Sympathetic vascular control of the pig nasal mucosa: (I) increased resistance and capacitance vessel responses upon stimulation with irregular bursts compared to continuous impulses

An in vivo model is described in which pentobarbital anaesthetized pigs were used to study the sympathetic nervous control of the nasal mucosal vascular bed. Changes in blood flow in the sphenopalatine artery (representing nasal blood flow) and in the volume of the nasal cavity (mainly reflecting blood content in venous sinusoids), upon electrical stimulation of the cervical sympathetic trunk, were recorded simultaneously. Single impulses (15V, 5 ms) reduced both the arterial flow and the volume of the nasal mucosa. The effects of nerve stimulation with a continuous train of impulses at 0.59, 2 and 6.9 Hz were compared with those caused by stimulation with the irregular bursting pattern, triggered by recorded human sympathetic vasoconstrictor nerve activity, with the same average frequencies. Both types of stimulation reduced nasal blood flow and volume, but the responses were significantly larger with burst stimulation at 0.59 Hz. The volume reduction was already maximal at 0.59 Hz while the blood flow response increased further higher frequencies. Local intra-arterial pretreatment with the α-adrenoceptor antagonist phenoxybenzamine significantly attenuated the flow and volume responses to single impulses, while clear-cut reductions in blood flow (by 40%) and volume (by 80%) remained, upon stimulation, at 6.9 Hz. Noradrenaline given intra-arterially caused a dose-dependent reduction in nasal blood flow and volume. The noradrenaline effects were blocked by phenoxybenzamine treatment. The results show that the pig nasal mucosa represents a model where both blood flow and volume changes can be studied in parallel in vivo. Furthermore, stimulation with the firing pattern of human vasoconstrictor nerves, i.e. irregular bursts, causes larger vascular responses in the pig nasal mucosa compared to a continuous stimulation. The large residual vascular responses to sympathetic nerve stimulation at high frequency after a-adrenoceptor blockage may be mediated by some other non-adrenergic transmitter substance(s).     

Sympathetic vascular control of the pig nasal mucosa (III): co-release of noradrenaline and neuropeptide Y

The overflows of noradrenaline (NA) and neuropeptide Y like immunoreactivity (NPYLI) and vascular responses upon sympathetic nerve stimulation were analysed in the nasal mucosa of pentobarbital anaesthetized pigs. In controls, a frequency-dependent increase in NA overflow was observed whereas detectable release of NPY-LI occurred only at 6.9 Hz. Parallel decreases in blood flow in the sphenopalatine artery and vein and in nasal mucosa volume (reflecting blood volume in the venous sinusoids) were observed. The laser Doppler flowmeter signal (reflecting superficial blood flow) increased upon low and decreased upon high frequency stimulation. Twenty-four hours after reserpine pretreatment and preganglionic decentralization, the NA overflow was abolished while a frequency-dependent release of NPY-LI occurred. Forty, 60 and 80% of the vasoconstrictor responses then remained upon stimulation with a single impulse, 0.59 and 6.9 Hz, respectively. Both the vasoconstriction and NPY-LI overflow, however, were subjected to fatigue upon repeated stimulation. In reserpinized animals release of NPY-LI and vasoconstrictor responses were larger upon stimulation with irregular bursts at 0.59 Hz compared to effects seen at stimulation with continuous impulses. Pre-treatment with the a-adrenoceptor antagonist phenoxybenzamine or the monoamine reuptake inhibitor, desipramine, enhanced NA overflow by 2–3 and 1.5 times at 0.59 and 6.9 Hz, respectively. Phenoxybenzamine significantly reduced the nerve-evoked vascular responses while the release of NPY-LI at 6.9 Hz was increased. Desipramine increased the functional responses but reduced the NPY-LI overflow. During tachyphylaxis to the vasoconstrictor effects of the stable adenosine 5′-triphosphate (ATP) analogue α-β-methylene ATP (mATP) in controls, the vasoconstrictor responses as well as the NA and NPY-LI overflow to nerve stimulation were unmodified. In reserpinized animals, however, the vascular responses and the overflow of NPY-LI were reduced after mATP tachyphylaxis. These data show that both NA and NPY are released upon sympathetic nerve stimulation in the nasal mucosa in vivo and this release seems to be regulated via prejunctional a-adrenoceptors. The lack of effect of mATP tachyphylaxis under control conditions makes it less likely that ATP serves as a major mediator of the large nonadrenergic vasoconstrictor component.     

