Noradrenaline Overflow Research Articles

Sympathoadrenal Responses to Bronchoconstriction in Asthma: An Invasive and Kinetic Study of Plasma Catecholamines

1. Bronchoconstriction does not seem to be a stimulus for sympathoadrenal activation, as judged by venous plasma concentrations of noradrenaline, adrenaline or neuropeptide Y-like immunoreactivity. However, venous measurements have methodological drawbacks. In the present study arterial and mixed venous (pulmonary arterial) levels of these variables were determined before and after histamine-induced bronchoconstriction in non-medicated asthmatic subjects. In addition, noradrenaline kinetics in plasma (isotope dilution) and the pulmonary overflows of noradrenaline and neuropeptide Y-like immunoreactivity were determined. 2. Histamine inhalation induced bronchoconstriction; forced expiratory volume in ls decreased by 38.7% +/- 4.1% (SE) and arterial PO2 by 3.0 +/- 0.9 kPa. This acute bronchoconstriction induced significant elevations of arterial and mixed venous plasma noradrenaline from < or = 1.18 nmol/l to > or = 1.40 nmol/l. The clearance of NA from plasma increased marginally. Thus, the arterial plasma NA response was due to increased spillover of noradrenaline to plasma (from 1.80 +/- 0.18 to 2.52 +/- 0.36 mmol min-1/m2 at maximal bronchoconstriction, with a subsequent further increase). There were no elevations of adrenaline or neuropeptide Y-like immunoreactivity in arterial plasma. 3. No sympathetic activation could be demonstrated in the lungs (pulmonary noradrenaline or neuropeptide Y-like immunoreactivity overflow), and no alterations in pulmonary vascular resistance or cardiac output were observed. Neither arterial nor mixed venous plasma concentrations of adrenaline were influenced by bronchoconstriction. 4. Acute bronchoconstriction thus leads to peripheral sympathetic activation (possibly due to the increased work of breathing) which does not involve the lungs.(ABSTRACT TRUNCATED AT 250 WORDS)

Co-released adrenaline markedly facilitates noradrenaline overflow through prejunctional β2-adrenoceptors during swimming exercise

The effect of intravenously applied (−)-adrenaline, taken up by and released from sympathetic nerves, on swimming exercise-induced noradrenaline overflow in permanently cannulated adrenal demedullated rats was studied. Adrenaline (100 ng/min) was infused for 2 h, during which a plasma concentration of 500 pg/ml (approximately 2.5 nM) was reached. One hour later plasma adrenaline had returned to undetectable levels. During swimming, adrenaline was released into the plasma in concentrations up to 133 pg/ml and the noradrenaline concentration was markedly enhanced as well. The total catecholamine increase amounted to 178% of control (saline infusion) in the first 3 min of swimming and 165% for the whole 20 min. Cocaine (2.5 mg/kg plus 0.05 mg/kg/min), infused together with adrenaline and continued throughout the experiment, prevented the exercise-induced release of adrenaline and no increase in plasma noradrenaline concentration was observed. Yohimbine (0.25 mg/kg) strongly further enhanced the exercise-induced overflow of both noradrenaline and adrenaline. This further increase was completely blocked by the selective β 2-adrenoceptor antagonist ICI 118,551 ((±)-1-[(2,3-dihydro-7-methyl-1 H-inden-4-yl)oxy]-3-[(1-methylethyl)amino]-2-butanol) (1.0 mg/kg). These results demonstrate that adrenaline can be taken up by sympathetic nerve endings through cocaine-sensitive uptake carriers and is released from these nerves during swimming exercise. Neuronally released adrenaline markedly enhances exercise-induced catecholamine overflow through activation of prejunctional β 2-adrenoceptors.

Interaction between nitric oxide and angiotensin II on antidiuresis and norepinephrine overflow induced by stimulation of renal nerves in anesthetized dogs.

