Influence of laryngeal CO2 on respiratory activities of motor nerves to accessory muscles.

Intralaryngeal CO2 in decerebrate, vagotomized cats decreases phrenic nerve activity and increases the respiratory activity of the hypoglossal (HG) nerve. These responses are mediated by afferents in the superior laryngeal nerves. To explore the responses of other respiratory motor nerves to this stimulus, we have recorded the activities of the nasolabial (NL) branch of the facial nerve, the posterior cricoarytenoid (PCA) and thyroarytenoid (TA) branches of the recurrent laryngeal nerve and the nerve to triangularis sterni (TS) muscle. In response to 5 and 10% CO2 in the surgically isolated upper airway, we found dose-related decreases in phrenic activity, increases in HG and NL activity and characteristic, but intermittent, exaggeration of early expiratory bursts of TA activity. The activities of the PCA and TS nerves showed no consistent responses. These results broaden the definition of the reflex response to intralaryngeal CO2, revealing components that reflect ventilatory inhibition, upper airway dilation and laryngeal protection.     

Naloxone enhances the response to hypercapnia of spinal and cranial respiratory nerves

To assess the effects of endogenous opiates on respiratory muscle responses to CO2, naloxone was administered intravenously to paralyzed, vagotomized and artificially ventilated cats anesthetized with alpha-chloralose. Neural activity was recorded from the phrenic, hypoglossal (HG), glossopharyngeal (GP) and recurrent laryngeal (RL) nerves. Before naloxone, phasic activity began first in the phrenic at a PETCO2 of 30.0 +/- 1.8 Torr, followed by the RL at a PETCO2 of 33.5 +/- 1.7 Torr, the HG at a PETCO2 of 39.9 +/- 2.1 Torr and the GP at a PETCO2 of 42.5 +/- 2.2 Torr during CO2 rebreathing. Naloxone had no significant effect on the apneic threshold of any of the nerves studied. Naloxone did, however, increase respiratory frequency (P less than 0.01) mainly by causing a significant (P less than 0.01) shortening of TE as it had no significant effect on TI. Naloxone also significantly increased the rate at which peak nerve activity increased with CO2 in the HG (P less than 0.01) and the GP (P less than 0.01) nerves, but not in the phrenic and RL nerves. Instead, the maximum activity produced by hypercapnia and the PETCO2 level at which maximum activity occurred in the phrenic, but not the RL, increased after naloxone. The result of these effects was that naloxone extended the range over which the HG and GP behaved proportionally with the phrenic, but it did not change the curvilinear nature of these relationships.     

Phrenic and hypoglossal neural responses to cold airflow in the upper airway.

Cold air flowing through the larynx is known to alter the activities of laryngeal receptors with afferents in the superior laryngeal nerves (SLNs) and to induce reflex apnea in neonatal mammals. To examine the ventilatory response in adult animals and to explore associated upper airway motor responses, we recorded phrenic and hypoglossal neural responses to cooling the isolated larynx with cold air in decerebrate, vagotomized, paralyzed, ventilated cats. The most consistent response was phrenic inhibition, which occurred in all animals tested. Either excitation or inhibition of hypoglossal activity was seen consistently in individual cats, with the result that the group response was not statistically significant. All responses to laryngeal cooling were abolished by section of the SLNs. The findings confirm that directing cold air through the larynx causes reflex inhibition of ventilatory (phrenic) activity, but raise new questions as to how the two, directionally opposite hypoglossal responses are mediated.     