Sympathetic vascular control of the pig nasal mucosa (2): Reserpine-resistant, non-adrenergic nervous responses in relation to neuropeptide Y and ATP

The possible occurrence of non-adrenergic mechanisms in the sympathetic vascular control of the nasal mucosa was studied in vivo using reserpine-treated pigs (1 mg kg-1, i.v., 24 h earlier) in combination with pharmacological blockade of alpha-adrenoceptors by local phenoxybenzamine (1 mg kg-1, i.a.) infusion. The nasal mucosal depletion (99%) of the content of noradrenaline (NA) in reserpinized animals was not influenced by preganglionic denervation while the depletion (44%) of neuropeptide Y (NPY) was prevented. Upon stimulation with single shocks, 25% of the arterial blood flow reduction and 47% of the nasal mucosal volume reduction (reflecting contraction of venous sinusoids) were still present after reserpine as compared with controls. In reserpinized animals, the vascular responses were slow developing and long-lasting, and about 60% remained at 0.59 Hz and more than 80% at 6.9 Hz. The vascular effects after reserpine were, however, subjected to fatigue, which may explain why phenoxybenzamine treatment still reduced the functional effects in the absence of NA. Local intra-arterial injections of NA, NPY and the metabolically stable adenosine-5'-triphosphate analogue alpha, beta-methylene ATP (mATP) caused reduction in both arterial blood flow and nasal mucosal volume. The C-terminal fragment of NPY (NPY 13-36) also induced nasal vasoconstriction although with a fivefold lower potency than NPY 1-36. Adenosine-5'-triphosphate caused a biphasic vascular effect with vasodilatatory actions at low doses and a short-lasting vasoconstriction followed by vasodilatation at very high doses (100-fold higher than the threshold response to mATP). In contrast to the response to NA, the long-lasting vascular effects of NPY and mATP were resistant to phenoxybenzamine treatment. In conclusion, although NA is likely to mediate most of the sympathetic vascular responses to low-frequency stimulation in the pig nasal mucosa, a large resistance and capacitance vessel component upon high-frequency stimulation seems to be non-adrenergic and mimicked by NPY rather than ATP.     

Release and vasoconstrictor effects of neuropeptide Y in relation to non-adrenergic sympathetic control of renal blood flow in the pig

The possible involvement of neuropeptide Y (NPY) in sympathetic control of renal blood flow was investigated in the pig in vivo. Exogenous NPY caused renal vasoconstriction with a threshold effect at an arterial plasma concentration of 164 pmol 6(-1). Stimulation of the renal nerves (0.59, 2 and 10 Hz) in control animals evoked rapid and frequency-dependent reduction in renal blood flow and overflow of NPY-like immunoreactivity (NPY-LI) and noradrenaline (NA) from the kidney, suggesting co-release from sympathetic nerves. Following the administration of the alpha- and beta-adrenoceptor antagonists phenoxybenzamine and propranolol, the vasoconstrictor response to exogenous NA was reduced by 98%, whereas that of NPY was unaltered. The response to nerve stimulation with 0.59 Hz was abolished, whereas relatively slowly developing reductions in renal blood flow by 7 and 28% were obtained upon stimulation with 2 and 10 Hz respectively. The nerve stimulation-evoked overflow of NA at 0.59 and 2 Hz, but not at 10 Hz and not that of NPY-LI, was enhanced after adrenoceptor blockade. Twenty-four hours after reserpine treatment (1 mg kg-1 i.v.) the contents of NPY-LI and NA in the renal cortex were reduced by 80 and 98% respectively. Sectioning of the renal nerves largely prevented the reserpine-induced depletion of NPY-LI, but not that of NA. Nerve stimulation of the denervated kidney with 2 and 10 Hz 24 h after reserpine treatment evoked slowly developing and long-lasting reductions in renal blood flow by 6 and 52% respectively. These responses were associated with overflow of NPY-LI, which was similar to and threefold higher than that observed in controls at 2 and 10 Hz respectively, while no detectable overflow of NA occurred. Repeated stimulation with 10 Hz resulted in a progressive fatigue of the vasoconstrictor response and the associated overflow of NPY-LI, giving a high correlation (r = 0.86, P less than 0.001) between the two parameters. It is concluded that NPY is a potent constrictor of the renal vascular bed. Furthermore, although NA is the likely transmitter mediating most of the responses to low to moderate nerve activation under control conditions, the data suggest that NPY may mediate the non-adrenergic reductions in renal blood flow evoked by high-frequency sympathetic nerve stimulation after reserpine treatment.     