We examined the effects of NG-nitro-L-arginine (NOARG) on antidiuresis and norepinephrine (NE) overflow in anesthetized dogs, induced by renal nerve stimulation (RNS), with or without blockade of an action of endogenous angiotensin II (AII) on the AT1 receptors by losartan. RNS (2.5-5.0 Hz) caused significant reductions in renal blood flow (RBF), glomerular filtration rate (GFR), filtration fraction (FF), urine flow (UF), and urinary excretion of sodium (UNaV) and increases in the differences in renal arteriovenous NE concentrations (NEC). Intrarenal arterial (i.r.a.) infusion of NOARG (40 micrograms/kg/min) significantly decreased RBF and UF, and increased FF, but did not alter GFR. When losartan 100 micrograms/kg/min was infused simultaneously, NOARG reduced RBF, UF, and GFR but had no effect on FF. With high-frequency RNS, NOARG enhanced the RNS-induced decreases in RBF, GFR, UF, and UNaV and the increases in NEC. During losartan infusion, NOARG-induced enhancements on renal actions in response to RNS were observed in a manner qualitatively similar to that without losartan. Most likely endogenous nitric oxide (NO) plays the role of inhibitory modulator of renal noradrenergic neurotransmission. Enhancement of renal noradrenergic neurotransmission induced by NO blockade is likely to be independent of an action of endogenous AII on the AT1 receptors.

Impulse interval-dependent effect of sympathetic nerve stimulation on evoked acetylcholine release from the rabbit perfused atria preparation

The aim of the present study was to explore possible prejunctional effects mediated by impulse activity of sympathetic terminals on evoked acetylcholine release in an organ innervated by the autonomic ground plexus. Rabbit atria were isolated with the extrinsic right vagus and sympathetic nerves intact and perfused with Tyrode solution. Acetylcholine overflow was determined after labelling of the transmitter stores with [14C]choline and fractionation of the radioactivity on cation exchange columns. The overflow of endogenous noradrenaline was measured by HPLC and electrochemical detection. The vagus nerve was stimulated at 2 Hz for 3 min four times at intervals of 10 min. During the second stimulation the postganglionic sympathetic nerves were stimulated (2 Hz, 3 min) in such a way that the impulses preceded the vagus stimuli by a fixed time interval which was varied in different experiments (0, 7, 19, 50, 132, and 350 ms). Evoked acetylcholine release was significantly enhanced when the vagus was excited 7, 19 and 50 ms after the sympathetic nerves but it was unaltered at the 132 or 350 ms intervals, and when both nerves were stimulated simultaneously. Noradrenaline release was similar (about 6 ng per stimulation period) in all experimental groups. When sympathetic nerve stimulation had little effect in releasing noradrenaline (< 2.0 ng per stimulation period), facilitation of acetylcholine release at the 19 ms pulse interval was absent. The resting outflow of acetylcholine was unaffected by sympathetic nerve stimulation. The experiments show a facilitation of evoked acetylcholine release by sympathetic activity. As revealed by the pulse-to-pulse method this effect is confined to a relatively brief interval immediately following the excitation of the noradrenergic terminal, and is unlikely to be mimicked by exogenous drug application.

Sympatholytic action of intravenous amiodarone in the rat heart.

Amiodarone is a commonly used antiarrhythmic agent with complex pharmacological effects. Although ventricular arrhythmias can be suppressed soon after intravenous amiodarone, the mechanisms responsible for this action are unclear. We studied the effects of acute treatment with amiodarone on the metabolism and release of norepinephrine (NE) in intact rats and in perfused rat hearts. Experiments were performed in anesthetized rats and in perfused, innervated hearts with amiodarone administered intravascularly. NE release was induced by electrical stimulation of the sympathetic ganglion. Concentrations of NE and its intraneuronal metabolite dihydroxyphenylglycol (DHPG) in hearts, plasma, and coronary venous effluent were measured by high-performance liquid chromatography. Acute administration of amiodarone induced dose-dependent increases in DHPG concentrations in plasma (5 mg/kg, +48%; 15 mg/kg, +84%; and 50 mg/kg, +467%) and in coronary venous effluent (1 mumol/L, +37%; 3 mumol/L, +510%; and 10 mumol/L, +1100%) together with an unchanged basal overflow of NE. In perfused hearts, NE release evoked by nerve stimulation was inhibited by infusion of amiodarone (1 mumol/L, -16%; 3 mumol/L, -24%; and 10 mumol/L, -64%) or by intravenous amiodarone (50 mg/kg) given 1 hour before heart perfusion (-70%), and the extent of this suppression correlated well with levels of DHPG overflow present immediately before nerve stimulation. When given in vitro and in vivo, amiodarone also significantly reduced NE and increased DHPG content in the heart, leading to a raised DHPG/NE ratio. All these effects of amiodarone were similar to those found with reserpine but less potent. In contrast, oral amiodarone produced none of these effects. Acute administration of amiodarone in perfused hearts or intact rats induces partial NE depletion in the heart by interfering with vesicular NE storage and enhancing intraneuronal NE metabolism, effects associated with an impaired NE release during sympathetic activation. Oral dosing with amiodarone has no such effect. Further study is required to test whether this novel sympatholytic effect of amiodarone contributes to its antiarrhythmic action after intravenous administration.

