Neural organization of the viscero-cardiac reflexes

The reflex responses evoked in the postganglionic nerves to the heart were tested in chloralose-anaesthetized cats. Electrical stimulation of the A delta afferent fibres from the left inferior cardiac nerve evoked spinal and supraspinal reflex responses with the onset latencies of 36 ms and 77 ms respectively. The most effective stimulus was a train of 3-4 electrical pulses with the intratrain frequency of 200-300 Hz. Electrical stimulation of the high threshold afferent fibres (C-fibres) from the left inferior cardiac nerve evoked the reflex response with the onset latency of 200 ms. The C-reflex was present in intact animals and disappeared after spinalization. The most effective stimulus to evoke this reflex was a train of electrical pulses delivered at a frequency of 1-2 Hz with an intratrain frequency of 20-30 Hz. The most prominent property of the C-reflex was its marked increase after prolonged repeated electrical stimulation. We conclude that: (1) viscero-cardiac sympathetic reflexes may be organized at the spinal and supraspinal level; (2) viscero-cardiac sympathetic reflexes evoked by stimulation of the A delta and C afferent fibres from the left inferior cardiac nerve have different central organization.     

Supraspinal regulation of spinal reflex discharge into cardiac sympathetic nerves

(1) In chloralose anaesthetized cats, reflex responses were recorded in inferior cardiac nerves following stimulation of intercostal nerves and hind limb afferent nerves. (2) In 80% of cats, a long latency reflex response alone was recorded, whereas, in the others, a short and long latency response was present to intercostal nerve stimulation. (3) In cats displaying only a long latency somatocardiac reflex response, damage to the ventral quadrant of the ipsilateral cervical spinal cord, through which runs a bulbospinal inhibitory pathway, resulted in the appearance of shorter latency reflexes to intercostal nerve stimulation. Lesions elsewhere in the cervical cord did not do this. (4) The characteristics of the early responses indicated that they were somatosympathetic reflexes and not dorsal root reflexes. (5) The early reflexes remained and the late reflex disappeared on subsequent complete transection of the spinal cord. The early reflexes were therefore spinal reflexes, and suppressed in the animal with cord intact. (6) Lesions at C4, which included a contralateral hemisection and a section of dorsal columns extending into the dorsal part of the lateral funiculus, abolished the inhibition of a sympathetic reflex that followed stimulation of some somatic afferent nerve fibres. These sections did not release the spinal reflex. Therefore, this reflex inhibition was not responsible for the suppression of the spinal somatosympathetic reflex. (7) The descending inhibitory influence on the segmental reflex pathway was not antagonized by strychnine, bicuculline or picrotoxin. (8) The possibility is discussed that the spinal reflex pathway into cardiac sympathetic nerves is tonically inhibited by a bulbospinal pathway originating from the classical depressor region of the ventromedial reticular formation.     

Tonic descending inhibition of the spinal cardio-sympathetic reflex in the cat

Electrical stimulation of the left inferior cardiac nerve elicited a two-component reflex potential (spinal and supraspinal reflexes) in the ipsilateral white ramus T3 from which recordings were made in chloralose-anaesthetised cats. Reversible interruption of all spinal pathways achieved by cooling the spinal cord at C2/C3 produced an enhancement of the spinal reflex and abolished the supraspinal reflex, the latter usually being the more prominent reflex potential prior to spinal cord block. The spinal cord block-induced increase in the amplitude of the spinal reflex was, however, less than the increase observed during stimulation of the somatic intercostal nerve T4. Recordings of the afferent volley following cardiac nerve stimulation and analysis of the stimulus-reflex response relationship in neuraxis-blocked cats indicated that the spinal reflex as determined here was activated by A delta afferent fibres. However, if stimulus strength was raised above C-fibre threshold, spinal cord block revealed in addition a late spinal reflex response. In some cases, the appearance of this late potential was accompanied by a secondary decline of the earlier spinal reflex potential, possibly indicating C-fibre-mediated afferent inhibition. Neither baroreceptor activation nor denervation had any effect on spinal reflex amplitudes. Pharmacologically, clonidine given i.v. to cats with a blocked neuraxis reduced the spinal reflex amplitudes to pre-block values, an action which could be antagonised by the subsequent administration of the alpha 2-adrenoceptor antagonist rauwolscine. When given to non-pretreated cats with intact neuraxis, however, neither rauwolscine nor its analog yohimbine were capable of inducing a persistent release from tonic inhibition. The results suggest that both purely visceral and somato-visceral reflexes are subject to tonic descending inhibition, but they do not support the hypothesis that a catecholamine is the responsible transmitter mediating this inhibition.     