The role of ATP in non-adrenergic sympathetic vascular control of the nasal mucosa in anaesthetized cats and dogs.

1. In anaesthetized cats and dogs, local intra-arterial injection of noradrenaline and alpha, beta-methylene adenosine 5'-triphosphate (mATP) reduced both nasal arterial blood flow and nasal mucosal volume (a measure of capacitance vessel function). The responses to mATP were not modified by pretreatment with the adrenoceptor antagonists phentolamine and propranolol or the purinoceptor antagonist suramin. The vascular effects of noradrenaline were not altered by suramin, but were virtually abolished by adrenoceptor antagonists. 2. After adrenoceptor blockade, frequency-dependent reductions in nasal arterial blood flow with sympathetic nerve stimulation were reduced by 25 and 39% in cats and dogs, respectively; whereas the volume response was reduced by 56% in cats and 54% in dogs. The remaining non-adrenergic sympathetic nerve-evoked vascular responses were not influenced by suramin. 3. During desensitization to mATP induced by local intra-arterial infusion for 5 min, the remaining non-adrenergic nasal blood flow and volume responses to sympathetic nerve stimulation were reduced in the dog but not in the cat. 4. It is suggested that both adrenergic and non-adrenergic mechanisms are involved in the sympathetic control of the nasal mucosa vascular bed of both species. Since desensitization to mATP markedly reduces the remaining non-adrenergic nasal vasoconstriction evoked by sympathetic nerve stimulation in the dog, ATP is a possible sympathetic mediator in the nasal vascular bed in this species.     

Possible involvement of neuropeptide Y in sympathetic vascular control of canine skeletal muscle

Sympathetic nerve stimulation (2 min, 2 and 10 Hz) increased perfusion pressure in the blood perfused canine gracilis muscle in situ after pretreatment with atropine, desipramine and beta-adrenoceptor antagonists. This vasoconstriction was accompanied by clear-cut increases in the overflow of endogenous noradrenaline (NA) at both frequencies and, at 10 Hz but not at 2 Hz, also of neuropeptide Y-like immunoreactivity (NPY-LI). The irreversible alpha-adrenoceptor antagonist phenoxybenzamine enhanced the nerve stimulation induced overflows of NA and NPY-LI five- to eightfold and threefold, respectively. The fractional overflows of NA and NPY-LI per nerve impulse were similar in response to the high-frequency stimulation, indicating equimolar release in relation to the tissue contents of the respective neurotransmitter. The maximal vasoconstrictor response elicited by 10 Hz was reduced by about 50% following a dose of phenoxybenzamine which abolished the effect of exogenous NA and the remaining response was more long-lasting. Local i.a. infusion of NPY evoked long-lasting vasoconstriction in the presence of phenoxybenzamine, while the stable adenosine 5(1)-triphosphate (ATP) analogue alpha-beta-methylene ATP was without vascular effects. Locally infused NPY reduced the nerve stimulation evoked NA overflow by 31% (P less than 0.01) at 1 microM in arterial plasma, suggesting prejunctional inhibition of NA release. In conclusion, NPY-LI is released from the canine gracilis muscle upon sympathetic nerve stimulation at high frequencies. There is nerve stimulation evoked vasoconstriction, which is resistant to alpha-adrenoceptor blockade. This may in part be mediated by NPY released together with NA from the sympathetic vascular nerves.     