N-Methyl- di-aspartate receptors modulate neurotransmitter release and peristalsis in the guinea pig isolated colon

To assess the role of NMDA receptors in modulating neurotransmitter release in the myenteric plexus, we studied the effects of l-glutamic acid and NMDA on endogenous acetylcholine and noradrenaline overflow (assayed by HPLC) from the guinea pig isolated distal colon. l-Glutamic acid and NMDA enhanced electrically evoked acetylcholine and noradrenaline overflow and these effects were reversed by selective NMDA receptor antagonists. The possible functional significance of these findings was studied by measuring the efficiency of the colonic peristaltic reflex in the presence of NMDA receptor agonists. NMDA inhibited propulsion velocity at all concentrations tested, this effect being antagonized by (±)-2-amino-5-phosphonopentanoic acid and virtually abolished in sympathetically denervated animals. In conclusion, the inhibitory effect of NMDA on peristalsis, being almost entirely dependent on the integrity of sympathetic; pathways, could be, at least in part, due to NMDA-induced noradrenaline release.

1-Aminocyclopropanecarboxylic acid is a partial agonist at rat hippocampal presynaptic NMDA receptors

Pre- and postjunctional effects of the α1-selectiv adrenoceptor antagonist prazosin and the α1- and α2-selective adrenoceptor agonists methoxamine and 6-fluoronoradrenaline, respectively, were studied in skeletal muscle in situ. Prazosin reduced the vasoconstriction and enhanced the overflow of endogenous noradrenaline elicited by sympathetic nerve stimulation (1–4 Hz, 2 min); the threshold concentration was 10–100 times lower for postjunctional than for prejunctional α-adrenoceptor blockade. The enhancement of noradrenaline overflow by prazosin was not inversely frequency-dependent, as shown elsewhere for α2-adrenoceptor antagonists. Thus, different mechanisms may be involved. Inhibition of prostaglandin synthesis by diclofenac did not alter the stimulation-evoked noradrenaline overflow, indicating a minor importance of prostaglandin-mediated transjunctional mechanisms in the modulation of noradrenaline overflow. Methoxamine and 6-fluoronoradrenaline elevated the basal vascular tone and, at higher concentrations, reduced the stimulation-evoked noradrenaline overflow. Methoxamine was 20 times more selective than 6-fluoronoradrenaline for postjunctional receptors. Our results are compatible with a pre- and postjunctional localization of α2-adrenoceptors and a predominantly, but not exclusively, postjunctional localization of α1-adrenoceptors. The postjunctional selectivity for prazosin was less marked than previously reported from in vitro studies. Hence, care should be taken when extrapolating in vitro findings to the more complex in vivo situation.

Electrically-evoked release of taurine in the rat vas deferens: evidence for a purinoceptor-mediated effect.