Recurrent hypoxic exposure and reflex responses during development in the piglet

The effects of recurrent hypoxia on cardiorespiratory reflexes were characterized in anesthetized piglets at 2-10 d (n=15), 2-3 weeks (n=11) and 8-10 weeks (n=8). Responses of phrenic and hypoglossal electroneurograms (ENG(phr) and ENG (hyp)) to hypoxia (8% 0(2), bal N(2), 5 min), hypercapnia (7% CO(2) bal O(2), 5 min) and intravenous capsaicin were tested before and after recurrent exposure to 11 episodes of hypoxia (8% O(2) bal N(2), 5 min). In piglets 2-10 d, ENG(phr) response to hypoxia declined in proportion to the number of hypoxic exposures; however, ENG (hyp) response to hypoxia was unchanged. In piglets at 2-10 d, intracisternal injection of bicuculline (GABA(A) receptor antagonist) reversed effects of recurrent hypoxia on ENG(phr) hypoxic response, eliminated apnea during hypoxia, as well as the delay in appearance of ENG(phr) after hypoxia. The ENG(phr) response to 7% CO(2) inhalation also decreased after recurrent hypoxia; however, the ENG(phr) response to C-fiber stimulation by capsaicin was unaltered. Piglets at 2-3 and 8-10 weeks were resistant to the depressive effects of recurrent hypoxia on respiratory reflex responses. We conclude that the response of the anesthetized newborn piglet to recurrent hypoxia is dominated by increasing inhibition of phrenic neuroelectrical output during successive hypoxic exposures. Central GABAergic inhibition may contribute significantly to the cumulative effects of repeated hypoxia in the newborn piglet experimental model.     

Selective depression by ethanol of upper airway respiratory motor activity in cats

We studied the effects of systemically administered ethyl alcohol on the respiratory motor activity of the phrenic, hypoglossal and recurrent laryngeal nerves in unanesthetized, decerebrate cats. Some of the cats were studied after carotid sinus nerve section. In addition, parallel studies were done in intact, awake cats with chronic electromyographic electrodes in the diaphragm, genioglossus, and posterior cricoarytenoid (PCA) muscles. In decerebrate animals, alcohol induced a significant reduction of hypoglossal and recurrent laryngeal nerve activities at doses that had little or no effect on the phrenic nerve discharge. Similar changes were observed in chemodenervated cats. In awake animals, genioglossal and PCA muscle activities were depressed by alcohol, whereas diaphragm activity showed no consistent change. Alcohol caused a significant increase in respiratory frequency in awake cats and reduced the responses of genioglossal and PCA muscle activities to hypercapnia and normocapnic hypoxia. We conclude that alcohol induces a selective reduction in upper airway respiratory motor activity by an action that does not require intact suprapontile structures, vagal afferents, or peripheral chemoreceptors. This reduction may contribute to the alcohol-induced exacerbation of obstructive sleep apnea.     

Hypoglossal motoneuron responses to pulmonary and superior laryngeal afferent inputs

In decerebrate, paralyzed cats ventilated with a cycle-triggered pump, the inspiratory discharges of the hypoglossal (whole nerve or single fibers), phrenic, and recurrent laryngeal nerves were compared, and the effects of pulmonary and superior laryngeal afferent inputs were observed. During lung inflations in phase with neural inspiration, hypoglossal and recurrent laryngeal activities differed from phrenic with respect to (a) burst onset times: both preceded the phrenic; (b) overall pattern: phrenic, augmenting; hypoglossal, decrementing; recurrent laryngeal, plateau-like. When inflation was withheld, the phrenic pattern was not markedly changed, but both hypoglossal and recurrent laryngeal became augmenting; the marked increase of hypoglossal activity (both whole nerve and single fiber) indicated strong inhibition by lung afferents. Superior laryngeal electrical stimulation evoked excitation of the contralateral phrenic (latency 4.1 msec) and the ipsilateral whole hypoglossal (latency 5.3 msec), followed by bilateral inhibitions (durations 20-30 msec); most hypoglossal fibers showed only inhibition. We conclude that, although both hypoglossal and phrenic outputs are driven by the inspiratory pattern generator(s), their promotor systems differ with respect to influences from central and peripheral inputs.     

Differential elevation by protriptyline and depression by diazepam of upper airway respiratory motor activity

Effects of systemically administered protriptyline and diazepam on the respiratory activity of the phrenic, hypoglossal, and recurrent laryngeal nerves were investigated in vagotomized, decerebrate cats. Both hypoglossal and recurrent laryngeal nerve activities were consistently increased after protriptyline administration, whereas the phrenic nerve discharge was not systematically altered. Similar changes were observed in cats with bilateral carotid sinus nerve sections. Diazepam induced a reduction of hypoglossal and recurrent laryngeal nerve activities at doses that did not alter phrenic nerve discharge. These results with diazepam were the same in carotid chemodenervated cats. We conclude that neural mechanisms controlling upper airway muscles are much more sensitive to protriptyline and diazepam than are those of the bulbospinal-phrenic system. The selective augmentation of hypoglossal and recurrent laryngeal discharges by protriptyline could account for the reported decrease in the frequency of obstructive sleep apneas in patients receiving this antidepressant. In contrast, diazepam, by depressing motor activity to upper airway muscles, may exacerbate oropharyngeal obstruction during sleep.     