Effects of cervical sympathetic nerve stimulation and neuropeptide Y (NPY) on cranial blood flow in the cat

Effects of cervical sympathetic nerve stimulation (SNS) at 10 Hz and intravenous infusion of neuropeptide Y (NPY), 10 and 100 pmol x kg body wt-1 x min-1 for 5 min, on regional blood flow in the cat were investigated with radioactive microspheres. Sympathetic nerve stimulation caused significant reductions in blood flows in the facial tissues including the eye. Alpha-adrenoceptor blockade with phenoxybenzamine and combined beta- and alpha-adrenoceptor blockade with propranolol and phenoxybenzamine abolished the effects of sympathetic nerve stimulation in most facial tissues except in the tongue, upper eyelid and masseter muscle. In most cranial tissues, neuropeptide Y reduced regional blood flow and increased vascular resistance. No effect of neuropeptide Y on vascular resistance was observed in the choroid. In the present study, evidence for a non-adrenergic component in sympathetic vasoconstriction was found in the tongue, upper eyelid and masseter muscle but not in the majority of feline facial tissues. Neuropeptide Y was a potent vasoconstrictor in many cranial tissues, while in parts of the uvea, the effects of neuropeptide Y were less pronounced.     

Effects of stimulation of cervical sympathetic trunks with various frequencies on the local cortical cerebral blood flow measured by laser Doppler flowmetry in the rat

The effects of electrical stimulation of cervical sympathetic trunks for 1-min duration at supramaximal intensity with various stimulus frequencies on local cortical cerebral blood flow were investigated in urethane-anesthetized rats. Electrical stimulation with low frequency (1-2 Hz) produced a significant increase in local cortical cerebral blood flow during the stimulation. The local cortical CBF reached 111% of the resting value during the stimulation at 10 Hz, and slightly decreased for about 30s after the end of stimulation. High-frequency stimulation (20-30 Hz) produced the short-term increase during the stimulation, which was followed by the dominant and long-lasting decrease, and the local cortical CBF reached 87% (at 30 Hz) of the resting value after the end of stimulation. The response of increase in flow was abolished by intravenous administration of beta adrenergic blocking agent (propranolol, 1.3 mg/kg i.v.), while the response of decrease in flow was abolished by alpha adrenergic blocking agent (phenoxybenzamine, 0.5 mg/kg i.v.).     

Nervous control of tracheal blood flow in the cat measured by the laser Doppler technique

The tracheal blood flow as determined by the laser Doppler technique was continuously monitored in anaesthetized cats. Electrical stimulation of the right superior laryngeal nerve caused an atropine-resistant increase in blood flow of the upper trachea. Unilateral vagal nerve stimulation at the cervical level in the presence of atropine induced a frequency-dependent increase in blood flow of the lower trachea. Intermittent stimulation with bursts of impulses at a high frequency resulted in a considerably larger blood flow increase than a continuous low frequency stimulation giving the same total number of impulses. The ganglionic blocking agent chlorisondamine abolished most of the vagally induced increase in tracheal blood flow when using low threshold parameters (2 V, 0.2 ms) presumably activating preganglionic nerves. High threshold stimulation (10 V, 5 ms) however, still resulted in an increased blood flow suggesting antidromic activation of sensory C fibres. Local mechanical irritation or chemical irritation by capsaicin also increased tracheal blood flow. Furthermore, local application of calcitonin gene-related peptide on to the mucosa caused a slowly developing, long-lasting increase in blood flow. Electrical stimulation of the cervical sympathetic trunk and local application of adrenaline reduced tracheal blood flow. In conclusion, vagal nerve stimulation induces an atropine-resistant increase in tracheal blood flow probably mainly by activating preganglionic parasympathetic nerves and possibly also by antidromic stimulation of C-fibre afferents.     