Release of taurine evoked by electrical stimulation (2700 pulses; 5 Hz; 10 mA unless stated otherwise) and its dependence on noradrenaline and ATP was studied in isolated, perifused rat vas deferens. Outflow of noradrenaline was also measured in some experiments. The basal outflow of taurine averaged 3.90 +/- 0.32 nmol/g tissue per min. Electrical stimulation increased the outflow to about 4 times basal values. The electrically-evoked overflow averaged 128.0 +/- 11.7 nmol/g. An increase in current strength to 40 mA increased the evoked overflow by about 50%. At either current strength, the evoked overflow of taurine (and noradrenaline) was abolished by tetrodotoxin. Ca(2+)-deprivation blocked the overflow of taurine elicited by 10 mA and increased the overflow elicited by 40 mA pulses (but abolished noradrenaline overflow under either condition). Neither prazosin nor pretreatment of the rats with reserpine reduced electrically-evoked overflow of taurine (although reserpine pretreatment abolished evoked noradrenaline overflow). Tyramine (100 mumols/l; 9 min) caused an overflow of taurine 36% of that caused by electrical stimulation (but an overflow of noradrenaline 3 times higher than that evoked by electrical stimulation). Exogenous noradrenaline (9 min) caused a concentration-dependent overflow of taurine with a maximal effect at 162 mumol/l, amounting to 33% of the electrically-evoked overflow. alpha,beta-Methylene ATP (19 mumols/l) elicited an overflow of taurine that faded despite continued exposure to the drug and amounted to 62% of the response to electrical stimulation. Thirty minutes after the start of application of alpha,beta-methylene ATP, electrically-evoked overflow of taurine was greatly reduced. Suramin (100 mumols/l) also reduced taurine overflow in response to electrical stimulation.(ABSTRACT TRUNCATED AT 250 WORDS)

Central nervous system noradrenergic control of sympathetic outflow in normotensive and hypertensive humans.

We applied transmitter washout methodology, sampling internal jugular venous plasma via a percutaneously placed catheter, to study CNS norepinephrine release in humans and its relation to peripheral sympathetic activity. Norepinephrine overflows into the venous drainage of the brain, as do its precursor, DOPA, and metabolites DHPG and MHPG, indicating that the blood-brain barrier provides an incomplete impediment to their outward flux from the brain. Pharmacological testing with two drugs which altered CNS norepinephrine turnover, the tricyclic antidepressant desipramine and the ganglionic blocker, trimethaphan, demonstrated a direct relation existed between CNS norepinephrine release and sympathetic nerve firing rates. In essential hypertension, the sympathetic activation commonly present was associated with, and possibly caused by increased CNS release of norepinephrine, manifested in elevated overflow of norepinephrine, MHPG and DHPG from the brain. Bilateral jugular sampling, coupled with a cerebral venous sinus scan to delineate the drainage pattern, demonstrated that this increased norepinephrine release was confined to subcortical forebrain regions.

Nitric Oxide and Peripheral Adrenergic Neuromodulation

Researches indicate that in resistance vessels nitric oxide (NO) attenuates adrenergic responses by a postjunctional action, but not by decreasing norepinephrine (NE) release. In the heart NO does not modulate the chronotropic response to adrenergic nerve stimulation, but does enhance NE overflow in association with coronary vasodilation and ischemia/reperfusion. By directly testing the effects of NO in a reductionist system such as cardiac synaptosomes, where no local reflex mechanisms come into play, a potent concentration-dependent biphasic effect of NO on adrenergic nerve endings is uncovered. Thus, findings on cardiac synaptosomes may help to explain the discrepancies in the literature on the modulatory effects of NO on adrenergic nerve function. NO could have both inhibitory and facilitatory prejunctional effects on vascular sympathetic neurotransmission. As considerable disagreement still exists as to whether NO facilitates or inhibits sympathetic neurotransmission and whether NO acts pre- or postjunctionally, the role of NO is examined by studying its effects on endogenous norepinephrine (NE) release in a prototypic peripheral resistance bed, in the whole heart, and in sympathetic nerve endings isolated from the heart (i.e., cardiac synaptosomes). These studies indicate that in resistance districts, NO modulates adrenergic responses, but not NE release.