Longitudinal distribution of negative cord dorsum potentials following stimulation of afferent fibres in the left inferior cardiac nerve

Cord dorsum potentials were recorded along the spinal cord following electrical stimulation of afferent fibres of the left inferior cardiac nerve in chloralose anaesthetized cats. The potentials were more pronounced in spinal than in intact cats. Afferent fibres which generated cord dorsum potentials in the cervical spinal cord were localized mainly in T2 and T3 and to a smaller extent in C8 and T1 dorsal roots. The responses consisted of two waves: with short (7.0 ms; N3 wave) and long (56 ms; N4 wave) latency to the onset of potentials. N3 and N4 waves were generated by group III and group IV afferent fibres, respectively. The N3 wave was maximal at C8 and T1 spinal cord level and could be detected at least 5-6 segments rostrally from the level of afferent input responsible for its generation. The N4 wave could be detected at least 4 segments rostrally from its afferent fibre input. We conclude that afferent fibres from the left inferior cardiac nerve activate neurones in the cervical spinal cord. The implications of such finding are discussed.     

Action of delta 9 tetrahydrocannabinol on the central cardiovascular regulation : mechanism and localization]

Delta9-tetrahydrocannabinol (30-300 mug.kg-1 i.v.) induced in cats and dogs a decrease in blood pressure and heart rate. This decrease appears to be centrally mediated. In fact, the splanchnic and cardiac discharges were reduced in intact animals as well as in debuffered cats ruling out a reflexly mediated action. The mechanism of this central decrease in the sympathetic tone appears to be different from the mechanism of the reduction induced by clonidine or by narcotic analgesics agents. In fact, piperoxan (1 mg.kg-1 i.v.), an alpha adrenoceptor blocking agent, antagonized or reversed the centrally mediated reduction in the sympathetic tone induced by clonidine or L-dopa, but did not change the effects of narcotic analgesic agents and of delta9-tetrahydrocannabinol. Naloxone (30 mug.kg-1 i.v.) prevented or reversed the cardiovascular effects of fentanyl and the reduction in splanchnic discharges induced by this agent, but no change was found after naloxone in the effects of clonidine or delta9-tetrahydrocannabinol. The pressor response to high frequency stimulation of the medulla oblongata was abolished by small doses of delta9-tetrahydrocannabinol. This agent did not reduce the pressor response to stimulation of the posterior hypothalamus induced by supramaximal stimulation and did not alter the hypertensive effect induced by stimulation of the cervical spinal cord. Medulla oblogata appears therefore to be the main site of action.     

Characteristics of sympathetic reflexes evoked by electrical stimulation of phrenic nerve afferents.

In chloralose-anaesthetized cats, sympathetic reflex responses were recorded in left cardiac and renal nerve during stimulation of afferent fibres in the ipsilateral phrenic nerve. In cardiac nerve, a late reflex potential with a mean onset latency of 75.6 +/- 13.8 ms was regularly recorded which, in 20% of the experiments, was preceded by an early, very small reflex component (latency between 35 and 52 ms). In contrast, in renal nerve only a single reflex component after a mean latency of 122.1 +/- 13.1 ms was observed. Bilateral microinjections of the GABA-agonist muscimol into the rostral ventrolateral medulla oblongata resulted in a nearly complete abolition of sympathetic background activity and in an 88% reduction of the late reflex amplitude with only small effects on the latency of the evoked potentials. Under this condition, an early reflex component was never observed to appear. After subsequent high cervical spinalization, the residual small potentials which persisted after bilateral muscimol injections were completely abolished and in cardiac nerve an early reflex potential with a mean latency of 45 +/- 10 ms was observed in all but one experiment. The early reflex was therefore referred to as a spinal reflex component which, however, is suppressed in most animals with an intact neuraxis. In the renal nerve a spinal response was only observed in one experiment after spinalization. The results suggest that sympathetic reflexes evoked by stimulation of phrenic nerve afferent fibres possess similar spinal and supraspinal pathways as previously described for somato-sympathetic and viscero-sympathetic reflexes.(ABSTRACT TRUNCATED AT 250 WORDS)     

The relationship between propagated contractions and pseudoaffective changes in blood pressure in response to intestinal distension

