Intranasal orexin A modulates sympathetic vascular tone: a pilot study in healthy male humans.

Previous research suggests that the neuropeptide orexin A contributes to sympathetic blood pressure (BP) control inasmuch as hypothalamic injection of orexin A increases sympathetic vasomotor tone and arterial BP in rodents. In humans with narcolepsy, a disorder associated with loss of orexin-producing neurons, vasoconstrictive muscle sympathetic nerve activity (MSNA) is reduced. Since intranasally administered oligopeptides like orexin are known to modulate brain function, we investigated the effect of intranasal orexin A on vascular sympathetic baroreflex function in healthy humans. In a balanced, double-blind crossover study, orexin A (500 nmol) and placebo, respectively, were intranasally administered to 10 lean healthy males (age 25.8 ± 4.6 yr). MSNA was assessed microneurographically before and 30-45 min after either substance administration. Additionally, baroreflex was challenged via graded infusions of vasoactive drugs before and after substance administration. Baroreflex function was defined as the correlation of BP with MSNA and heart rate. Intranasal orexin A compared with placebo induced a significant increase in resting MSNA from pre-to postadministration [Δburst rate, orexin A vs. placebo: +5.8 ± 0.8 vs. +2.1 ± 0.6 bursts/min, P = 0.007; total activity 169 ± 11.5% vs. 115 ± 5.0%; P = 0.002]. BP, heart rate, and sympathovagal balance to the heart, as represented by heart rate variability (HRV), as well as baroreflex sensitivity during the vasoactive challenge were not altered. Intranasally administered orexin A acutely induced vasoconstrictory sympathoactivation in healthy male humans. This result suggests that orexin A mediates upward resetting of the vascular baroreflex set point at centers superordinate to the mere baroreflex feedback loop.NEW & NOTEWORTHY Our pilot study adds another important part to the complex network of neuroendocrine-sympathetic interaction. Our results demonstrate that intranasal orexin A elicits an excitatory effect on sympathetic vascular tone superordinate to mere baroreflex feedback regulation. This resetting of the baroreflex set point suggests an activation of hypothalamic core centers such as the paraventricular nucleus (PVN). The role of the orexinergic system in the development of neurogenic arterial hypertension warrants further investigations.

Intranasal oxytocin has sympathoexcitatory effects on vascular tone in healthy males.

Oxytocin appears to be involved in the neuroendocrine regulation of sympathetic blood pressure (BP) homeostasis. In animals, intracerebral administration of oxytocin induces BP-relevant sympathetic activation. In humans, central nervous effects of oxytocin on BP regulation remain unclear. Intranasal administration supposedly delivers oligopeptides such as oxytocin directly to the brain. We investigated the effects of intranasal oxytocin on sympathetic vascular baroreflex function in humans using microneurographic techniques. In a balanced, double-blind crossover design, oxytocin or placebo was administered intranasally to 12 lean, healthy males (age 25 ± 4 yr). Muscle sympathetic nerve activity (MSNA) was assessed microneurographically before (presubstance), 30-45 min (postsubstance I), and 105-120 min (postsubstance II) after oxytocin administration. Baroreflex was challenged via graded infusions of vasoactive drugs, and correlation of BP with MSNA and heart rate (HR) defined baroreflex function. Experiments were conducted in the afternoon after a 5-h fasting period. After oxytocin, resting MSNA (burst rate and total activity) showed significant net increases from pre to postsubstance II compared with placebo [Δincrease = +4.3 ± 1.2 (oxytocin) vs. +2.2 ± 1.4 bursts/min (placebo), ANOVA; P < 0.05; total activity = 184 ± 11.5% (oxytocin) vs. 121 ± 14.3% (placebo), ANOVA; P = 0.01). This was combined with a small but significant net increase in resting diastolic BP, whereas systolic and mean arterial BP or HR as well as baroreflex sensitivity at vasoactive drug challenge were not altered. Intranasally administered oxytocin induced vasoconstrictory sympathoactivation in healthy male humans. The concomitant increase of diastolic BP was most likely attributable to increased vascular tone. This suggests oxytocin-mediated upward resetting of the vascular baroreflex set point at centers superordinate to the mere baroreflex-feedback loop.

[Central nervous system control of energy homeostasis]. / Die Rolle des Gehirns in der Regulation des Stoffwechsels.

The brain is continuously supplied with information about the distribution and amount of energy stores from the body periphery. Endocrine, autonomic and cognitive-hedonic signals are centrally integrated and exert effects on the whole organism via anabolic and catabolic pathways. The adiposity signals insulin and leptin reflect the amount of body fat and are part of a negative feedback mechanism between the periphery and the central nervous system. The hypothalamic arcuate nucleus is the most important central nervous structure, which integrates this information. Furthermore, the CNS is able to directly measure and to respond to changes in the concentration of certain nutrients. In order to develop effective therapies for the treatment of disorders of energy balance the further elucidation of these neuro-biological processes is of crucial importance. This article provides an overview of the CNS regulation of metabolism and its underlying molecular mechanisms.