonin turnover is elevated in unmedicated patients with MDD and is influenced by the 5-HTT genotype. The marked reduction in serotonin turnover following SSRI treatment and the accompanying improvement in symptoms suggest that high brain serotonin turnover may be a biological substrate of MDD.

Phenotypic Evidence of Faulty Neuronal Norepinephrine Reuptake in Essential Hypertension

Previous reports suggest that neuronal norepinephrine (NE) reuptake may be impaired in essential hypertension, perhaps because of dysfunction of the NE transporter, although the evidence is inconclusive. To further test this proposition, we applied phenotypically relevant radiotracer methodology, infusion of tritiated NE and quantification of NE metabolites, to 34 healthy lean subjects (body mass index <27.0 kg/m2), 19 overweight (body mass index >28.0 kg/m2) but otherwise healthy normotensive subjects, 13 untreated lean patients with essential hypertension, and 14 obesity-related hypertensives. Spillover of NE from the heart was increased in lean hypertensives only (mean±SD 33.4±20.6 versus 16.1±11.7 ng/min in lean normotensives, P <0.05), but this could have resulted from high cardiac sympathetic nerve firing rates, faulty NE reuptake, or both. The arterial plasma concentration of 3-methoxy-4-hydroxylphenylglycol, an extraneuronal metabolite of NE, was elevated in lean hypertensives only (3942±1068 versus 3055±888 pg/mL in healthy subjects, P <0.05). The fractional extraction of plasma tritiated NE in passage through the heart, determined on the basis of neuronal NE uptake, was reduced in lean essential hypertensives (0.65±0.19 versus 0.81±0.11 in healthy subjects, P <0.05). Cardiac release of the tritiated NE metabolite [3H]dihydroxylphenylglycol, produced intraneuronally by monoamine oxidase after uptake of [3H]NE by the transporter, was reduced in lean hypertensives only (992±1435 versus 4588±3189 dpm/min in healthy subjects, P <0.01) These findings suggest that neuronal reuptake of NE is impaired in essential hypertension. Through amplification of the neural signal, such a defect could constitute a neurogenic variant of essential hypertension. In obesity-related hypertension, there was no phenotypic evidence of NE transporter dysfunction.

Leptin-receptor polymorphisms relate to obesity through blunted leptin-mediated sympathetic nerve activation in a Caucasian male population.

Leptin plays a key role in the regulation of body weight through the sympathetic nervous system; however, the contributions of leptin-receptor polymorphisms to obesity and sympathetic nerve activity have not been fully clarified. In the present study, we examined the relationships between leptin-receptor polymorphisms, plasma leptin and whole-body norepinephrine (NE) spillover as an index of sympathetic nerve activity in a Caucasian male cohort. In 129 young healthy normotensive men with a wide range of body mass index (BMI) (19.4–39.5 kg/m2), we measured leptin-receptor polymorphisms (Gln223Arg, Lys656Asn, and Lys109Arg), plasma leptin levels, whole-body NE spillover, whole-body NE clearance, BMI and blood pressure (BP) levels in the supine position after overnight fasting. Overweight-obese (BMI≥25 kg/m2) subjects had significantly greater BMI, BP levels, plasma leptin and whole-body NE spillover compared to lean (BMI<25 kg/m2) subjects, but the NE clearance was similar. Overweight-obese subjects had significantly higher frequencies of the Arg223 allele and the Arg223 homozygous allele of Gln223Arg and the Asn656 allele of Lys656Asn compared to lean subjects. Subjects carrying the Arg223 homozygous or the Asn656 allele had higher levels of plasma leptin, BMI, waist circumference, and waist-to-hip ratio, but significantly less whole-body NE spillover, especially when they were also overweight-obese. BP levels and whole-body NE clearance were similar between subjects with and without the Arg223 homozygous or Asn656 allele. No differences were found in the distributions of the Arg109 allele of Lys109Arg polymorphism between nonobese and overweight-obese subjects. In addition, BMI, BP, plasma leptin levels, whole-body NE spillover and whole-body NE clearance were similar between those with and without the Arg109 allele. Together, these findings demonstrate that leptin-receptor polymorphisms were related to the incidence of obesity in a Caucasian male population. These polymorphisms were accompanied by high plasma leptin levels (leptin resistance) and lower whole-body plasma NE spillover (blunted sympathetic nerve activity). We therefore hypothesize that leptin-receptor play a role in the development of obesity through leptin resistance and blunted leptin-mediated sympathetic nerve activity.