Interaction of sympathetic vasoconstriction and antidromic vasodilatation in the control of skin blood flow

 We studied the interaction between the vasoconstriction evoked by postganglionic sympathetic neurones (sympathetic vasoconstriction) and the vasodilatation mediated by small-diameter afferent neurones (antidromic vasodilatation) in hairless skin of anaesthetized rats kept under controlled conditions. In all animals both the lumbar sympathetic trunk (LST) and the ipsilateral dorsal root (DR) L5 were surgically exposed, sectioned and electrically stimulated using different protocols. This experimental approach results in the exclusive and selective activation of sympathetic efferents and primary afferents respectively. Blood flow responses were measured using laser Doppler flowmetry. Sectioning the LST resulted in a pronounced increase in cutaneous blood flow by 112±15% (mean±SEM, n=25) indicating that ongoing sympathetic vasoconstrictor activity had been abolished. When a brief antidromic vasodilatation was produced by DR stimulation with 10–15 pulses at 1 Hz with C-fibre intensity during a sustained sympathetic vasoconstriction, peak blood flow reached preconstriction levels at LST stimulation frequencies of ≤3 Hz. By contrast, antidromic vasodilatation was reduced at sympathetic stimulation frequencies of ≥5 Hz and absent when stimulating the LST with 20 Hz. A similar response characteristic was obtained when LST and DR stimulation were started simultaneously. Continuous DR stimulation with 0.1 Hz evoked a substantial increase in cutaneous blood flow by 38±10% (mean±SEM, n=8) to a new baseline level. When sympathetic vasoconstriction was elicited on this background DR stimulation, the responses were smaller at all sympathetic frequencies. However, the maximum decrease in blood flow was significantly smaller than the controls at LST stimulation with ≤3 Hz but not at higher frequencies. We conclude that sympathetic vasoconstriction and antidromic vasodilatation are competitive influences in the control of cutaneous blood flow. At low levels of cutaneous sympathetic vasoconstrictor activity, which probably prevail under resting conditions in the absence of cold stress, antidromic vasodilatation overrides sympathetic vasoconstriction. At high levels of cutaneous sympathetic activity, which may be reached in normal life under the conditions of severe cold, sympathetic vasoconstriction can suppress antidromic vasodilatation almost totally. Received: 24 April 1996 / Accepted: 3 September 1996     

Negative feed-back regulation of noradrenaline release by nerve stimulation in the perfused cat's spleen: differences in potency of phenoxybenzamine in blocking the pre- and post-synaptic adrenergic receptors

1. The effects of low concentrations of phenoxybenzamine (8.8 x 10(-10) to 2.9 x 10(-7)M) on responses and on noradrenaline overflow elicited by nerve stimulation were studied in the perfused cat's spleen.2. In the presence of 8.8 x 10(-10)M or 2.9 x 10(-9)M phenoxybenzamine there was a significant reduction in responses to nerve stimulation while the overflow of the transmitter did not increase at the two frequencies of stimulation employed: 5 and 30 Hz.3. In the presence of 2.9 x 10(-8)M or 2.9 x 10(-7)M phenoxybenzamine the responses to nerve stimulation were practically abolished and a significant increase in transmitter overflow was obtained at both frequencies of stimulation. The drug was more effective in increasing transmitter overflow at 5 Hz when compared with 30 Hz.4. The higher effectiveness of phenoxybenzamine in blocking the post-synaptic alpha-receptor when compared with the blockade of the presynaptic alpha-receptor that regulates transmitter release is compatible with the view that these two receptors are not identical.5. A second alternative for the difference in effectiveness of phenoxybenzamine is that both types of alpha receptors are identical, but the spare receptor capacity for the presynaptic adrenergic receptors is higher than that of the post-synaptic receptors.     