Influence of the baroreceptor reflex on the modulation of noradrenaline overflow through prejunctional receptors in the portal vein of freely moving rats

1. The effects of alterations in mean arterial blood pressure (MAP), as induced by vasoactive drugs, on heart rate (HR), basal noradrenaline concentration and electrically evoked noradrenaline overflow and on blood flow in the portal vein of freely moving rats, were investigated. 2. By infusion of sodium nitroprusside or phenylephrine (0.5, 1.0 and 2.5 micrograms kg-1 min-1), MAP was altered over a range of 50 to 150 mmHg. The resulting changes in HR showed a sigmoidal relationship with MAP. Noradrenaline overflow increased linearly when MAP was decreased; when MAP was increased, however, noradrenaline levels only decreased to 70% and reached a plateau from 125 mmHg onwards. 3. Nitroprusside (2.5 micrograms kg-1 min-1) and fenoterol (0.25 mg kg-1) decreased MAP to the same extent (-46 mmHg). HR and basal noradrenaline concentration, however, were increased to a higher extent by fenoterol (+192 beats min-1; +373 pg ml-1, respectively) than by nitroprusside (+78 beats min-1; +206 pg ml-1, respectively). Electrically evoked overflow was not changed at all after nitroprusside, whereas fenoterol induced an increase to 206% of control. 4. Phenylephrine (2.5 micrograms kg-1 min-1) and angiotensin II (1 microgram kg-1 min-1) increased MAP to the same extent (to 155 and 161 mmHg, respectively). Basal noradrenaline concentration decreased by 30% after phenylephrine, whereas angiotensin II increased noradrenaline levels to 226% of control. Evoked noradrenaline overflow was not changed after phenylephrine but was increased to 204% of control after angiotensin II.(ABSTRACT TRUNCATED AT 250 WORDS)

Muscarinic inhibition of cardiac norepinephrine and neuropeptide Y release during ischemia and reperfusion

It was the aim of the present study to characterize the modulatory effect of muscarinic agonists on the overflow of norepinephrine and neuropeptide Y (NPY) from the in situ perfused guinea pig heart, induced by electrical stimulation of the left stellate ganglion (6 Hz, 5 V, 1 min). The muscarinic agonists oxotremorine (0.01-1 microM) and carbachol (0.1-10 microM) reduced norepinephrine and NPY overflow in a concentration-dependent manner to approximately 30% of control. The inhibitory effect of carbachol was antagonized by the unspecific muscarinic antagonist atropine (1 microM) but not by the nicotinic antagonist hexamethonium (100 microM). The M2-specific antagonist AF-DX-116BS was 25 times more potent than the M1-specific antagonist pirenzepine in antagonizing the inhibitory effect of carbachol [50% inhibitory concentration (IC50) = 0.2 microM for AF-DX-116BS; IC50 = 5.0 microM for pirenzepine]. These findings indicate that presynaptic muscarinic inhibition of stimulated norepinephrine and NPY release from the guinea pig heart is mediated mainly by activation of M2 receptors. As early as 2 min after stop-flow ischemia, the inhibitory effect of carbachol (10 microM) on the stimulation-evoked overflow of norepinephrine and NPY was lost. On reperfusion with oxygenated buffer after 10 min of stop-flow ischemia the inhibitory effect of carbachol (10 microM) on stimulation-induced norepinephrine and NPY overflow recovered within 3 min.

Intracoronary infusion of bradykinin: effects on noradrenaline overflow following reperfusion of ischemic myocardium in the anesthetized dog.

The aim of this study was to investigate the effects of intracoronary bradykinin (BK) infusion on noradrenaline release and ventricular arrhythmias induced by coronary occlusion and reperfusion in the anesthetized dog. 14 anesthetized adult mongrel dogs of either sex underwent a 60 min occlusion of the left anterior descending coronary artery (LAD) followed by a 30-min reperfusion period. BK (1 ng.kg-1.min-1, n = 7), or its vehicle (Lactate Ringer, n = 7), infusions just distal to the left coronary ostium started 15 min before the LAD occlusion and were maintained throughout the experimental period. An epicardial vein, running parallel to the LAD was cannulated to enable the biochemical determinations. The effects of BK on ventricular arrhythmias, cardiac noradrenaline and lactate releases and creatine kinase activity were assessed. BK significantly reduced the amount of noradrenaline released at reperfusion by ischemic myocardium (from 82.1 +/- 31.7 to 11.9 +/- 9.6 ng.min-1), as well as plasma creatine kinase activity at 30 min of reperfusion. This is accompanied by a significant reduction in the incidence of reperfusion-induced sustained ventricular tachycardia. This suggests that the protective effect of bradykinin against reperfusion-induced sustained ventricular tachycardia could be associated with a reduction in cardiac noradrenaline release.

