Neurotransmitters and neuromodulators controlling the hypoxic respiratory response in anaesthetized cats.

1. The contributions of neurotransmitters and neuromodulators to the responses of the respiratory network to acute hypoxia were analysed in anaesthetized cats. 2. Samples of extracellular fluid were collected at 1-1.5 min time intervals by microdialysis in the medullary region of ventral respiratory group neurones and analysed for their content of glutamate, gamma-aminobutyric acid (GABA), serotonin and adenosine by high performance liquid chromatography. Phrenic nerve activity was correlated with these measurements. 3. Levels of glutamate and GABA increased transiently during early periods of hypoxia, coinciding with augmented phrenic nerve activity and then fell below control during central apnoea. Serotonin and adenosine increased slowly and steadily with onset of hypoxic depression of phrenic nerve activity. 4. The possibility that serotonin contributes to hypoxic respiratory depression was tested by microinjecting the 5-HT-1A receptor agonist 8-OH-DPAT into the medullary region that is important for rhythmogenesis. Hypoxic activation of respiratory neurones and phrenic nerve activity were suppressed. Microinjections of NAN-190, a 5-HT-1A receptor blocker, enhanced hypoxic augmentation resulting in apneustic prolongation of inspiratory bursts. 5. The results reveal a temporal sequence in the release of neurotransmitters and neuromodulators and suggest a specific role for each of them in the sequential development of hypoxic respiratory disturbances.

cAMP-dependent reversal of opioid- and prostaglandin-mediated depression of the isolated respiratory network in newborn rats.

1. Membrane potential (Vm) and resistance (Rm) of ventral respiratory group (VRG) neurons were measured in the isolated brainstem-spinal cord from newborn rats during bath application of the opioid receptor agonists fentanyl or [D-Ala2, D-Leu5]-enkephalin (Ala-Leu-Enk) and of the prostaglandin E1 (PGE1). 2. PGE1 (0.1-3 microM) and fentanyl or Ala-Leu-Enk (1-50 microM) produced depression and, at higher doses, block of inspiratory nerve activity and respiration-related postsynaptic potentials. This apnoea was associated with hyperpolarization and Rm fall in 25% of thirty-two VRG neurons tested, whereas resting Vm and Rm were not changed in the other cells. 3. The selective mu- and delta-receptor blockers naloxonazine (10-20 microM) and naltrindole (50-100 microM) antagonized the effects of 5 microM fentanyl and 50 microM Ala-Leu-Enk, respectively. 4. Opioid- and PGE1-evoked respiratory depression was reversed upon elevation of endogenous cAMP levels by stimulating adenylyl cyclase with 100 microM forskolin, activating dopamine D1 receptors with 50-100 microM 6-chloro-7,8-dihydroxy-3-allyl-1-phenyl-2, 3,4,5-tetrahydro-1H-3-benzazepine (6-chloro-APB) or preventing cAMP breakdown with 50-100 microM isobutylmethylxanthine. 5. The results indicate that opioid- or prostaglandin-induced respiratory depression is due to a fall in cAMP levels in cells responsible for generation of rhythm or providing a tonic drive to the respiratory network. 6. We suggest that elevation of cAMP levels is an effective antidote in neonates against such forms of respiratory depression.

cAMP-dependent protein kinase modulates expiratory neurons in vivo.