Comparison of the effects of stimulation of the sympathetic vasomotor nerves and the adrenal medullary catecholamines on the hind limb blood vessels of the rabbit

1. The responses to sympathetic nerve stimulation and to the adrenal medullary hormones have been studied in the hind limb vascular beds of the anaesthetized rabbit.2. Simultaneous measurements of femoral arterial blood pressure and of femoral venous blood flow indicate that stimulation of the sympathetic nerves decreases the calculated vascular conductance in both the intact and skinned hind limbs. Evidence is presented to show that these changes are due to vasoconstriction.3. The vasoconstriction in both skin and muscle vascular beds reaches a maximum at frequencies of stimulation around 15 Hz. No vasodilatation is obtained at any frequency of stimulation.4. The rabbit adrenal gland secretes only adrenaline during splanchnic nerve stimulation at frequencies between 3 and 60 Hz. The amounts liberated from both glands over this frequency range are 25-500 ng.kg body wt.(-1) min(-1).5. Intravenous infusions of adrenaline in concentrations similar to those liberated by the adrenal glands during splanchnic nerve stimulation, and of noradrenaline, cause only vasoconstrictor responses in skin and muscle.6. Simultaneous stimulation of the sympathetic nerves to the hind limb and infusion of adrenaline in quantities that could be liberated by splanchnic nerve stimulation at equivalent frequencies shows that the vasoconstrictor effects exerted by the individual components are additive, though the effects produced by the direct sympathetic nerve supply overshadow those produced by the catecholamine.7. The results are discussed in the context of the possible vascular role of the adrenal medullary hormones in the rabbit.     

Influence of renal nerve activity on arteriolar resistance,ultrafiltration dynamics and fluid reabsorption

In anaesthetized 300 g rats, the influence of sympathetic nerve activity on the renal hemodynamics, glomerular filtration and fluid reabsorption was studied with direct stimulation at frequencies of 2 Hz and 5 Hz. The single nephron plasma flow at control conditions was 164 nl/min decreasing to 138 nl/min during 2 Hz and 68 nl/min during 5 Hz, reaching complete glomerular ischemia at about 10 Hz. At 2 Hz, the pressure drop over the two arterioles remained essentially unchanged, indicating an equal response to sympathetic discharge. At higher frequencies the afferent tone showed a more marked increase. The glomerular ultrafiltration decreased in parallel to the blood flow. The filtration fraction remained thereby constant at about 0.33. The fractional proximal fluid reabsorption up to the puncture site in early distal tubules showed a clear increase; the Tf/P-Inulin increasing from 6.0 to 7.1 and 7.2 for 2 Hz and 5 Hz, respectively. The absolute reabsorption decreased, however, and indeed not far from the decrement in glomerular filtration.It is concluded that sympathetic nerve activity acts in the direction of fluid conservation, by reducing the glomerular filtration and increasing the fractional reabsorption. The hemodynamic effects will play the dominant role even at 2 Hz stimulation.     

Stimulation of lumbar sympathetic trunk produces vasoconstriction of the vasa nervorum in the sciatic nerve via alpha-adrenergic receptors in rats.

The effects of repetitive electrical stimulation of a lumbar sympathetic trunk (LST) for 30 s at various frequencies and supramaximum intensity on the nerve blood flow in a sciatic nerve were studied by laser Doppler flowmetry in anesthetized Fischer-344 male rats. The response was biphasic; i.e. an initial increase and then a decrease. The maximum mean increase after 2 Hz stimulation was 22 +/- 8%, while the maximum mean decrease after 20-50 Hz stimulation was 79 +/- 3%, of the prestimulus control level. The initial increase, which was greater at lower frequencies and existed even after local sympathetic denervation, was passive, and was caused by the systemic pressor response to LST stimulation. The decrease, which was nearly abolished by an i.v. alpha-adrenergic blocker, phentolamine (10 mg/kg), resulted from vasoconstriction in the vasa nervorum, mainly via activation of alpha-adrenergic receptors.     

An electrophysiological analysis of the uptake of noradrenaline at sympathetic nerve terminals

