Combined antagonism of aminergic excitatory and amino acid inhibitory receptors in the XII nucleus abolishes REM sleep-like depression of hypoglossal motoneuronal activity.

It is hypothesized that the suppression of motor activity (atonia) that occurs during REM sleep is caused by the combined inhibition of motoneurons by glycine or GABA and withdrawal of excitation mediated by serotonin and norepinephrine. However, it is not known whether these mechanisms can fully account for the atonia. In urethane-anesthetized, paralyzed and artificially ventilated rats, REM sleep-like episodes can be repeatedly elicited by microinjections of a cholinergic agonist, carbachol, into the dorsomedial pons. We used this model to determine whether microinjections of a combination of antagonists of serotonergic, adrenergic, GABA(A) and glycinergic receptors (methysergide, prazosin, bicuculline and strychnine) into the XII nucleus can abolish the carbachol-induced depression of XII motoneuronal activity. REM sleep-like episodes were elicited prior to, and at different times after, antagonist microinjections. In all six rats studied, the depression of XII motoneuronal activity did not occur when tested 30-60 min after the antagonists, whereas other characteristic features of the response (latency, duration, the appearance of hippocampal theta rhythm, activation of the cortical EEG, slowing of the respiratory rate) remained intact. The carbachol-induced depression partially recovered after 2-3 hours. We conclude that the REM sleep-like depression of XII motoneuronal activity can be fully accounted for by all or some of the following mechanisms: a withdrawal of motoneuronal excitation mediated by norepinephrine and serotonin and increased inhibition mediated by GABA and glycine.

Behavior of hypoglossal inspiratory premotor neurons during the carbachol-induced, REM sleep-like suppression of upper airway motoneurons.

In individuals with compromised upper airway anatomy, genioglossus (GG), the main protruder muscle of the tongue, is an important upper airway dilator which helps prevent upper airway obstructions. During rapid eye movement (REM) sleep, both the tonic and inspiratory-modulated components of GG activity are suppressed in parallel with the characteristic postural atonia. We tested whether the REM sleep-related reduction in the respiratory activity of GG may, in part, result from a reduced inspiratory drive relayed to hypoglossal (XII) motoneurons from their premotor medullary inspiratory neurons. In 15 urethane-anesthetized, paralyzed, vagotomized and artificially ventilated rats, we recorded XII nerve activity and the extracellular activity of medullary inspiratory-modulated neurons antidromically activated with latencies of 0.8 ms +/- 0.3(SD) from within (n = 19) or adjacent to (n = 11) the XII nucleus. Carbachol (10-20 nl, 10 mM), a cholinergic agonist, was microinjected into the dorsomedial pons. Such injections trigger a REM sleep-like state in chronically instrumented, intact animals and, in anesthetized rats, produce respiratory and electrocortical changes similar to those of REM sleep. Following the injections, the respiratory component of XII nerve activity was depressed by 51 +/- 22%, while the mean inspiratory firing rate of the neurons decreased by only 7.4 +/- 13.8% (from 69 +/- 34 Hz to 65 +/- 37 Hz; P < 0.02; n = 30). The activity of ventral respiratory group (VRG) and reticular formation inspiratory neurons with axons within the XII nucleus was reduced by 10 +/- 14% (P < 0.005; n = 19), whereas the activity of neurons located near the VRG that had axons passing below the XII nucleus did not change (n = 5). Thus, the depressant effect of carbachol on medullary inspiratory neurons was slightly more pronounced in reticular formation and VRG cells premotor to XII motoneurons than in other medullary inspiratory cells. For all cells, the magnitude of the decrease of cell activity was not related to the magnitude of depression of XII nerve activity, the simultaneously occurring decrease in respiratory rate or the cell's control firing rate. Since the magnitude of this depressant effect on all cell types was disproportionately small when compared with the depression of XII nerve activity, the REM sleep-like decrease in GG activity must be mainly mediated by non-respiratory premotor pathways.

Differential suppression of upper airway motor activity during carbachol-induced, REM sleep-like atonia.