The adenosine 3',5'-cyclic monophosphate (cAMP)-dependent protein kinase (PKA) second-messenger system influences neuronal excitability by modulating voltage-regulated and transmitter-activated channels. In this study we investigated the influence of the cAMP-PKA system on the excitability of expiratory (E) neurons in the caudal medulla of anesthetized, paralyzed, and artificially ventilated adult cats. We intracellularly injected the PKA inhibitors cAMP-dependent PKA inhibitor 5-22 amide (Walsh inhibitory peptide) and Rp-adenosine 3',5'-cyclic monophosphothioate triethylamine (Rp-cAMPS), the PKA activator Sp-adenosine 3',5'-cyclic monophosphothioate triethylamine (Sp-cAMPS), and the adenylyl cyclase activator forskolin and measured membrane potential, neuronal input resistance, and synaptic membrane currents. Inhibition of cAMP-PKA activity by Walsh inhibitory peptide or Rp-cAMPS injections hyperpolarized neurons, decreased input resistance, and depressed spontaneous bursts of action potentials. Action potential duration was shortened and afterhyperpolarizations were increased. Inhibitory synaptic currents increased significantly. Stimulation of cAMP-PKA activity by Sp-cAMPS or forskolin depolarization neurons and increased input resistance. Spontaneous inhibitory synaptic currents were reduced and excitatory synaptic currents were increased. Rp-cAMPs depressed stimulus-evoked excitatory postsynaptic potentials and currents, whereas Sp-cAMPS increased them. Sp-cAMPS also blocked postsynaptic inhibition of E neurons by 8-hydroxy-dipropylaminotetralin, a serotonin-1A (5-HT-1A) receptor agonist that depresses neuronal cAMP-PKA activity. To determine the predominant effect of G protein-mediated neuromodulation of E neurons, we injected guanosine-5'-O-(3-thiotriphosphate) tetralithium salt (GTP-gamma-S), an activator of both stimulatory and inhibitory G proteins. GTP-gamma-S hyperpolarized E neurons, reduced input resistance, and increased action potential afterhyperpolarization. We conclude that the intracellular cAMP-PKA messenger system play an important role in the activity-dependent modulation of excitability in E neurons of the caudal medulla. In addition, the cAMP-PKA pathway itself is downregulated during activation of 5-HT-1A receptors.

Nucleus raphe obscurus evokes 5-HT-1A receptor-mediated modulation of respiratory neurons.

We analysed in vivo the synaptic mechanisms underlying serotonin-mediated depression of expiratory neuronal discharges and phrenic nerve activity. We report that nucleus raphe obscurus stimulation not only abolishes phrenic nerve activity, but also hyperpolarizes the membrane potential, depresses periodic synaptic drive potentials and thus action potential discharges in caudal medullary expiratory neurons. These effects originate from pre- and post-synaptic inhibitory processes that involve 5-HT-1A receptor activation.

Intracellular signal pathways controlling respiratory neurons.

Medullary respiratory neurons are influenced by a variety of neuromodulators, but there is a lack of information about the specific intracellular signal pathways involved. In this report we describe the modulatory effects of the cyclic adenosine-triphosphate (cAMP)-dependent protein kinase and of protein kinase C pathways on voltage- and ligand-controlled ionic conductances and demonstrate their functional significance in regulating the excitability of medullary respiratory neurons of the vivo cat. Evidence is presented that PKA and PKC pathways are persistently activated. PKA regulates current flow through persistently activated and GABAB receptor-controlled potassium channels as well as GABAA receptor-controlled chloride channels. PKC also depresses persistent potassium currents but it potentiates excitatory and inhibitory synaptic currents. The clinical significance of these intracellular signal pathways is demonstrated in a case of a child suffering from apneustic breathing, who was successfully treated with a 5HT-1A receptor agonist.

Voltage-clamp analysis of neurons within deep layers of the brain.

Single electrode whole cell current- and voltage-clamp techniques in conjunction with intra- and extracellular phoresis and extracellular application of pharmacological agents were applied to study neurons in deep layers of the brainstem of anesthetized, paralyzed and artificially ventilated cats. We compared slow rhythmic changes and stimulus-evoked postsynaptic current and voltage responses of neurons as they were recorded with fine-tipped microelectrodes filled with 2-3 M 'microelectrode solutions' or with 0.3 M 'patch solutions', or with patch electrodes. The experimental data were then compared with the effects of somatic and dendritic conductance changes simulated in a cell model. A new method was introduced for alternating current and voltage-clamp measurements performed at 300 Hz, which provided quasi-simultaneous measurements of slow changes of spontaneous synaptic currents and potentials. During current or voltage clamp, chemicals which affect voltage- and receptor-controlled conductances were ionophoresed intracellularly through single or theta-type glass electrodes. We show examples of activation of low-voltage activated Ca2+ responses after blockade of Na+ currents by intracellular QX 314 and K+ currents by intracellular Cs+ injections in addition to Sp-cAMPs to activate protein kinase A. TEA, NMDA and GABA were used to demonstrate the effectiveness of extracellular application of drugs through multibarrel electrodes or local application through a 'bath'. The various tests demonstrated that single electrode whole cell current- and voltage-clamp methods, in combination with various techniques for drug application, can be well applied to study the biophysical properties and pharmacological sensitivities of neurons embedded in in vivo networks within deep layers of the brain.

Protein kinase C pathways modulate respiratory pattern generation in the cat.