Cardiac Sympathetic Nerve Biology and Brain Monoamine Turnover in Panic Disorder

Abstract: Panic disorder serves as a clinical model for testing whether mental stress can cause heart disease. Our own cardiologic management of panic disorder provides case material of recurrent emergency room attendances with angina and electrocardiogram ischemia, triggered arrhythmias (atrial fibrillation, ventricular fibrillation), and documented coronary artery spasm, in some cases with coronary spasm being complicated by coronary thrombosis. Application of radiotracer catecholamine kinetics and clinical microneurography methodology suggests there is a genetic predisposition to panic disorder that involves faulty neuronal norepinephrine uptake, possibly sensitizing the heart to symptom generation. During panic attacks there are large sympathetic bursts, recorded by clinical microneurography in the muscle sympathetic nerve neurogram, and large increases in cardiac norepinephrine spillover, accompanied by surges of adrenal medullary epinephrine secretion. In other conditions such as heart failure and presumably here also, a high level of sympathetic nervous activation can mediate increased cardiac risk. The sympathetic nerve cotransmitter, neuropeptide Y (NPY), is released from the cardiac sympathetics during panic attacks, an intriguing finding given that NPY can cause coronary artery spasm. There is ongoing, continuous release of epinephrine from the heart in panic sufferers, perhaps attributable to epinephrine loading of cardiac sympathetic nerves by uptake from plasma during panic attacks, or possibly to in situ synthesis of epinephrine through the action of intracardiac phenylethanolamine‐N‐methytransferase (PNMT) activated by repeated cortisol responses. We have used internal jugular venous sampling and measurement of overflowing lipophilic brain monoamine metabolites to quantify brain norepinephrine and serotonin turnover in untreated patients with panic disorder. We find normal norepinephrine turnover but a marked increase in brain serotonin turnover in patients with panic disorder, in the absence of a panic attack, which presumably represents an underlying neurotransmitter substrate for the condition.

Increased brain serotonin turnover in panic disorder patients in the absence of a panic attack : reduction by a selective serotonin reuptake inhibitor

Since the brain neurotransmitter changes characterising panic disorder remain uncertain, we quantified brain noradrenaline and serotonin turnover in patients with panic disorder, in the absence of a panic attack. Thirty-four untreated patients with panic disorder and 24 matched healthy volunteers were studied. A novel method utilising internal jugular venous sampling, with thermodilution measurement of jugular blood flow, was used to directly quantify brain monoamine turnover, by measuring the overflow of noradrenaline and serotonin metabolites from the brain. Radiographic depiction of brain venous sinuses allowed differential venous sampling from cortical and subcortical regions. The relation of brain serotonin turnover to serotonin transporter genotype and panic disorder severity were evaluated, and the influence of an SSRI drug, citalopram, on serotonin turnover investigated. Brain noradrenaline turnover in panic disorder patients was similar to that in healthy subjects. In contrast, brain serotonin turnover, estimated from jugular venous overflow of the metabolite, 5-hydroxyindole acetic acid, was increased approximately 4-fold in subcortical brain regions and in the cerebral cortex (P < 0.01). Serotonin turnover was highest in patients with the most severe disease, was unrelated to serotonin transporter genotype, and was reduced by citalopram (P < 0.01). Normal brain noradrenaline turnover in panic disorder patients argues against primary importance of the locus coeruleus in this condition. The marked increase in serotonin turnover, in the absence of a panic attack, possibly represents an important underlying neurotransmitter substrate for the disorder, although this point remains uncertain. Support for this interpretation comes from the direct relationship which existed between serotonin turnover and illness severity, and the finding that SSRI administration reduced serotonin turnover. Serotonin transporter genotyping suggested that increased whole brain serotonin turnover most likely derived not from impaired serotonin reuptake, but from increased firing in serotonergic midbrain raphe neurons projecting to both subcortical brain regions and the cerebral cortex.