We investigated the relationship between changes in small intestinal motility and changes in blood pressure and heart rate in response to intestinal distension. Rats were maintained under stable anaesthesia with alpha-chloralose, and jejunal motility, blood pressure and heart rate were recorded. Pressure changes during propagated contractions of the circular muscle were recorded in the jejunum when the intraluminal pressure was maintained at 10 mmHg. Raising the pressure in 10 mmHg increments from 10 mmHg to 40 mmHg increased the frequency of propagated contractions from 0.30 +/- 0.06 min-1 (mean +/- SEM) to 1.29 +/- 0.09 per min. In contrast, amplitudes of contractions above baseline pressure decreased from 19.5 +/- 0.6 mmHg to 7.8 +/- 0.5 mmHg. Simultaneously, blood pressure and heart rate were both increased. Pretreatment of rats with capsaicin, or severing the mesenteric nerves acutely, prevented these cardiovascular responses, but did not influence the changes in propagated activity caused by distension. Propagated contractions were blocked by hexamethonium (10 mg kg-1, intravenously [i.v.]) and by local application of 2% lidocaine, but propulsion was unchanged by hyoscine (1 mg kg-1, i.v.). Phentolamine (1 mg kg-1, i.v.) increased the frequency of propagated contractions. The methods described in this work allow the effects of drugs on intrinsic intestinal reflexes to be distinguished from their effects on extra-intestinal, pseudoaffective reflexes. In addition, unlike other experiments using anaesthetized rats, blood pressure increased in response to distension, as it does in mammals that are not anaesthetized. The experiments demonstrate that the neural pathways for propagated contractions that rely on intrinsic nerve circuits, including intrinsic primary afferent neurones, and the neural pathways for extrinsic reflexes that signal pain or discomfort in the intestine, which involve capsaicin-sensitive spinal afferent neurones, are independent.     

Selective augmentation of visual pathways by morphine in α-chloralose-anesthetized cats

Morphine sulfate, 0.1 to 5.0 mg/kg, was tested for effects on afferent sensory activity in acutely prepared α-chloralose-anesthetized cats. Morphine increased the responsiveness of the primary projection tracts of the visual system to electrical stimulation of the optic chiasm but did not augment responses in the primary somatosensory system to stimulation of the radial nerve. Preferential sensory augmentation was observed in cortical areas which exhibited responses to both sensory modalities. Anterior marginal association activity evoked by stimulation of the optic chiasm was augmented by morphine but activity elicited by radial nerve stimulation was not. In cats anesthetized with dial-urethane or midcollicularly transected, morphine was without significant effect on the visual afferent pathways. A possible brain stem site for morphine facilitation of visual tract responsiveness is discussed.     

Actions of morphine and enkephalins on the internal anal sphincter of the cat: relevance for the physiological role of opiates

The effects of Leu-enkephalin, Met-enkephalin and morphine on the electrical activity of the internal anal sphincter were studied in anesthetized spinalized cats and in vitro on sphincteric muscle strips. All the effects of enkephalins and morphine were antagonized by naloxone (2 mg/kg, i.v. in vivo and 10(-6)M in vitro). In vivo, the enkephalins (0.01 mg/kg i.v.) and morphine (2 mg/kg, i.v.) decreased the amplitude of the excitatory responses evoked in the sphincter by stimulation of the hypogastric nerves. Opiates presumably act on the sympathetic nerve endings by reducing the release of noradrenaline. In vitro, the enkephalins (10(-6)M) and morphine (10(-6)M) had a similar inhibitory effect, indicating that opiates act, at least partly, at intramural level. In vivo, the enkephalins and morphine produced an inhibition of the spontaneous electrical activity of the internal anal sphincter. This inhibition occurs also in vitro; it is thus due to a peripheral effect of opiates acting either directly on the sphincteric smooth muscle cells, or through the nervous structures controlling sphincteric motility. In addition, the distribution of nerves containing enkephalin-like immunoreactivity, using whole mount preparations of cat internal anal sphincter, indicates that this area is supplied with a dense Leu- and Met-enkephalinergic innervation. Met- and Leu-enkephalin-like immunoreactive axons were detected within the circular and longitudinal muscles.     

Evidence that the opiate receptors of the substantia gelatinosa contribute to the depression, by intravenous morphine, of the spinal transmission of impulses in unmyelinated primary afferents

In barbiturate anaesthetized cats, dorsal horn neurones were excited by electrical stimulation of the common tibial nerve. The numbers of action potentials evoked by excitation of C fibres were depressed by analgesic doses of morphine (1–4 mg/kg i.v.). Naloxone, administered electrophoretically in the substantia gelatinosa, fully reversed the inhibitory action of morphine. The results suggest that opiate receptors in the substantia gelatinosa play a role in morphine analgesia.     