1. The significance of protein kinase C (PKC) in respiratory pattern generation was investigated in forty-three expiratory neurones of anaesthetized cats. 2. Intracellular injection of R-2,6-diamino-N-([1-(oxotridecyl)-2-piperidinyl]-methyl)-hexana mide dihydrochloride reversibly hyperpolarized twenty-six neurones. Respiratory drive potentials decreased to 92% of control, and action potential discharges were reduced. Neuronal input resistance (Rin) decreased during inspiration and increased during expiration. 3. Voltage clamp revealed that blockade of PKC induced an increase of inhibitory drive currents and a decrease of excitatory drive currents in sixteen neurones. The amplitude of respiratory drive currents was decreased to 91% of control. The slope of synaptic inward currents during postinspiration was reduced. 4. After blockade of K+ conductances by TEA, additional blockade of PKC caused a hyperpolarization during postinspiration and expiration, but depolarization during inspiration in fourteen neurones. The respiratory drive currents were reduced to 61% of control. Respiratory drive potentials decreased to 72% of control, leading to reduced spontaneous discharge. Rin was increased throughout the respiratory cycle. 5. Stimulus-evoked postsynaptic currents and potentials decreased after blockade of PKC with and without TEA. 6. The results indicate that PKC is endogenously active in expiratory neurones, modulating their excitability in three different ways: (a) it downregulates persistent K+ currents, (b) it upregulates Cl(-)-mediated inhibitory postsynaptic currents (IPSCs), and (c) it upregulates excitatory postsynaptic currents (EPSCs).

5-HT2 receptor-controlled modulation of medullary respiratory neurones in the cat.

1. The effects of the 5-HT2 receptor agonist alpha-methyl-5-HT were studied on the membrane of expiratory (E2) and post-inspiratory (PI) neurones, by intracellular recordings in the caudal medulla of anaesthetized cats. 2. Ionophoresis of alpha-Me-5-HT depolarized membrane potential and increased action potential frequency in a majority of neurones tested. Depolarization of neurones by alpha-Me-5-HT was accompanied by increased input resistance throughout all phases of the respiratory cycle. These effects were antagonized by ionophoresis of cinanserin, a receptor-blocking agent with high affinity for 5-HT2 receptors. 3. E2 neurones were voltage clamped to measure membrane current changes induced by alpha-Me-5-HT ionophoresis. alpha-Me-5-HT induced a net inward current by reducing inspiratory-phase outward currents and increasing expiratory-phase inward currents. These changes were equivalent with steady membrane depolarization, decreased inspiratory phase membrane hyperpolarization and increased expiratory drive potential recorded from the same neurones in current clamp. 4. The effects of alpha-Me-5-HT are consistent with activation of 5-HT2 receptors on E2 and PI neurones leading to blockade of synaptically activated and persistent conductances to potassium ions.

The excitability and rhythm of medullary respiratory neurons in the cat are altered by the serotonin receptor agonist 5-methoxy-N,N, dimethyltryptamine.

5-Methoxy-N,N-dimethyltryptamine (5-MeODMT) is an indolealkylamine which has agonist activity at 5HT receptors. In the present investigation, 5-MeODMT had two types of effects on medullary respiratory neurons of the cat. Iontophoretic administration or i.v. doses (43 +/- 8.9 micrograms/kg) of 5-MeODMT hyperpolarized respiratory neurons and severely reduced action potential discharges. Cinanserin, a 5HT-2/1 c receptor antagonist, when injected i.v. reduced the inhibition produced by i.v. injection of 5-MeODMT. Iontophoresis of cinanserin did not antagonize inhibition produced by iontophoresis of 5-MeODMT or 5-HT. The depression of respiratory discharge by i.v. injection of 5-MeODMT is attributed to presynaptic effects (network depression) and post-synaptic activation of 5HT-1A receptors on respiratory neurons. 5-MeODMT (27 +/- 2.78 micrograms/kg i.v.) also increased discharge frequency of inspiratory and expiratory neurons. Inspiratory neuron discharges were briefer and expiratory neuron discharges occurred earlier in relation to phrenic nerve activity. It is suggested that the effects of the smaller doses are due to binding of 5-MeODMT to 5HT-1A receptors on early inspiratory neurons of the medulla.

Serotonin 1A-receptor activation suppresses respiratory apneusis in the cat.