1. An electrophysiological analysis has been made of the uptake of NAd in the sympathetic nerve terminals of the isolated vas deferens of the mouse. The amplitude of the excitatory junction potentials (e.j.p.s) recorded intracellularly in smooth muscle cells was taken as a measure of the NAd output per impulse from the terminals of sympathetic axons.2. Neuronal uptake blockers (desipramine and cocaine) greatly depressed the amplitude of all e.j.p.s after the first in a short train (< 100) at high frequencies (>/= 1 Hz).3. Blocking neuronal uptake did not affect the time course of decline in amplitude of the e.j.p. during long trains of stimulation over several minutes, apart from the immediate depression in the e.j.p. following the first few impulses.4. The time course of decline of the e.j.p. amplitude during continual stimulation, when both neuronal uptake and synthesis was blocked, was similar to that when only synthesis was blocked, apart from the immediate depression following the first few impulses.5. Phenoxybenzamine reversed the normal depression in e.j.p. amplitude observed at high frequencies (>/= 1 Hz) to facilitation. This facilitation lasted for several minutes of high frequency stimulation.6. A model has been proposed of the sympathetic nerve terminal, in which NAd is released by each nerve impulse in a train from a small pool in the nerve terminal, which is principally replenished by uptake of the NAd released by the immediately preceding impulses in the train. The pool is replenished to a less extent by transmitter located in two stores in the terminal which are in turn replenished by transmitter synthesis.     

The role of sympathetic efferent activity in the regulation of brain temperature

The role of nasal heat exchange in the control of brain temperature has been studied in cats, pigs, ducks and rabbits during acute experiments under general anaesthesia. Nasal air flow at physiological rates caused hypothalamic temperature to fall at beween 0.2 and 0.5°C/min in cats, pigs and ducks, which all have arterial rete systems that can cool blood flowing to the brain, but not in rabbits, which lack an arterial rete. Bilateral stimulation of cervical sympathetic trunks reduced or abolished the brain cooling effect of nasal air flow in cats, pigs and ducks. After a period of airflow during which brain cooling was reduced by sympathetic stimulation, the end of stimulation was sometimes followed by marked and rapid brain cooling, indicating re-perfusion through ischaemic cooled tissues. Cervical sympathetic stimulation caused a reduction in resistance to nasal airflow in all species studied, by inducing vasoconstriction and shrinkage of the nasal mucosa. In species with well-developed arterial retia, the effect of cervical sympathetic stimulation in regulating nasal cooling of the brain is probably mediated by controlling blood flow through the nasal mucosa. Although this vascular control also occurs in rabbits, they cannot selectively cool the brain and sympathetic stimulation has no effect on rabbit brain temperature.     

Guanethidine-sensitive release of neuropeptide Y-like immunoreactivity in the cat spleen by sympathetic nerve stimulation

Splenic nerve stimulation (10 Hz for 2 min) caused a perfusion-pressure increase, a volume reduction and an increase in the output of neuropeptide Y-like immunoreactivity (NPY-LI) from the isolated blood-perfused cat spleen. Gel-filtration HPLC analysis revealed that plasma NPY-LI collected during nerve stimulation was similar to the NPY-LI in the spleen and synthetic porcine NPY. Combined propranolol and phenoxybenzamine pretreatment enhanced NPY output upon nerve stimulation by about 60%. Forty percent of the perfusion-pressure increase and 25% of the volume reduction seen during control stimulations remained after adrenoceptor blockade. Guanethidine abolished the release of NPY-LI, the perfusion-pressure increase and the volume reduction normally seen upon splenic nerve stimulation. Infusion of synthetic porcine NPY caused a long-lasting increase in perfusion pressure and a relatively moderate volume reduction. Noradrenaline (NA) both increased perfusion pressure and induced a marked volume reduction. The NPY effects were resistant to adrenoceptor antagonists in doses which abolished the NA response. In conclusion, the present data show that NPY-LI is released upon sympathetic nerve stimulation by a guanethidine-sensitive mechanism. Furthermore, the sympathetic response is partially resistant to adrenoceptor antagonists and NPY has powerful vasoconstrictor effects. This provides further evidence for a role of NPY in sympathetic vascular control.     