Separation of the medullo-spinal descending pathway for somatic and autonomic outflow in the cat

The present study investigated differences between vestibulo-somatic and vestibulo-sympathetic reflexes, along with differences between somatic and autonomic spino-bulbo-spinal (SBS) reflexes in chloralose-urethane anesthetized cats. Electrical stimulation was applied to the vestibular nerve (V) for a duration of 0.3 ms. The potential responses in the sympathetic renal nerve (RN) and somatic lumbar nerve were recorded simultaneously. Responses were recorded for a variety of conditioning stimulus to testing stimulus intervals, and the results were plotted to form a recovery curve. The recovery curve for the test response from the somatic nerve was very different from that of the sympathetic nerve. Following transection of the lateral part of the thoracic cord, in the case of the sympathetic renal nerve, recorded responses were still present on vestibular and lumbar nerve stimulation, whereas in the case of the vestibulo-somatic and somatic SBS reflexes, the reflex response had disappeared after transection. These findings suggest that sympathetic and somatic reactions as a result of vestibular stimulation have different descending pathways in the spinal cord, and that their physiological characteristics are different.     

Afferent stimulation frequency modulates GABAergic phenomena in the spinal cord: reversal by benzodiazepine antagonists

Switching from a low (0.5 Hz) to a higher (5 Hz) frequency repetitive stimulation of hindlimb muscle nerve afferents reduced GABA-mediated dorsal root potentials and dorsal root reflexes in the lumbosacral cord of spinal cats. Benzodiazepine receptor antagonists flumazenil and Ro 15-3505 in a very low dose (0.03 mg/kg i.v.) reversed this effect suggesting a stimulation-coupled release of an endogenous benzodiazepine receptor ligand down-regulating GABAA-receptors in the spinal cord.     

Analysis of reflex activity in cardiac sympathetic nerve induced by myelinated phrenic nerve afferents

Electrical stimulation of the phrenic nerve afferents evoked excitatory responses in the right inferior cardiac sympathetic nerve in chloralose-anaesthetized cats. The reflex was recorded in intact and spinal cats. The latency and threshold of the volley recorded from the phrenic nerve as well as of the cord dorsum potentials evoked by electrical stimulation of the phrenic nerve indicated that group III afferents were responsible for this reflex. The phrenicocardiac sympathetic reflex recorded in intact cats was followed by a silent period. The maximum amplitude of the reflex discharges was 800 microV, the latency was 83 ms and the central transmission time 53 ms. Duration of the silent period lasted up to 0.83 s. In spinal cats the reflex was recorded 5.5-8 h after spinalization. The maximum amplitude of the spinal reflex discharges ranged from 22 to 91 microV and the latency from 36 to 66 ms.     

Some pharmacological effects of delta-sleep-inducing peptide (DSIP)

The synthetic nonapeptide DSIP was studied in rabbits and cats under normal conditions and under conditions of disturbed sleep. In other experiments, the effect of the oligopeptide on withdrawal jumping provoked by naloxone in morphine-dependent mice was studied. In rabbits, DSIP at 25 micrograms X kg-1 i.v. and 1 mg X kg-1 s.c. augmented spindle-dominated, light nonREM sleep and prevented hyposomnia after a stressful situation. In cats, 25 micrograms X kg-1 i.v. and 100 micrograms X kg-1 s.c. preferentially augmented REM sleep and abolished the sleep suppressant effect of morphine. In morphine-dependent mice, 25.5 micrograms X kg-1 i.v. as well as doses beyond 85 micrograms X kg-1 s.c. attenuated naloxone-induced withdrawal jumping. In most experimental situations, indications for bell-shaped dose-response curves of DSIP were found.     

Axial muscle EMG responses evoked by cutaneous flank nerves in the female rat: effects of spinal transection, steroid hormones, and anesthesia.