Malfunction of inhibitory synaptic processes in the brainstem result in abnormal prolonged inspiration (apneusis). Since we previously found that the serotonin (5-hydroxytryptamine; 5-HT) 5-HT1A receptor agonist 8-hydroxy-dipropylaminotetralin (8-OH-DPAT) shortens inspiratory discharges, we tested its ability to suppress apneusis. We recorded phrenic nerve activity and the membrane potential of medullary expiratory (E-2) and postinspiratory (PI) neurons in 14 anaesthetized, paralyzed, artificially ventilated cats. Systemic hypoxia or i.v. injection of pentobarbital sodium or the N-methyl-D-aspartate (NMDA) receptor blocker ketamine induced apneustic phrenic nerve discharges, delayed depolarization to threshold of E-2 neurons and prolonged hyperpolarization in PI neurons. 8-OH-DPAT (10-40 micrograms/kg i.v.) produced partial to complete restoration of normal phrenic nerve discharges and membrane potential.

5-HT-1A receptor-mediated modulation of medullary expiratory neurones in the cat.

The involvement of the 5-HT-1A receptor in serotoninergic responses of stage 2 expiratory (E-2) neurones was investigated in pentobarbitone-anaesthetized, mechanically ventilated cats. The specific agonist of the 5-HT-1A receptor, 8-hydroxy-diproplaminotetralin (8-OH-DPAT), administered systemically or by ionophoresis directly on to the neurones, had a clear depressant effect. Administration of 8-OH-DPAT at doses of 10-50 micrograms kg-1 (I.V.) increased the membrane hyperpolarizations of E-2 neurones during the inspiratory and postinspiratory phases, and shortened their duration of activity in association with shortening of phrenic nerve activity. Discharges of E-2 neurones were also less intense. At doses of 50-90 micrograms kg-1, 8-OH-DPAT reduced or abolished inspiratory hyperpolarizations, and reduced expiratory depolarizations of membrane potential and discharge in parallel with inhibition of phrenic nerve discharges. The effects of the larger doses were reversed by I.V. injection of NAN-190, an antagonist at the 5-HT-1A receptor. Dose-dependent effects on the membrane potential and discharge of E-2 neurones, but not on phrenic nerve activity, were also seen by ionophoretic administration of 8-OH-DPAT on to E-2 neurones. At low currents, ejection of 8-OH-DPAT hyperpolarized the neurones without affecting the duration of inspiratory hyperpolarization and expiratory depolarization. This hyperpolarization depressed the intensity and the duration of expiratory discharges. Ejection with larger currents hyperpolarized the E-2 neurones further, and depressed expiratory depolarization leading to blockade of expiratory discharges. The effects on membrane potential were accompanied by decreased neuronal input resistance. This depressed the excitability of E-2 neurones as tested by discharge evoked by intracellular current injection. The amplitudes of action potentials decreased in parallel with the changes in input resistance. The effects were attributed to a postsynaptic effect of 8-OH-DPAT leading to a gradually developing inhibition by activation of 5-HT-1A receptors. Hyperventilatory apnoea depressed on-going synaptic activity and unmasked the effect of ionophoretically applied 8-OH-DPAT. The responses of the E-2 neurone were enhanced, as evidenced by increased membrane hyperpolarization and greater reduction of input resistance. Both responses faded appreciably, indicating receptor desensitization. The degree and rate of apparent desensitization depended on the dose/ejecting current. The greater sensitivity and faster desensitization to 8-OH-DPAT were attributed to the hyperventilatory alkalinization of the extracellular fluid, which might influence agonist binding to 5HT-1A receptors and/or receptor properties.

Inhibition of caudal medullary expiratory neurones by retrofacial inspiratory neurones in the cat.