Microinjections of carbachol into the pontine tegmentum of decerebrate cats have been used to study the mechanisms underlying the suppression of postural and respiratory motoneuronal activity during the resulting rapid eye movement (REM) sleep-like atonia. During REM sleep, distinct respiratory muscles are differentially affected; e.g., the activity of the diaphragm shows little suppression, whereas the activity of some upper airway muscles is quite strong. To determine the pattern of the carbachol-induced changes in the activity of different groups of upper airway motoneurons, we simultaneously recorded the efferent activity of the recurrent laryngeal nerve (RL), pharyngeal branch of the vagus nerve (Phar), and genioglossal branch of the hypoglossal (XII) and phrenic (Phr) nerves in 12 decerebrate, paralyzed, vagotomized, and artificially ventilated cats. Pontine carbachol caused a stereotyped suppression of the spontaneous activity that was significantly larger in Phar expiratory (to 8.3% of control) and XII inspiratory motoneurons (to 15%) than in Phr inspiratory (to 87%), RL inspiratory (to 79%), or RL expiratory motoneurons (to 72%). The suppression in upper airway motor output was significantly greater than the depression caused by a level of hypocapnia that reduced Phr activity as much as carbachol. We conclude that pontine carbachol evokes a stereotyped pattern of suppression of upper airway motor activity. Because carbachol evokes a state having many neurophysiological characteristics similar to those of REM sleep, it is likely that pontine cholinoceptive neurons have similar effects on the activity of upper airway motoneurons during both states.

Differential sensitivity of laryngeal and pharyngeal motoneurons to iontophoretic application of serotonin.

Serotonergic neurons decrease their activity during sleep, especially rapid eye movement sleep, thereby reducing their facilitatory effect on upper airway motoneurons. The magnitude of teh sleep-related loss of tone varies among upper airway muscles (e.g., pharyngeal dilator motoneurons are more suppressed than laryngeal motoneurons). We hypothesized that these differences may be related to the sensitivity of different groups of upper airway motoneurons to serotonin. Experiments were done on decerebrate, vagotomized, paralysed and artificially-ventilated cats. Hypoglossal and laryngeal motoneurons were recorded extracellularly using five-barrel pipettes filled with: serotonin, glutamate and methysergide (serotonergic antagonist) for iontophoresis, and NaCl for recording and current balancing. All but two of the 65 hypoglossal motoneurons (45 inspiratory, 10 expiratory, 10 tonic) and 27 out of 32 laryngeal motoneurons (14 inspiratory, 18 expiratory) were excited by serotonin, and the excitation was abolished by methysergide. To compare the magnitude of the excitatory effect among distinct motoneuronal groups, we applied small ejection currents in a standardized manner (+15 nA for 3 min; 10 mM serotonin in 150 NaCl) onto spontaneously active motoneurons (13 inspiratory hypoglossal, 11 inspiratory laryngeal and 11 expiratory laryngeal). Serotonin increased the number of spikes per respiratory burst of inspiratory hypoglossal motoneurons from 19 +/- 4.0 (S.E.M.) to 35 +/- 4.8, of inspiratory laryngeal motoneurons from 44 +/- 8.3 to 55 +/- 8.8, and of expiratory laryngeal motoneurons from 23 +/- 4.8 to 33 +/- 6.2. The relative increases in activity (to 220% +/- 24, 147% +/- 23 and 148% +/- 9 of control, respectively) were significantly higher in hypoglossal than in laryngeal motoneurons. In addition, the excitatory effect developed significantly faster in hypoglossal than in laryngeal motoneurons. Methysergide reduced the spontaneous activity of about half the hypoglossal and laryngeal motoneurons to 66% +/- 5 of control. Thus, the sensitivity to the excitatory effects of serotonin varies among different pools of upper airway motoneurons. These differences correlate with the pattern of airway muscle hypotonia seen during sleep.

Interaction of serotonergic excitatory drive to hypoglossal motoneurons with carbachol-induced, REM sleep-like atonia.