In the lateral longissimus muscle (LL) of ovariectomized, female rats anesthetized with low surgical doses of urethane (1.0 g/kg), cutaneous reflexes with similar EMG and response patterns could be elicited from CNS-intact rats and from rats 24 h after complete thoracic spinal cord transection. The probability of eliciting a response to contralateral cutaneous nerve stimulation alone is much lower in rats with complete spinal transections compared to CNS-intact rats. For both CNS-intact and spinal-transected rats, responses to ipsilateral cutaneous nerve stimulation had a shorter latency and required significantly less current on average than responses to contralateral stimulation. The respective currents for eliciting threshold responses to ipsi- and contralateral stimulation are less for CNS-intact than spinal-transected rats. For both CNS-intact and spinal-transected rats, responses to bilateral cutaneous nerve stimulation were inconsistent in the same animal from run to run. With the variability of response at this anesthetic level, no consistent effects of progesterone (acute, i.v.) or estrogen (acute, i.v. and pretreatment, s.c.) were observed in spinal-transected rats. Intravenous progesterone reduced early, unilateral responses in CNS-intact rats anesthetized with 1.0 g of urethane/kg. For both CNS-intact and spinal-transected rats, additional anesthesia during EMG recording produced a gradual decline in response magnitude which could be recovered with a modest increase in stimulus intensity. However, spinal-transected rats appear to require less anesthesia to reduce comparable responses. The results suggest that supraspinal input is especially effective for facilitating contralateral cutaneous reflexes in back muscles, whereas it contributes more equally with afferent input and segmental circuitry to the efficacy of ipsilateral cutaneous reflexes.     

Differential modulation of withdrawal reflexes by a cannabinoid in the rabbit

Inhibition of spinal and trigeminal withdrawal reflexes by morphine and by the cannabinoid agonist HU 210 has been studied in anaesthetized and in decerebrated rabbits. In intact, pentobarbitone-anaesthetized animals, the jaw-depressor reflex (JDR) evoked by stimulation of the tongue, and the reflex elicited in the ankle flexor tibialis anterior (TA) by stimulation of the toes were inhibited to the same extent by morphine (1-30 mg kg(-1) i.v. cumulative). In spinalized, anaesthetized rabbits morphine depressed the JDR to the same level as in non-spinal preparations, but the effect of the opioid on the TA reflex was significantly reduced. All effects of morphine were reversed by naloxone (0.25 mg kg(-1), i.v.). In anaesthetised intact animals, HU 210 depressed the JDR at a dose of 100 nmol kg(-1) i.v. cumulative, reduced reflexes evoked in the knee flexor muscle semitendinosus (ST) by stimulation at the toes at a dose of 30 nmol kg(-1) i.v. cumulative, but had no consistent or significant effects on the TA reflex to toe stimulation. The same results were obtained in spinalized, anaesthetised animals. In decerebrated, spinalized rabbits with no anaesthesia, HU 210 (30 nmol kg(-1)) depressed both ST and TA reflexes evoked by toe stimulation. These data reveal that trigeminal and spinal withdrawal reflexes are equally sensitive to morphine provided the spinal cord is intact, suggesting that at least part of the action of systemic morphine is due to activation of descending inhibition. The present results also show for the first time that cannabinoid agonists can inhibit trigeminal withdrawal reflexes. HU 210 had differential effects on the three reflexes studied depending on the presence or absence of anaesthesia. This is the first occasion on which we have found pharmacological distinctions between withdrawal reflexes, and indicates that spinal sensorimotor processing is more heterogeneous than has been suspected previously.     

Spinal 5-HT2A receptors regulate cutaneous sympathetic vasomotor outflow in rabbits and rats; relevance for cutaneous vasoconstriction elicited by MDMA (3,4-methylenedioxymethamphetamine, "Ecstasy") and its reversal by clozapine