1. Comparisons between the spike discharge of inspiratory neurons within the retrofacial area (RFN), and the membrane potential of expiratory neurones within the caudal medulla were made in pentobarbitone-anaesthetized, vagotomized, artificially ventilated cats. Spike-triggered averaging (STA) of synaptic potentials, triggered by the discharge of inspiratory RFN neurones, was utilized to test for synaptic connectivity. 2. Eighty-nine neurons with respiratory-phased discharge patterns were recorded in the vicinity of the RFN. Fifty-four neurones discharged at or slightly before the onset of the inspiratory burst activity of the phrenic nerve and continued firing throughout inspiration. Two continued to fire during post-inspiration. Forty-five of fifty-four inspiratory RFN neurones exhibited incrementing discharge patterns, six discharged with a plateau pattern, while only three neurones had a decrementing discharge pattern. 3. The membrane potential trajectories of caudal expiratory neurones revealed a typical wave of early inspiratory hyperpolarization. Occasionally, a second wave of hyperpolarization occurred during late inspiration, in conjunction with increased phrenic nerve activity. 4. Spike-triggered averaging revealed averaged inhibitory postsynaptic potentials (IPSPs), indicative of inhibitory synaptic connections, between eight and sixty-three pairs of RFN inspiratory and caudal expiratory neurones. 5. Inhibitory postsynaptic potentials detected by STA exhibited a relatively long latency and a slow time course. The IPSPs began, on average, 3.8 ms after an RFN action potential. The rise times, half-widths and durations of IPSPs were longer than expected for a monosynaptic somal input from myelinated axons of inspiratory RFN neurones. It is suggested that an inhibitory relay neurone in the immediate vicinity of the expiratory neurones is activated by a collateral of the RFN inspiratory neurone. 6. Retrofacial inspiratory neurones were antidromically activated only when high-intensity electrical stimulation was applied in the vicinity of caudal expiratory neurones. 7. The averaged IPSPs were preceded by diphasic and triphasic 'spike potentials'. The averaged spike potentials were highly entrained to the action potentials of RFN inspiratory neurones which triggered IPSPs. The spike potentials may be terminal potentials recorded from axons of RFN inspiratory neurones. 8. Evidence for convergence of synaptic inputs was obtained from STA tests in a caudal expiratory neurone receiving IPSPs from four RFN neurones. 9. The functional significance of this observation is discussed. We conclude that RFN inspiratory neurones exert a moderate inhibitory influence and act conjointly with other types of medullary inspiratory neurones.

Peripheral chemoreceptor inputs to medullary inspiratory and postinspiratory neurons of cats.

The effect of peripheral chemoreceptor activation on inspiratory and postinspiratory medullary neurons was investigated using intracellular recording techniques. Peripheral chemoreceptors were activated by injecting CO2 saturated 1 N bicarbonate solution into the lingual artery or by electrically stimulating the carotid sinus nerve. Injections of 20-300 microliters bicarbonate solution evoked changes in respiratory frequency and in peak phrenic nerve discharge. The membrane potential of inspiratory alpha neurons, whether bulbospinal or not and independent of their anatomic location, was decreased during inspiration. A sequence of compound excitatory and inhibitory effects were observed when the stimulus was given during the postinspiratory and expiratory phases of the respiratory cycle. Inspiratory beta- and late-inspiratory neurons, however, were inhibited by peripheral chemoreceptor activation. Postinspiratory neurons were strongly activated during postinspiration. Neither class of respiratory neurons were shown to receive direct synaptic inputs from the peripheral chemoreceptors as tested by electrical stimulation of the carotid sinus nerve and signal averaging of the respiratory neuron membrane potential. The experiments revealed differential influences of afferent chemoreceptor activity on various components of the respiratory network. We conclude that chemoreceptor afferents activate non-respiratory modulated medullary neurons which, in turn, activate or inhibit various neurons of the medullary respiratory control network. The responses of each type of respiratory neuron to chemoreceptors afferents may then be considered in the context of this direct interaction as well as the network interactions of the various cells.

Serotoninergic and non-serotoninergic responses of phrenic motoneurones to raphe stimulation in the cat.