Complementary role of vasoactive intestinal polypeptide (VIP) and acetylcholine for cat submandibular gland blood flow and secretion I. VIP release

The effects of parasympathetic and sympathetic nerve stimulation on VIP release in relation to blood flow and secretion were studied in the cat submandibular salivary gland. Parasympathetic nerve stimulation caused a marked VIP overflow (over thousand fold increase in VIP output) into the venous effluent from the gland which was simultaneous with profuse salivation and an about 10–15 fold increase in blood flow. The VIP output was dependent on the stimulation frequency, the duration of the stimulation period as well as the glandular blood flow. At 15 Hz maximal VIP output (about 4 fmol per impulse) was obtained after about 5 min of stimulation simultaneously with the maximum of the maintained phase of vasodilation. About 50 pmol VIP was recovered in the venous effluent from the gland during 1 h of maximal nerve stimulation. The VIP output after 1 h, was only about 20% of maximal, however, suggesting that the storage reserves and/or resupply of VIP might be running out. Under physiological conditions (frequencies ≤ 6 Hz) it was estimated that the axonal transport mechanism should be sufficient for replacement of VIP. At lower frequencies (2 and 6 Hz) the VIP output was parallel to vasodilation and secretion, while at a high frequency (15 Hz) a much more pronounced VIP output was seen. The increased overflow at 15 Hz may either be due to an actual increase in release or to a saturation of local VIP inactivating mechanisms. When stimulated simultaneously, the parasympathetic vasodilator mechanism seemed much more potent than sympathetic vasoconstriction. Since VIP may be present in cholinergic neurons, data from the literature concerning acetylcholine release are discussed in relation to the observed VIP output.     

Blood flow and oxygen consumption in skeletal muscle during sympathetic stimulation

We studied the effects of physiological rates (0-4 Hz) of sympathetic stimulation on blood flow and oxygen consumption of extensor digitorum longus muscles isolated from anesthetized dogs. Observations were made with the preparation at rest and during isometric twitch exercise at 1 and 4 Hz produced by somatic nerve stimulation. Graded increases in sympathetic stimulation rate resulted in graded and sustained reductions in muscle blood flow in all cases. A given rate of sympathetic stimulation reduced muscle blood flow by nearly the same absolute amount regardless of muscle exercise rate. Consequently the curve relating muscle blood flow to muscle oxygen consumption was progressively shifted downward in a parallel fashion with graded increases in sympathetic stimulation rate. Sympathetic stimulation at 0.5 and 1 Hz reduced muscle oxygen consumption during 4-Hz exercise but failed to do so during rest or 1-Hz exercise. Thus even during heavy exercise, local metabolic mechanisms do not override sympathetic vasoconstriction sufficiently to prevent the latter from limiting muscle oxygen consumption. In addition, the functional consequences of sympathetic activation appear to be greater for heavily exercising muscle than resting muscle.     

An electrophysiological analysis of the storage and release of noradrenaline at sympathetic nerve terminals

1. An electrophysiological analysis has been made of the storage and release of noradrenaline (NAd) in the sympathetic nerve terminals of the isolated vas deferens of the mouse. The amplitude of the excitatory junction potentials (e.j.p.s) recorded intracellularly in smooth muscle cells was taken as a measure of the NAd output per impulse from the terminals of sympathetic axons.2. During short trains of impulses (< 100), the amplitude of the e.j.p. increased with successive impulses at the beginning of a train, and then either continued to increase until a steady-state amplitude was reached (frequencies < 1 Hz), or decreased until a depressed steady amplitude was reached (frequencies > 1 Hz).3. During trains of impulses lasting for several minutes, the amplitude of the e.j.p. continually declined (frequencies > 1 Hz) until a steady-state amplitude was reached after 8 min of stimulation. This steady-state amplitude is smaller, the higher the frequency of stimulation.4. During short trains of impulses in the presence of high magnesium solutions, the amplitude of successive e.j.p.s increased until a steady state was reached, no matter what the frequency of stimulation. This growth of the e.j.p. amplitude during a train could be quantitatively predicted in terms of the linear summation of the individual facilitatory effects introduced by each impulse in the train.5. During trains of impulses lasting for several minutes, in the presence of a NAd synthesis blocker, the amplitude of the e.j.p. continually declined along a curve which could be described as the sum of two exponential components: one with a time constant of 1 min and the other of 10 min.6. These results suggest that NAd is released from a small pool of transmitter in sympathetic nerve terminals, which is replenished from two stores, which are in turn replenished by the synthesis of new NAd.