The facilitatory effect of serotonin (5HT) on hypoglossal (XII) motoneurons is likely to be reduced during rapid eye movement (REM) sleep, when the activity of the brainstem serotonergic system reaches its nadir. Therefore, we assessed the hypothesis that application of exogenous 5HT will attenuate the REM sleep-like suppression of XII motoneurons produced in decerebrate cats by pontine microinjections of a cholinergic agonist, carbachol. Microinjections of 5HT or 5-carboxamidotryptamine into the XII nucleus increased XII nerve activity to 182 +/- 53% (standard deviation; SD) of control. Subsequent pontine microinjections of carbachol reduced XII nerve activity by 55 +/- 21% of the pre-5HT level (n = 12). Microinjections of methysergide (a 5HT antagonist) into the XII nucleus reduced XII nerve activity to 54 +/- 17% of the pre-methysergide control (n = 6). Pontine carbachol injections after methysergide further reduced XII nerve activity by 49 +/- 20% of the pre-methysergide level. Treatments with both agonists and the antagonist attenuated the carbachol-induced decrease when compared to two previous studies using the same model: 1) In experiments with no injections of serotonergic agents, pontine carbachol injections decreased XII nerve activity by 90 +/- 6% of control. 2) After enhancement of XII nerve activity by inhibitory amino acid antagonists (to 135 +/- 60%), the subsequent carbachol-induced decrease was even larger, 112 +/- 62% of control. We propose that serotonergic excitation can significantly attenuate the REM sleep-like suppression of XII nerve activity, and that this is achieved, in part, by substituting for the decreased endogenous 5HT in the XII nucleus. The study also demonstrates that other, non-serotonergic, mechanisms also contribute to the carbachol-induced suppression.

Behaviour of raphe cells projecting to the dorsomedial medulla during carbachol-induced atonia in the cat.

1. The activity of most brainstem serotonergic cells is suppressed during sleep, particularly the rapid eye movement (REM) phase. Thus, they may play a major role in state-dependent changes in CNS functioning. Our main goal was to search for medullary raphe cells having axonal branches in the region of the hypoglossal (XII) motor nucleus and assess their behaviour during the atonia produced by microinjections of a cholinergic agonist, carbachol, into the dorsal pontine tegmentum. In chronic animals, such microinjections evoke a desynchronized sleep-like state similar to natural REM sleep; in decerebrate animals, they produce eye movements and a motor suppression similar to the postural atonia of REM sleep. 2. In decerebrate, paralysed, vagotomized and artificially ventilated cats, we recorded extracellularly from medullary raphe cells antidromically activated from the XII nucleus region. Forty-five cells recorded in the raphe obscurus and pallidus nuclei were antidromically activated with latencies characteristic of non-myelinated fibres (4.4-42.0 ms). For thirty-three of the forty-five cells, we found one or more axonal branches within or just below the XII nucleus. The remaining twelve cells, in addition to the XII nucleus, had axonal ramifications in the medial nucleus of the solitary tract (NTS) and/or the dorsal motor nucleus of the vagus (DMV). 3. A subset of fourteen spontaneously active cells with identified axonal projections were held long enough to be recorded during the carbachol-induced atonia, and eight of these also during the subsequent recovery and a systemic administration of the serotonergic 1A receptor agonist (+/-)8-hydroxy-2-(di-N-propylamino)tetrealin hydrobromide (8-OH-DPAT). All but one were suppressed during the atonia in parallel to the suppression of XII, phrenic and postural nerve activities (firing rate, 1.3 +/- 0.7 Hz before and 0.1 +/- 0.2 Hz after carbachol (means +/- S.D.)). Following the recovery from the atonia, the firing rates of the eight cells increased to the pre-carbachol level (1.6 +/- 1.0 Hz). Subsequently, all were silenced by 8-OH-DPAT. 4. These cells fulfil most physiological criteria for serotonergic cells and have the potential to modulate, in a state-dependent manner, activities in the motor XII nucleus, visceral sensory NTS, and DMV. The decrements in serotonergic neuronal activity that occur during the carbachol-induced atonia suggest that a similar withdrawal of serotonergic input may occur during REM sleep and contribute to the characteristic reductions in upper airway motor tone.