Histamine and serotonin released from the rat perfused heart by compound 48/80 or by allergen challenge influence noradrenaline or acetylcholine exocytotic release.

Terminal nerve fibres of the autonomic nervous system closely approach mast cells in peripheral organs, and mutual influences between release of neurotransmitters or mast cell mediators may cause neuro-immunological interactions. We have studied the influence of mast cell degranulation on the release of endogenous noradrenaline and newly incorporated acetylcholine (such as 14C-choline/acetylcholine overflow) evoked by stimulation of extrinsic postganglionic sympathetic or preganglionic vagal nerves in the rat Langendorff heart perfused with Tyrode solution. Compound 48/80 perfused in normal hearts, or ovalbumin infused into hearts from rats sensitized to ovalbumin, enhanced the overflow of endogenous histamine and serotonin. Both stimuli increased the release of mediators to a similar extent and with fast kinetics. Maximum average concentrations in the perfusate of histamine were about 800 nmol/l, and of serotonin 40 nmol/l, in a sample collected within 4 min after mast cell degranulation. Stimulation of autonomic nerves did not affect basal histamine or serotonin overflow. Whereas basal overflows were unaffected, the stimulation-evoked releases of both noradrenaline and acetylcholine, were facilitated when compound 48/80 was perfused before and during nerve stimulation. The facilitation of noradrenaline overflow was more pronounced (by 60%) when compound 48/80-induced mediator overflow started 4 min before nerve stimulation as compared to 30 s (15%), and was reduced by cocaine (by 50%), and, in the presence of cocaine, abolished by cimetidine (but was unaffected by mepyramine and thioperamide) and NG-nitro-(L)-(-)-arginine. In the presence of cimetidine and cocaine, when the facilitatory components were abolished, the evoked noradrenaline overflow observed 30 s after the start of infusion of compound 48/80 was inhibited, and the inhibition was partly reduced by methiotepin and ketanserin. Ovalbumin infusion in hearts from sensitized animals caused an inhibition of evoked noradrenaline overflow sensitive to methiotepin and also partly to ketanserin, and no facilitation was observed. The facilitation (> 100%) of evoked overflow of acetylcholine observed at 4 min after the start of perfusion with compound 48/80 was partly reduced by thioperamide (but not mepyramine or cimetidine) and to a comparable extent either by tropisetron (3 mumol/l) alone or by tropisetron plus methiotepin. In conclusion, degranulation of immunological cells is followed by histamine and serotonin release in the rat heart and may affect the release of autonomic neurotransmitters in rather unusual ways, by i) an uptake1-dependent and ii) an H2-mediated facilitation which probably involves nitric oxide as a permissive mediator, and iii) a serotonergic inhibition, of noradrenaline release, and iv) an H3- and serotonergic facilitation of acetylcholine release.

Beta-adrenoceptor-mediated facilitation of endogenous noradrenaline release from rat isolated trachea.

Overflow of endogenous noradrenaline from rat isolated trachea was evoked by electrical field stimulation (3 Hz, 540 pulses) in the presence of yohimbine, desipramine and tyrosine. Isoprenaline 100 nmol/l increased the evoked overflow of noradrenaline by about 65%. This effect was antagonized by propranolol (100 nmol/l) and the beta 2-selective adrenoceptor antagonist ICI 118,551 (100 nmol/l), but not by the beta 1-selective adrenoceptor antagonist CGP 20712 A (100 nmol/l). The beta 2-selective adrenoceptor agonist formoterol (1-100 nmol/l) also facilitated the evoked overflow of noradrenaline, but maximally by only about 25% at 10 nmol/l, i.e. formoterol behaved as a partial agonist at these facilitatory beta-adrenoceptor. This assumption is also supported by the observation that formoterol (10 nmol/l) acted as antagonist against isoprenaline (100 nmol/l). Mechanical removal of the mucosa resulted in a 30% decrease in tissue noradrenaline and a 55% reduction of the evoked overflow of noradrenaline. In mucosa-denuded preparations isoprenaline failed to facilitate noradrenaline overflow. In the presence of indomethacin (3 mumol/l) the evoked overflow of noradrenaline from mucosa containing preparations was increased by about 50%, but isoprenaline still further facilitated the evoked noradrenaline overflow by about 40%. In conclusion, the overflow of noradrenaline in the rat trachea is facilitated via beta 2-adrenoceptors, an effect which requires an intact airway mucosa.