Dynamic changes of hypoglossal and phrenic activities by hypoxia and hypercapnia

Steady-state responses of unanesthetized subjects to hypercapnia or hypoxia provide no evidence that chemoreceptor afferents are differentially distributed upon hypoglossal and bulbospinalphrenic neurons, as suggested by results in anesthetized animals. We hypothesized that dynamic changes in activities of phrenic and hypoglossal nerves might differ following sudden alterations of inspired gases. This hypothesis was based on the observation that episodes of obstructive apnea may follow central apnea. The obstruction might reflect phrenic activity increasing more quickly than that of the hypoglossal upon resumption of ventilation. In decerebrate, vagotomized, paralyzed and ventilated cats, we recorded phrenic and hypoglossal activities before and during abrupt, sustained exposure to hypercapnia, hypoxia and hypoxic hypercapnia, and following sudden withdrawal of these stimuli. For all such manoeuvres, activities of phrenic and hypoglossal nerves increased or decreased in parallel fashion. Our findings cause rejection of the hypothesis of differing dynamic phrenic and hypoglossal responses to chemoreceptor stimuli. The concept that the ventilatory control system is well organized to prevent upper airway obstructions is discussed.     

Respiratory and vasomotor responses to focal cooling of the ventral medullary surface (VMS) of the rat

Experiments were performed on anesthetized, paralyzed and artificially ventilated rats after denervation of the vagus and carotid sinus nerves. The electrical activity of the phrenic and cervical sympathetic nerves (CS) along with the arterial blood pressure (BP) were monitored. Graded unilateral cooling of the ventral lateral surface (VMS) from 37 degrees C to 10 degrees C between 6th and 12th nerve rootlets did not affect the phrenic activity. Whereas, a significant depression or apnea was seen with cooling of an area between 1st cervical and 12th nerve rootlets. Bilateral cooling also produced similar respiratory responses. Respiratory depression could also be obtained during higher respiratory drive (7% CO2 in O2). On the other hand, a significant fall in BP and reduction in CS activity were observed with unilateral cooling in any of these VMS areas. However, the magnitude of BP decrease was less with 7% CO2 in O2 compared to 100% O2 breathing.     

Influence of lung volume on respiratory responses to spontaneous bladder contractions

Spontaneous bladder contractions (SBCs) in decerebrate, vagotomized, paralyzed, ventilated cats have been shown to decrease phrenic and hypoglossal inspiratory nerve activities, as well as the activities of other respiratory motor nerves. To determine whether vagal afferents from the lung influence the respiratory inhibition associated with SBCs, we recorded phrenic and hypoglossal nerve activities in decerebrate, paralyzed, vagally intact cats. The animals were ventilated by a servo-respirator, which inflated the lungs in accordance with integrated phrenic nerve activity. Maintained increases in end-expiratory lung volume were produced by the application of 2–10 cm H₂O positive end-expiratory pressure (PEEP). SBCs were accompanied by decreases in both phrenic and hypoglossal peak integrated nerve activities, as well as by marked decreases in respiratory frequency. The reduction of respiratory frequency was greater with higher levels of PEEP, a few animals becoming apneic during SBCs. After bilateral vagotomy, SBCs continued to decrease phrenic and hypoglossal peak integrated nerve activities as previously reported, but the reduction of respiratory frequency was much less striking than when the vagi were intact. These results indicate that activity of vagal afferents from the lung augments the respiratory influence of SBCs. Furthermore, SBCs in vagally intact animals can induce periodic breathing.     

Influence of extreme hypercapnia on respiratory motor nerve activity in cats

Sedative drugs have been found to depress the respiratory activity of upper airway muscles more than that of the diaphragm. To determine whether CO2 at narcotic levels has a similar action, we recorded phrenic and hypoglossal nerve activities in decerebrate, vagotomized, paralyzed cats. T5 or T6 external intercostal nerve activity was also recorded in some animals. End-tidal CO2 concentration was raised progressively to over 30% or until depression of nerve activity was apparent. Respiratory frequency was reduced by severe hypercapnia in most cats. Hypoglossal nerve activity was consistently decreased more than that of the phrenic nerve. In most cases intercostal nerve activity was also more susceptible than phrenic nerve activity to hypercapnic depression. The results indicate that CO2 at narcotic levels interferes both with the central pattern generator for breathing movements and with the expression of the pattern in specific motor nerves.     