Changes in serotonin level in the hypoglossal nucleus region during carbachol-induced atonia.

The excitability of hypoglossal (XII) motoneurons innervating genioglossal muscles is markedly suppressed during the rapid-eye-movement (REM) stage of sleep. This may contribute to airway obstructions in sleep apnea patients. Based on our earlier studies in decerebrate cats using injections of carbachol into the pons to induce a REM sleep-like atonia and microinjections of serotonin (5HT) into the XII motor nucleus, we hypothesized that a sleep-related withdrawal of the serotonergic excitatory input to XII motoneurons may play a major role in these processes. To test one aspect of this hypothesis, we inserted microdialysis probes into the XII nucleus region of decerebrate, paralyzed, vagotomized and artificially ventilated cats. The probes were perfused without or with the addition of a 5HT reuptake blocker, clomipramine. The levels of 5HT and its metabolite, 5-hydroxyindoleacetic acid (5HIAA), were determined using HPLC and electrochemical detection in dialysate samples collected over successive 20 min periods under four successive experimental conditions: control (at least 2 h after probe insertion); during the postural atonia and respiratory depression produced by pontine microinjection of carbachol; recovery from the effects of carbachol produced by pontine microinjection of atropine; and, to verify that the presence of 5HT in the dialysate was related to the activity of serotonergic cells of the brainstem, following administration of 8-OH-DPAT, a 5HT 1A receptor agonist known to suppress activity in the serotonergic cells of the raphe system. After correcting for recovery rates of individual probes, the mean control 5HT level in the extracellular space of the XII nucleus region was 7.9 +/- 4.4 nM (S.D.) in eight experiments without reuptake blockers. During the carbachol-induced depression, it was reduced to 70 +/- 20% of the pre-carbachol level. It increased to the original control level 98 +/- 27% after pontine injection of atropine. 8-OH-DPAT reduced the 5HT level to 43 +/- 14% of the post-atropine level. Changes in the 5HIAA level were not as consistent as for 5HT and did not reach statistical significance under any of the experimental conditions. Thus, a functionally significant amount of 5HT is present in the extracellular space within the XII nucleus region, and its decrement during carbachol-induced, REM sleep-like atonia is likely to reflect that occurring during natural REM sleep; this may contribute to the decreased tone of upper airway muscles and airway patency.

Clinical safety profile of sotalol in the treatment of arrhythmias.

The safety of sotalol was evaluated in 3,257 patients treated for cardiac arrhythmias in double-blind and open-label clinical trials that support United States registration of the drug. In this composite population, 80% of patients had structural heart disease and 42% had life-threatening ventricular arrhythmias, i.e., ventricular tachycardia (VT) or fibrillation (VF). Proarrhythmia was reported in 141 patients (4.3%). Of these, 78 (2.4%) had torsades de pointes and 26 (0.8%) had sustained VT or VF. The overall incidence was higher in patients treated for sustained VT or VF (6.5%). In these patients, serious proarrhythmia was predominantly torsades de pointes (4.1%) and was more prevalent in patients with congestive heart failure and low ejection fraction. Torsades de pointes was observed early in the course of treatment, and its occurrence was related to dose. The overall mortality in patients treated with sotalol was 4.3% (139 patients); in patients with life-threatening arrhythmias, cardiac mortality was 4.8%. In only 27 patients (0.8%) was the death thought to be potentially drug-related. The deaths were not related to dose. Data from a previously reported placebo-controlled postmyocardial infarction trial indicated no significant difference in mortality between sotalol and placebo. Heart failure was reported in 3.3% of patients and was most prevalent in those with a previous history of congestive heart failure, cardiomyopathy, or structural heart disease. The occurrence of heart failure was unrelated to dose or time on drug; in more than half of the patients, sotalol treatment was continued. On average, there was no decrease in ejection fraction.(ABSTRACT TRUNCATED AT 250 WORDS)

Suppression of hypoglossal motoneurons during the carbachol-induced atonia of REM sleep is not caused by fast synaptic inhibition.