NPY Y1 receptors exert opposite effects on corticotropin releasing factor and noradrenaline overflow from the rat hypothalamus in vitro

Neuropeptide Y (NPY), corticotropin releasing factor (CRF) and noradrenaline play important roles in the regulation of a number of endocrine and autonomic functions. NPY is co-localised with noradrenaline in the central nervous system and has been observed to modulate noradrenaline release. Recent morphological and physiological studies also support co-modulatory interactions between NPY and CRF. Earlier in vivo studies in our laboratory showed a potentiation of K(+)-stimulated noradrenaline release following NPY administration, possibly due to an NPY Y1 receptor mechanism. In this study, in vitro superfusion techniques were established to simultaneously monitor the release of endogenous noradrenaline and CRF from the hypothalamus of adult rats and to examine the direct neuromodulatory action of NPY on the overflow of CRF and noradrenaline. Administration of 0.10 microM NPY significantly increased CRF overflow to 395% basal levels and reduced hypothalamic noradrenaline overflow to 61% of basal levels. These effects were blocked by prior administration of the NPY Y1 receptor antagonist GR231118. Thus, this study suggests that NPY, working through a Y1 receptor, has dual and opposing effects on CRF and noradrenaline overflow in vitro.

Influence of ageing on the sympathetic nervous system and adrenal medulla at rest and during stress

The influence of ageing on the sympathetic nervous system and adrenal medulla was studied neuro chemically in humans, using isotopic dilution measurement of regional and whole body catecholamine release to plasma in humans. With ageing, sympathetic activation was evident in the heart, and the gut and liver at rest. The mechanism appeared to be by activation of sympathoexcitatory noradrenergic suprabulbar projections from the brainstem. Sympathetic nervous responses with stressors were augmented. Conversely, adrenal medullary release of epinephrine was subnormal in the elderly, at rest and during stress.

Influence of leptin on neurotransmitter overflow from the rat brain in vitro

The 16-kDa polypeptide hormone, leptin along with the neurotransmitters noradrenaline and serotonin (5-HT) have important physiological roles in the regulation of a number of neuroendocrine actions particularly feeding. Leptin receptor mRNA and immunoreactivity has been reported in various brain regions, while recent studies suggest that leptin is released from the human brain. This study investigated the interactions between leptinergic and neurotransmitter systems of the rat brain in vitro. Techniques were established to simultaneously monitor the release of endogenous noradrenaline and its metabolite 3,4 dihydroxyphenylglycol (DHPG), and 5-HT and its metabolite 5-hydroxyindoleacetic acid (5-HIAA) from the rat brain. The neuromodulatory action of leptin (0.2 and 3 nM) on the overflow of noradrenaline and DHPG from the medulla and hypothalamus was examined. The effect of leptin on 5-HT and 5-HIAA overflow from the hypothalamus was also investigated. Administration of 0.2 and 3 nM leptin significantly increased medullary noradrenaline overflow to 172% and 174% of basal levels, respectively. Leptin had no significant effect on hypothalamic noradrenaline overflow, while leptin perfusion induced a significant increase in 5-HIAA overflow from the hypothalamus. This study lends support to the notion of a complex interaction of the leptinergic and brain neurotransmitters involved in the control of feeding and energy metabolism.

Neuropeptide Y and [Leu31,Pro34]neuropeptide Y potentiate potassium-induced noradrenaline release in the paraventricular nucleus of the aged rat

This microdialysis study investigated the effects of NPY and the Y1 selective agonist [Leu31, Pro34]NPY on basal and potassium-stimulated noradrenaline release in the PVN of 18-month-old anaesthetised male Sprague-Dawley rats. Microdialysate noradrenaline, DOPAC and HVA concentrations were measured by HPLC after i.c.v. administration of 2 nmol NPY, [Leu31, Pro34]NPY or vehicle. [Leu31, Pro34]NPY produced a significant 40% reduction in basal noradrenaline concentration (P < 0.05). Aged rats had blunted noradrenaline response to potassium stimulation, however stimulated noradrenaline release was similar in 18-month-old NPY-treated animals and 3-month-old saline treated age controls (2.8 and 3.2 times resting, respectively). [Leu31, Pro34]NPY induced a significantly greater release of noradrenaline in response to KC1 (5.0 times resting, P < 0.05). Thus, in 18-month-old animals with reduced endogenous hypothalamic NPY content, administration of NPY or [Leu31, Pro34]NPY increased potassium-induced noradrenaline release to levels seen in 3-month-old rats. This effect may be mediated by an NPY Y1 receptor.