Effect of desipramine-induced blockade of neuronal uptake mechanisms on adrenoceptor-mediated responses in the guinea-pig colon

In order to clarify whether adrenoceptors in the guinea-pig distal colon are under sympathetic control, we assessed possible variations in the sensitivity to adrenoceptor agonists after blockade of neuronal catecholamine uptake mechanisms by desipramine (DMI). First, experiments were carried out to investigate the effects of DMI added in the organ bath on propulsion velocity, endogenous and [3H] prelabelled acetylcholine overflow, electrically evoked noradrenaline overflow and longitudinal smooth muscle tone. Secondly, we studied the effects of adrenoceptor agonists on the above parameters in untreated animals and in animals chronically treated with DMI. DMI added in the organ bath at concentrations equal to or higher than 30 nM inhibited all the parameters under study. Thus, when evaluating the effect of DMI on concentration-response curves to adrenoceptor agonists, concentrations which were per se inactive were used. DMI added in the organ bath at concentrations up to 30 nM potentiated the inhibitory effects of exogenous noradrenaline on propulsion velocity and acetylcholine overflow, but it did not affect the concentration-response curve to exogenous noradrenaline on longitudinal smooth muscle tone. Furthermore, 30 nM DMI inhibited propulsion velocity during sympathetic nerve stimulation. In preparations obtained from animals chronically treated with DMI, no significant change of propulsion velocity, endogenous and [3H] prelabelled acetylcholine overflow was found with respect to untreated animals. Nevertheless, in such preparations subsensitivity to isoprenaline (acting mainly on muscular beta-adrenoceptors) and clonidine (acting on neuronal alpha 2-adrenoceptors) and super-sensitivity to phenylephrine were observed. Electrically evoked noradrenaline overflow was enhanced, in a frequency-dependent way, by yohimbine and inhibited by clonidine.(ABSTRACT TRUNCATED AT 250 WORDS)

Sustained prejunctional facilitation of noradrenergic neurotransmission by adrenaline as a co‐transmitter in the portal vein of freely moving rats

1. The duration of the facilitatory effect of adrenaline on the electrically evoked overflow of noradrenaline was studied in the portal vein of permanently adreno-demedullated freely moving rats. 2. Rats were infused with adrenaline (20 or 100 ng min-1) for 2 h. After an interval of 1 h, when plasma adrenaline had returned to undetectable levels, electrical stimulation resulted in an enhanced catecholamine overflow amounting to 219% (noradrenaline) and 241% (noradrenaline plus adrenaline) of control (saline infusion), respectively. 3. When stimulation was applied again, in the same animal, at 24, 48 and 72 h after the first stimulation episode, the evoked noradrenaline overflow was 150, 111 and 102% (after 20 ng ml-1 adrenaline) and 158, 134 and 105% (after 100 ng min-1 adrenaline) of control. 4. The beta 2-adrenoceptor antagonist, ICI 118,551 (0.3 mg kg-1), blocked the facilitatory effect obtained after the 100 ng min-1 adrenaline infusion on all days. 5. The results show that adrenaline, after being taken up by and released from sympathetic nerve terminals, is able to facilitate the evoked noradrenaline overflow through activation of prejunctional beta 2-adrenoceptors for at least 48 h after administration.

In vivo dynamics of norepinephrine release-reuptake in multiple terminal field regions of rat brain.

Electrical stimulation of the ascending dorsal tegmental bundle of the locus ceruleus was used to elicit controlled release of norepinephrine. Real-time in vivo monitoring in the brains of urethane-anesthetized rats was observed with high speed chronocoulometry at rapidly responding carbon fiber electrodes. Using modeling similar to that developed for dopamine release, the electrochemical signals were characterized as the balance between norepinephrine release per electrical stimulation pulse and apparent Michaelis-Menten reuptake parameters. Stimulation produced simultaneous overflow release at all terminal fields examined. The release and reuptake characteristics varied considerably in different regions. If the parameters are normalized to endogenous concentration in the terminal fields, release but not reuptake correlates with innervation density in several regions. Stimulated release results in norepinephrine overflow and transport in most brain regions with half-lives of 1-3 s and overflow distances of 25-50 microns at most. A surprising exception occurs in the upper layers of cortex (cingulate and sensory) where half-lives may be in the 10s of seconds and spatial reach may be up to 100 microns. The uptake in the outer cortical layers appears to be minimal and comparable with only nonspecific reuptake.