The depression of upper airway motor activity that develops during the rapid eye movement (REM) stage of sleep is a major factor allowing upper airway obstructions to occur in patients with sleep apnea syndrome. Microinjections of carbachol, a cholinergic agonist, into the dorsal pontine tegmentum of chronically instrumented cats produce REM sleep. In acutely decerebrate cats, carbachol induces postural atonia, eye movements and a depression of the motor output to respiratory pump and upper airway muscles. In lumbar motoneurons, the depression of activity is due to a glycinergic inhibition that has the same characteristics during natural REM sleep in chronic cats and carbachol-induced atonia in decerebrate cats (Neurophysiology, 57 (1987) 1118-1129). The mechanisms that lead to the suppression of upper airway motoneuronal activity during REM sleep are unknown. In this study, we assessed whether the depression of hypoglossal (XII) nerve activity induced by pontine carbachol injections is caused by inhibitory amino acids acting within the XII nucleus. In decerebrate, paralyzed and artificially ventilated cats, we recorded the activities of both XII nerves (genioglossal branches), one phrenic and a cervical motor branch (to monitor postural activity). Postural atonia and respiratory depression were induced by pontine carbachol injections. The inhibitory amino acid receptor antagonists, strychnine (glycine receptors) or bicuculline (GABAA receptors), were injected (100-250 nl; 1.0-2.5 mM) into one XII nucleus (the other served as control) in an attempt to reduce or abolish the depression subsequently induced by pontine carbachol. Prior to the carbachol injections, both antagonists caused similar elevations of XII nerve activity on the treated side (30-40%). However, following carbachol, the XII nerve activity on the treated side was depressed to about 25% of the (pre-antagonist and pre-carbachol) control level, whereas the depression on the untreated side was slightly greater, to 10-15% of the control. Additional injections of antagonists during the carbachol-induced depression produced no further increase in nerve activity. This minor effect of the antagonists on the carbachol-induced depression of XII nerve activity was in contrast to the marked disinhibitory effects that both antagonists had on the XII nerve response to electrical stimulation of the lingual nerve. The latter was used as a control for the ability of strychnine and bicuculline to exert disinhibitory effects within the XII nucleus. Thus, there is little, if any, contribution of these inhibitory amino acids to the depression of XII motoneurons during the carbachol-induced, REM sleep-like postural and respiratory depression; mechanisms other than fast synaptic inhibition must be involved.

Behavior of VRG neurons during the atonia of REM sleep induced by pontine carbachol in decerebrate cats.

The microinjection of carbachol into the pons of acute decerebrate cats elicits a REM sleep-like atonia and a profound suppression of respiratory motoneuronal activity (J. Appl. Physiol., 69 (1990) 2280-2289). To assess whether this suppression is mediated by medullary neurons that provide respiratory drive to motoneurons of the respiratory pump muscles (diaphragm and intercostals), we studied the effect of pontine carbachol on the activity of neurons of the ventral respiratory group (VRG) in decerebrate, vagotomized, paralyzed and artificially ventilated cats. VRG neurons were recorded extracellularly along with the activity of phrenic and intercostal (external and internal) nerves. Both inspiratory (I) and expiratory (E) VRG neurons had incrementing, ramp-like bursts of activity during their firing periods and were not vagal motoneurons. Carbachol produced a depression of the peak firing rate in most (42/57) neurons studied. However, five cells showed no change and ten had an increase in activity in spite of consistent depression at the motoneuronal level. For the total population of cells (34 I and 23 E), the peak firing was reduced to 88.5% +/- 16.3 (S.D.) of control. The simultaneously recorded phrenic activity was reduced to 77.9% +/- 11.5, while inspiratory intercostal activity fell to 63.4% +/- 21.6 and expiratory to 23.2% +/- 21.2 of control. The carbachol-induced changes in peak firing of both I and E cells were quantitatively similar, and positively correlated to changes in peak phrenic activity. Analysis of this correlation suggested that phrenic and intercostal activities will be depressed to some degree by carbachol even when the average VRG cell activity remains unchanged. In addition, our data show that VRG cells may receive a combination of inhibitory and excitatory inputs during the carbachol-induced depression of respiratory motoneurons. Thus, although some disfacilitation from VRG cells may occur, there must be additional inhibitory or disfacilitatory pathways that mediate the decrease in activity of both phrenic and intercostal motoneurons that accompanies the REM sleep-like atonia.