We determined whether spinal 5-hydroxytryptamine 2A (5-HT2A) receptors contribute to resting cutaneous sympathetic vasomotor activity, and to increases in activity elicited by electrical stimulation of the medullary raphe/parapyramidal region, and whether these receptors are involved in the cutaneous vasoconstricting action of systemically administered MDMA (3,4-methylenedioxymethamphetamine, "Ecstasy") and its reversal by clozapine. Experiments were conducted in urethane-anesthetized rabbits and rats. Administration of the 5-HT2A antagonist, trans-4-((3Z)3-[(2-Dimethylaminoethyl)oxyimino]-3-(2-fluorophenyl)propen-1-yl)-phenol, hemifumarate (SR 46349B, 0.1 mg/kg, i.v.) inhibited resting ear pinna sympathetic vasomotor nerve discharge and reduced the extent to which raphe/parapyramidal electrical stimulation caused ear pinna (rabbit) and tail (rat) artery blood flow to fall. Clozapine (0.125-0.5 mg/kg, i.v.) also reduced the fall in ear pinna blood flow elicited by raphe/parapyramidal stimulation. In rabbits, after inactivation of raphe/parapyramidal function by local microinjection of muscimol (1 nmol in 100 nl), the 5-HT2A agonist R(-)-1-(2,5-dimethoxy-4-iodophenyl)-2-aminopropane hydrochloride (DOI, 50 microg/kg, i.v.) increased ear pinna sympathetic nerve activity from 3+/-2% to 129+/-5% of pre-muscimol levels (P<0.01, n=6), and this increase was abolished by section of the ipsilateral cervical sympathetic nerve trunk. MDMA (2 mg/kg, i.v.) after muscimol decreased ear pinna blood flow from 33+/-10 to 2+/-1 cm/s (P<0.01, n=5) and increased ear pinna sympathetic nerve activity from 8+/-4% to 120+/-41% of pre-muscimol levels (P<0.01, n=6). The MDMA-elicited increase in nerve activity was abolished by SR 46349B. Data suggest that spinal 5-HT2A receptors contribute to sympathetically induced cutaneous vasoconstriction regulated by raphe/parapyramidal neurons in the brainstem, and that these receptors contribute to the cutaneous vasoconstricting action of MDMA and its reversal by clozapine.     

Responses of inferior salivatory neurons to stimulation of trigeminal sensory branches

A total of 84 single inferior salivatory neurons was identified by antidromic stimulation of the tympanic nerve. Their responsiveness was tested to stimulation of the ipsilateral infraorbital, lingual, and inferior alveolar nerves in urethane-chloralose-anesthetized cats. The conduction velocities of preganglionic fibers of inferior salivatory neurons ranged from 2.2 to 9.1 m/s, and 54% of those neurons responded with spikes to stimulation of at least one of the infraorbital, lingual, or inferior alveolar nerves (responsive type neurons). The latencies of spike responses to stimulation of the trigeminal sensory branches ranged from 4.0 to 21.0 ms, which were shorter than those of superior salivatory neurons. Impulses of both A-beta and A-delta afferent fibers of the trigeminal nerve were found to be effective for activation of inferior salivatory neurons. The convergence of excitatory inputs from more than one sensory nerve was found in most of the responsive type neurons (73%).     

Evidence for a central depressor action of postsynaptic alpha 1-adrenergic receptor antagonists

The effects of alpha-adrenergic receptor antagonists on sympathetic nervous discharge (SND) recorded from the external carotid and splanchnic nerves were studied in baroreceptor intact and denervated cats. Prazosin (50 microgram/kg, i.v.) produced a rapid fall in mean arterial pressure (MAP) and no significant change in heart rate (HR) in baroreceptor denervated cats. Prazosin administration was also associated with a prolonged inhibition of SND. Nerve activity was significantly reduced within 5 min of prazosin administration remained depressed throughout the 2 h observation period. Like prazosin, WB-4101 (0.5 mg/kg, i.v.) also produced significant reductions in MAP and SND. In addition, WB-4104 produced a transient bradycardia. The decreases in MAP and SND were reversed by piperoxane (0.5 mg/kg, i.v.). Both prazosin and WB-4101 inhibited the pressor response to i.v. norepinephrine. In baroreceptor intact cats, prazosin decreased MAP and SND, but did not affect HR. In contrast, phentolamine (1 mg/kg, i.v.) decreased MAP but increased SND and HR. These data indicate that the sympatholytic action of WB-4101 and prazosin results from a centrally mediated reduction in SND as well as a peripheral blockade of alpha-adrenergic receptors. These data further suggest that noradrenergic neurons normally facilitate the outflow of sympathetic nerve activity from the central nervous system.     

A modulatory role of central cholinergic transmission in control of the 10-Hz rhythm in sympathetic nerve discharge

In 43 urethane-anesthetized or decerebrate, baroreceptor-denervated cats, spectral analysis showed that most of the power in sympathetic nerve discharge (SND) was at frequencies < 6 Hz. In 18 of these cats, physostigmine (100 μg/kg i.v.) induced a 10-Hz rhythm in inferior cardiac SND that was eliminated by atropine sulfate (0.25 mg/kg i.v.; n = 6). In contrast, the naturally occurring 10-Hz rhythm that appeared in SND in other experiments was atropine-insensitive (n = 6). The data indicate that central muscarinic cholinergic transmission is not essential for the naturally occurring 10-Hz rhythm. Nonetheless, facilitation of cholinergic transmission can induce a 10-Hz rhythm.