Experiments were conducted on anaesthetized, paralysed and artificially ventilated cats in order to determine if the altered discharge pattern of phrenic motoneurones recorded during stimulation of medullary raphe nuclei (raphe magnus (r. magnus), raphe obscurus (r. obscurus), raphe pallidus (r. pallidus] are related to release of serotonin (5-hydroxytryptamine, 5-HT) at synapses on respiratory neurones. Effects of 5-HT released by the neurotoxin p-chloroamphetamine (PCA) on spontaneous activity of phrenic motoneurones were also examined. In addition, responses of phrenic motoneurones to 5-HT applied by micro-electrophoresis were recorded. Stimulation (100 Hz) of r. magnus or r. obscurus depressed the spontaneous inspiratory discharges of phrenic motoneurones. Administration of the 5-HT receptor antagonists cinanserin, methysergide or methergoline reduced, but did not abolish, the inhibition. Inhibition of the neuronal reuptake of 5-HT with fluoxetine enhanced the inhibition and reduced the peak inspiratory action potential frequency of spontaneous discharges. Stimulation (100 Hz) of r. pallidus produced increased firing of phrenic motoneurones. Firing of phrenic motoneurones was evoked even during the normally quiescent expiratory phase of spontaneous respiratory activity. Antagonists at 5-HT receptors reduced the degree of tonic firing, resulting in partial restoration of expiratory pauses during r. pallidus stimulation. Inhibition of 5-HT reuptake, on the other hand, resulted in increased tonic firing. Release of 5-HT by PCA produced a rapid and severe reduction of phrenic nerve activity. Activity was restored by 5-HT receptor antagonists. In reserpine-treated cats, effects of stimulating medullary raphe nuclei were still pronounced, however 5-HT receptor antagonists had no effect on the responses. These results, along with the observation that 5-HT receptor antagonists are only partially effective in non-reserpinized cats, indicate that non-serotoninergic influences contribute as well to the responses evoked by raphe stimulation. Micro-electrophoretic application of 5-HT by large ejecting currents (100-200 nA) had weak stimulatory effects on twenty of forty-five phrenic motoneurones, which exhibited small increases in peak inspiratory discharge frequency during 5-HT application. Ejecting currents less than 100 nA were without effect. It is concluded that 5-HT analogues and agents which release endogenous 5-HT after parenteral administration do not act directly at synapses on the soma membranes of phrenic motoneurones.(ABSTRACT TRUNCATED AT 400 WORDS)

Responses of phrenic motoneurones of the cat to stimulation of medullary raphe nuclei.

Responses of phrenic motoneurones to stimulation of the three medullary raphe nuclei (raphe magnus (r. magnus), raphe obscurus (r. obscurus) and raphe pallidus (r. pallidus] were recorded in anaesthetized and decerebrated cats. Stimulation of r. magnus or r. obscurus depressed phrenic motoneurones. Stimulation at 100 Hz reduced action potential frequency within each inspiratory burst, without appreciable changes in inspiratory duration, or number of inspiratory bursts per unit time. The depression was proportional to the stimulus intensity (40-160 microA) and frequency (12-100 Hz) and lasted throughout the period of stimulation. Intracellular recording revealed concomitant depression of central respiratory drive potentials (c.r.d.p.s) and increased membrane input resistance during r. obscurus or r. magnus stimulation. In motoneurones which discharged action potentials during expiratory as well as inspiratory phases following intracellular chloride injection, stimulation of r. magnus or r. obscurus depressed cell firing during both phases. Both c.r.d.p.s and reversed inhibitory post-synaptic potentials (i.p.s.p.s) were depressed. These findings indicate that the depression is not related to post-synaptic inhibition of phrenic motoneurones. Stimulation (100 Hz) of r. pallidus produced discharges of action potentials in phrenic motoneurones. Stimulation lengthened the duration of each inspiratory discharge in proportion to stimulus intensity. Continuous firing occurred throughout the period of stimulation with maximal intensities. Intracellular recordings revealed sustained depolarization and reduction in membrane input resistance during the discharge. Responses were recorded extracellularly from medullary inspiratory neurones of the dorsal respiratory group (d.r.g.) and ventral respiratory group (v.r.g.) and from vagal axons which fired in phase with phrenic nerve activity. Responses to raphe stimulation were similar to those recorded from phrenic motoneurones. Evidence is presented that the responses are not related to stimulation of decussating bulbo-spinal axons from d.r.g. or v.r.g. neurones. It is suggested that medullary respiratory neurones receive inhibitory and excitatory synaptic inputs from medullary raphe neurones. Hypercapnia (5% CO2 in O2) or hypoxia (15% O2 in N2) reduced markedly the inhibition produced during stimulation of r. obscurus or r. magnus, and restored expiratory-linked silent periods during stimulation of r. pallidus. Activation of Hering-Breuer or baroreceptor reflexes did not alter responses to r. pallidus stimulation.(ABSTRACT TRUNCATED AT 400 WORDS)

Effects of baclofen and gamma-aminobutyric acid on different types of medullary respiratory neurons.

Effects of baclofen and gamma-aminobutyric acid on medullary respiratory neurons were investigated. Medullary inspiratory neurons of the dorsal and ventral respiratory groups were stimulated by baclofen, 0.5-2 mg/kg, and depressed by doses greater than 4-6 mg/kg. Expiratory neurons were depressed by doses of baclofen which increased phrenic nerve activity. Microelectrophoresis of baclofen (5 mM, pH 3) depressed medullary inspiratory neurons. It is suggested that low i.v. doses of baclofen increase inspiratory activity by disinhibition of medullary neurons whereas higher doses directly depress medullary inspiratory neurons.