Spontaneous ventilation and respiratory motor output during carbachol-induced atonia of REM sleep in the decerebrate cat.

Microinjections of carbachol into the pons induce a state that resembles rapid eye movement (REM) sleep in intact cats and, in decerebrate, artificially ventilated cats, produce postural atonia accompanied by a powerful depression of the respiratory motor output. In this study, pontine carbachol was used in decerebrate, spontaneously breathing cats to assess the effects of mechanical and chemical respiratory reflexes on the magnitude and pattern of the carbachol-induced depression of breathing, and to determine whether the depression is altered in those animals in which rapid eye movements are present. Phrenic nerve activity and tidal volume were only transiently depressed at the onset of the carbachol-induced postural atonia, whereas the decrease in respiratory rate and the depressions of hypoglossal and intercostal activities persisted until the response was reversed by a pontine microinjection of atropine 15-101 minutes after the onset of carbachol response. Ventilation was reduced to 70% of control during the steady-state conditions. The irregularity of breathing, characterized by the inter-quartile ranges of the distributions of the peak phrenic nerve activity and respiratory timing, did not increase following pontine carbachol. Neither vagotomy nor vigorous eye movements were associated with increased breathing irregularity. This contrasts with the irregular breathing (with minor average changes in ventilation) typical of natural REM sleep. We propose that the carbachol-injected decerebrate cat provides a useful model of the depressant effects that neural events associated with REM sleep may have on breathing.

Serotonergic excitatory drive to hypoglossal motoneurons in the decerebrate cat.

In decerebrate, paralyzed, vagotomized and artificially ventilated cats, serotonin (5-HT) and its analogues, microinjected into the hypoglossal (XII) motor nucleus, altered the activity of the genioglossal branch of XII nerve. 5-HT, carboxamidotryptamine maleate (5-CT) and DOI (1-5 mM) increased the activity by over 200%. Methysergide reversed this increase. Methysergide, mianserin, or ketanserin (100-250 nl, 1 mM) reduced the spontaneous hypoglossal activity by 20-50%. Buspirone, 8-OH-DPAT and (-)-propranolol were without effect. Thus, 5-HT provides a substantial tonic excitatory drive to XII motoneurons. The 5-HT receptors involved are likely to be type 1C or 2, but uncertainty regarding the affinity profiles of the drugs used in in vivo conditions in the cat precludes a definite identification.

The medullary projections of afferent bronchopulmonary C fibres in the cat as shown by antidromic mapping.

1. The activity of eighty-seven bronchopulmonary vagal afferent neurones with unmyelinated axons (C fibres) was recorded extracellularly in the nodose ganglia of decerebrate, paralysed and artificially ventilated cats. On the basis of their response latencies following the right atrial injection of capsaicin or phenyldiguanide, the cells were classified as having their receptor endings within the reach of pulmonary (latency less than 3.5 s) or bronchial (latency above 3.5 s) circulation. 2. Pulmonary and bronchial receptor cells differed only slightly in their response characteristics (firing rate, burst duration) and the conduction velocity of their peripheral axons. Bronchial C fibres represented about 70% of the population studied. 3. The medullary distributions of the central branches of six pulmonary and six bronchial C fibres were determined by means of the antidromic mapping technique. The two receptor subtypes did not differ in their central projection patterns. 4. Rostral to the obex, the central branches of the bronchopulmonary C fibres were localized within the medial portions of the nucleus tractus solitarii (NTS) and area postrema, and were most densely distributed along the borders of the parvicellular subnucleus of the NTS. Caudal to the obex, the most dense branching was found in the dorsal portion of the commissural subnucleus. Projections to the contralateral NTS were found, but these were of a much lower density. 5. The central distribution of bronchopulmonary C fibres is compared to the projection patterns of vagal and glossopharyngeal afferents of other modalities that are involved in respiratory and cardiovascular control. This is discussed in relation to the concept of a modality-specific organization of the NTS.