Participation of prostaglandins and bradykinin in the effects of angiotensin II and converting enzyme‐inhibition on sympathetic neurotransmission in vivo

We investigated the mechanism(s) by which angiotensin converting enzyme (ACE)-inhibition and angiotensin (Ang) II influence peripheral sympathetic neurotransmission in canine gracilis muscle in situ, with alpha-adrenoceptors either intact or irreversibly blocked by phenoxybenzamine. ACE-inhibition by ramiprilat reduced, and subsequent infusion of Ang II (30 ng kg-1 min-1 i.v.) markedly increased arterial plasma Ang-(1-8)octapeptide levels, basal muscle perfusion pressures and mean arterial pressure. Local intra-arterial bolus injection of Ang II caused marked vasoconstriction followed by vasodilation. This vasoconstrictor response was enhanced and the ensuing vasodilation was abolished following prostaglandin synthesis inhibition by diclofenac. The vasoconstrictor response to low frequency (0.5 Hz) sympathetic nerve stimulation was also enhanced by diclofenac. The nerve stimulation-evoked noradrenaline (NA) overflow was reduced by ramiprilat when alpha-adrenoceptors were blocked (-11 +/- 3%, P < 0.05), but increased when alpha-adrenoceptors were intact (+28 +/- 14%, P < 0.05). During ACE-inhibition, effective bradykinin receptor antagonism by HOE 140 reduced stimulation-evoked NA overflow irrespective of alpha-adrenoceptor blockade (i.e. by 25 +/- 5 and 20 +/- 3% in the absence and presence of alpha-adrenoceptor blockade, respectively, P < 0.01). Diclofenac increased stimulation-evoked NA overflow in the absence of alpha-adrenoceptor blockade (+ 19 +/- 4%, P < 0.05). IV infusion of Ang II failed to enhance stimulation-evoked NA overflow both before and after diclofenac.(ABSTRACT TRUNCATED AT 250 WORDS)

Heterogeneity of prejunctional neuropeptide Y receptors inhibiting noradrenaline overflow in the portal vein of freely moving rats

The effects of intraportal infusions of different doses of neuropeptide Y, its selective neuropeptide Y Y 1 receptor analogue, [Leu 31,Pro 34]neuropeptide Y, and the Y 2-selective C-terminal fragment, neuropeptide Y-(18–36), on basal and electrically evoked noradrenaline overflow in the portal vein as well as on mean arterial pressure and heart rate were investigated in permanently instrumented freely moving rats. Neuropeptide Y dose dependently (2–2000 ng/kg/min) attenuated the electrically evoked noradrenaline overflow and almost complete blockade was reached at the highest dose used. [Leu 31,Pro 34]Neuropeptide Y also dose dependently (20–20 000 ng/kg/min) attenuated the evoked overflow, reaching a maximum of 55% inhibition at the highest dose (20 000 ng/kg/min). Neuropeptide Y-(18–36) attenuated the evoked release only at 20 000 ng/kg/min (by 46%). Only at the highest dose did neuropeptide Y (2000 ng/kg/min) and [Leu 31,Pro 34]neuropeptide Y (20 000 ng/kg/min) significantly enhance mean arterial pressure and decrease heart rate and basal plasma noradrenaline levels, the latter two effects being due to the baroreceptor reflex. Neuropeptide Y-(18–36) did not influence these parameters at all doses used. The results indicate the presence of prejunctional neuropeptide Y Y 1 receptors, and possibly the coexistence of Y 1 and Y 2 receptors, in the portal vein of freely moving rats, which in conjunction are able to inhibit markedly electrically evoked noradrenaline overflow. Postjunctional neuropeptide Y receptors mediating an increase in blood pressure in the freely moving rat are solely of the Y 1 subtype.