Nonalgebraic interaction between pressor and depressor reflexes in dogs: evidence for a central site of action.

In a previous study (Kendrick, JE and Matson, G 1979, Amer J Physiol 327:H662-H667) we demonstrated that the vascular responses in dogs to electrical stimulation of aortic nerve (AN) pressor and carotid sinus nerve (CSN) depressor afferents did not sum algebraically. We suggest this results from a reflex interaction which occurs in the central nervous system. The present study extends earlier studies by recording sympathetic vasomotor in chloralose-anesthetized dogs. Stimulation of the CSN reduced sympathetic activity by 51 +/- 20 (SD)%. AN stimulation (2 Hz) caused a 17 +/- 12% increase in sympathetic activity. Combined stimulation of the ipsilateral CSN and AN caused 0 +/- 28% change rather than a 34% decrease expected by an additive interaction. The interaction recorded in this study from the sympathetic outflow is therefore consistent with the previously reported vascular responses (cited above) and implicates central nervous site(s) of action. A conditioning stimulus train to CSN inhibited sympathetic discharges to AN test stimuli. This inhibition was prevented by pairing an AN stimulus with the CSN stimulus train. The AN pressor reflexes act in part by increasing sympathetic activity and in part by suppressing the baroreflexes.

Biphasic effects of baclofen on phrenic motoneurons: possible involvement of two types of gamma-aminobutyric acid (GABA) receptors.

Intravenous injections of baclofen have two general dose-dependent effects on phrenic motoneurons in anesthetized cats. Small doses (0.5-1.5 mg/kg) increase the frequency of action potentials recorded from single motoneurons and from the phrenic nerve, whereas large doses (2-10 mg/kg) reduce or abolish action potentials. The increase in frequency produced by small doses is accompanied by membrane depolarization and, in most experiments, by increased input resistance. Large doses hyperpolarize phrenic motoneurons and produce greater increases in input resistance. Extracellular recording during microelectrophoretic application of baclofen reveals only one effect, depression of cell firing, at all effective current strengths. The low dose stimulatory effect of i.v. baclofen is attributed to disinhibition, whereas the depression by large doses is attributed to disfacilitation. During incomplete inhibition by baclofen, CO2 administration further depresses phrenic nerve activity. Bicuculline (100-600 micrograms/kg i.v.) and picrotoxin (900 micrograms/kg i.v.) restore firing depressed by baclofen, whereas strychnine (80-1280 micrograms/kg) does not. 3-Aminopropanesulfonic acid (5-75 mg/kg i.v.) an agonist at gamma-aminobutyric acid-A receptor sites, depresses phrenic nerve activity. It is suggested that the low dose stimulatory effects are related to actions at gamma-aminobutyric acid-B receptors, whereas the high dose depressant effects are related, at least in part, to activation of gamma-aminobutyric acid-A receptors.

Inhibition of respiratory neural discharges by clonidine and 5-hydroxytryptophan.

Activation of receptors for norepinephrine or serotonin in the central nervous system by i.v. injection of clonidine (10-50 micrograms/kg) or 5-hydroxytryptophan (20-40 mg/kg) inhibits phrenic neural discharges in anesthetized, artificially ventilated cats. Clonidine induces a rapid and complete inhibition of phrenic nerve activity which lasts for 1 to 3.2 hr. The inhibition is prevented by prior administration of phenoxybenzamine (10 mg/kg) or tolazoline (3 mg/kg). 5-Hydroxytryptophan, injected after inhibition of peripheral amino acid decarboxylase (carbidopa, 30-50 mg/kg), elicits a gradual but complete inhibition of phrenic nerve discharges which persists for 1 to 10 hr and is unaltered by alpha or beta adrenoceptor blocking agents. The inhibitions produced by clonidine and 5-hydroxytryptophan are overcome transiently during hypercapnia. Stimulation of carotid body chemoreceptors by i.a. injections of lobeline, doxapram or 0.015 N HCl in saline also briefly reinstates phrenic nerve discharges after inhibition by clonidine. Inhibition is also overcome during electrical stimulation of the carotid sinus nerve.