Cholinergic stimulation of the pons depresses respiration in decerebrate cats.

The injection of carbachol into the pontine tegmentum of decerebrate cats evokes a postural motor atonia that has many of the characteristics of the atonia of natural rapid-eye-movement (REM) sleep (Morales et al. J. Neurophysiol. 57: 1118-1129, 1987). We have used the carbachol-injected decerebrate cat to study the changes in respiratory neuronal activity that accompany the atonia. The activities of representative respiratory motor nerves--phrenic, intercostal, and hypoglossal--and that of a motor branch of C4 were recorded in decerebrate, vagotomized, paralyzed, and artificially ventilated cats. After the microinjection of carbachol, there was a profound suppression of activity in all the nerves and a decrease in respiratory rate. This was a consistent stereotyped response in which the magnitude of the suppression of respiratory-related activity was phrenic (to approximately 65% of control) less than inspiratory intercostal (approximately 50%) less than hypoglossal (approximately 10%) less than expiratory intercostal (approximately 5%). The decrease in respiratory rate (to approximately 70% of control) was caused by a prolongation of both inspiratory and expiratory durations. Complete reversal of the carbachol effect was elicited by the microinjection of atropine into the same site as the carbachol injection. This allowed us to produce a second episode of atonia by the injection of carbachol into the contralateral pons. Thus we have demonstrated the existence of neural pathways originating in the cholinoceptive cells of the pons that have the potential to powerfully and differentially depress various respiratory motoneuronal pools and to reduce the respiratory rate. These pathways are likely to be activated along with the atonia of REM sleep.

Effect of dorsolateral pontine lesions on diaphragmatic activity during REMS.

Muscle atonia is a feature of normal rapid-eye-movement sleep (REMS). The suppression of accessory respiratory muscle activity has been investigated and a role for sleep-disordered breathing hypothesized, but the suppression of diaphragmatic activity has rarely been considered. We hypothesized that the activity of the diaphragm was suppressed by an area of the dorsolateral pons during REMS. Lesions in this region have previously been shown to abolish the atonia of REMS. The diaphragmatic electromyogram (EMG) activity was analyzed in five naturally sleeping cats before and after pontine lesions leading to REMS without atonia. Although respiratory timing parameters were not altered by the lesion, the inspiratory rate of rise was significantly increased in all cats, and the brief pauses (40-100 ms) in the diaphragmatic EMG normally seen in REMS were virtually abolished. We conclude that the dorsolateral pons has a role in suppressing diaphragmatic activation during REMS. This suppression affects the average rate of rise of diaphragmatic activity and also leads to brief intermittent complete cessation of ongoing muscle activity. These decrements in diaphragm activity could jeopardize ventilation during REMS.

Startle-evoked changes in diaphragmatic activity during wakefulness and sleep.

Tonic inhibition of some respiratory muscles occurs as part of the generalized muscle atonia of rapid-eye-movement sleep (REMS). A second type of inhibition of the diaphragm during REMS, fractionations, consists of brief pauses in the diaphragmatic electromyogram (DIA EMG) in association with phasic events. Because motor inhibition can occur as part of the startle response, and the brain is highly activated during REMS, we hypothesized that the neural basis of the fractionations might be activation of a startle network. To test this hypothesis, tone bursts (100 dB, 20-ms duration at 15-s intervals) were applied to cats at a fixed inspiratory level in the DIA moving average during REMS, non-rapid-eye-movement sleep (NREMS), and wakefulness. Parallel sham studies (no tone applied) were obtained for each state. The response of the DIA EMG was averaged over 100 ms by using the tone pulse as a trigger, and the following parameters of the DIA EMG were measured: latency to peak and/or nadir, increment or decrement in activity, and duration of peak and/or nadir. After a tone, all five animals studied displayed a profound suppression of DIA activity during REMS (latency to nadir 42.4 +/- 10.0 ms, duration of suppression 35.9 +/- 17.6 ms). Similarly, DIA activity was suppressed in all cats during NREMS (latency to nadir 40.9 +/- 13.3 ms, duration 23.9 +/- 13.4 ms). An excitatory response was observed in only two cats during NREMS and wakefulness. The similarity of startle-induced DIA EMG pauses to spontaneous fractionations of DIA activity during REMS suggests that the latter result from activation of a central startle system.

Sites of termination and relay of pulmonary rapidly adapting receptors as studied by spike-triggered averaging.

The sites of termination and relay of pulmonary rapidly-adapting receptors (RARs) were determined by averaging the extracellular field potentials produced in the nucleus tractus solitarii of the cat by individual RAR neurons. Action potentials of individual RARs were recorded extracellularly in the nodose ganglion during mechanical stimulation of the receptive field in the lung and used as triggers for the averaging. The averaged records (2000-4000 sweeps) revealed the presence of terminal and focal synaptic potentials. These potentials, indicating the presence of pre- and postsynaptic elements at the recording site, were found ipsilaterally in the caudal medial and commissural subnuclei and contralaterally in the commissural subnucleus.

Role of medullary inspiratory neurones in the control of the diaphragm during oesophageal stimulation in cats.

1. The effect of oesophageal distension and swallowing on the activity of medullary respiratory neurones was recorded in decerebrate, spontaneously breathing cats. The distension, produced by inflating a balloon in the thoracic portion of the oesophagus, was of sufficient magnitude to induce inhibition of the peri-oesophageal part of the crural diaphragm, with little effect on the respiratory function of the diaphragm as measured by the activity in the C5 branch of the phrenic nerve. 2. 424 neurones were tested. They were located bilaterally, in the region of the nucleus tractus solitarius (dorsal respiratory group) or the ambiguous complex (ventral respiratory group). No cell exhibited a change in activity during periods of strong inhibition of crural electrical activity induced by distension or swallowing. The activity of all cells paralleled that of the C5 phrenic neurogram, which was unaffected by the tests. 3. We conclude that the reflex inhibition of the crural diaphragm during oesophageal distension does not result from an inhibition of medullary premotor inspiratory neurones of the dorsal and ventral groups. Additional central pathways must exist that inhibit motoneurones to the crural diaphragm during gastrointestinal reflexes.

Biotransformation of sulindac in end-stage renal disease.

In normal humans sulindac, a prodrug, undergoes two major biotransformations: irreversible oxidation to the inactive sulfone metabolite and reversible reduction to the pharmacologically active sulfide metabolite. To assess any effect of end-stage renal failure on sulindac biotransformation, six patients were given 200 mg sulindac orally. Plasma was sampled over 24 hours. Protein binding of sulindac and metabolites was determined by equilibrium dialysis. Results were compared with historic controls. AUC(0-12) for sulindac and the sulfone were similar to controls. AUC(0-12) for the sulfide was significantly reduced to 4.85 micrograms X hr/ml from 13.1 micrograms X hr/ml (P less than 0.02). Protein binding of all three compounds was significantly reduced by renal failure. When corrected for protein binding, the AUC(0-12) for sulindac and the sulfone was twice that of controls whereas that of the sulfide was 42 ng X hr/ml compared with 83 ng X hr/ml in normal individuals (P less than 0.001). This suggests that end-stage renal failure impairs the reduction of sulindac to the active sulfide whereas oxidation to the sulfone is intact.