Afferent pathways for hypoglossal and phrenic responses to changes in upper airway pressure

Our purpose was to determine the afferent pathways underlying reflexes by which changes in upper airway pressure induced alterations in hypoglossal and phrenic nerve activities. An isolated upper airway was produced in decerebrate, vagotomized, paralyzed and ventilated cats. Efferent activities of the phrenic and hypoglossal nerves were monitored. Hypoglossal activity significantly increased following pressure changes in the upper airway of -4 to -21 cm H2O; phrenic discharge declined in most trials. Similar alterations of neural activities were induced by positive pressures though changes of +14 to +21 cm H2O were required for significant responses. These changes in hypoglossal and phrenic activities were greatly reduced following bilateral sectionings of the superior laryngeal nerves but were augmented after the pharyngeal branches of the glossopharyngeal nerves were sectioned. Additional bilateral destruction of the trigeminal nerves almost entirely eliminated responses to pressure changes. We conclude that upper airway receptors may serve to maintain patency of the upper airways. These receptors may play a crucial role in promoting release from upper airway obstructions, especially in sleep.     

Role of the medullary raphe nuclei in the respiratory response to CO2

We characterized the role of neurons within the midline of the medulla oblongata on phrenic and hypoglossal nerve responses to hypercapnia during early development. Studies were performed on decorticate or anesthetized, vagotomized and mechanically ventilated 14–20 day old piglets. Reversible withdrawal of midline neuronal activity was induced by microinjections of lidocaine (2%, 300 nl; n=10) and lesioning was caused by microinjections of the neurotoxic agent, ibotenic acid (n=12), at the same sites. At any given end-tidal CO₂, peak phrenic and hypoglossal activities after lidocaine were significantly lower than in the control period (P<0.01). Similarly, 1–2 h after injections of ibotenic acid, both phrenic and hypoglossal nerve responses to CO₂ were significantly lower than in the control period (P<0.01). The results indicate for the first time that the medullary midline neurons are required for full expression of ventilatory responses to hypercapnia and raise the possibility that dysfunction of these nuclei may contribute to respiratory instability during early postnatal life.     

Reversal of the relation between respiratory drive and airway tone in cats

To examine the relationship between respiratory drive and airway tone in the exercise pressor reflex in the cat, we recorded tension in a tracheal segment and activity in the phrenic nerve, before and after injecting capsaicin in various doses (0.3-20 micrograms/kg) into the femoral artery. Injection of all doses of capsaicin relaxed the tracheal segment. However, high doses of capsaicin evoked neural apnea followed by increased phrenic nerve activity whereas low doses evoked only increased phrenic nerve activity. All responses were abolished by cutting hindleg nerves. We were certain that relaxation was due to decreases of parasympathetic bronchoconstrictor activity and not to increases in activity of other inhibitory pathways, because we found no change in capsaicin-evoked relaxation after beta-adrenergic blockade with propranolol and no capsaicin-evoked relaxation after muscarinic blockade with atropine and restoration of tone with 5-hydroxytryptamine. These results provide good evidence that injecting capsaicin into the femoral artery reverses the direct relation between respiratory drive and airway tone and does so by decreasing parasympathetic bronchoconstrictor activity.     

Similarities in reflex control of laryngeal and cardiac vagal motor neurones

We sought to test the hypothesis that laryngeal adductor and cardiac vagal motor neurones respond similarly to the activation of certain afferent inputs. Experiments were performed on a working heart-brainstem preparation of rat devoid of pulmonary stretch receptor feedback. Upper airway negative pressure receptors (UANPR), peripheral arterial chemoreceptors and receptors at the junction of the pharynx and oesophagus were stimulated selectively while recording heart rate, recurrent laryngeal, phrenic and hypoglossal motor outflows, subglottic pressure during constant translaryngeal airflow (as an index of laryngeal resistance), and single unit respiratory neurone activity. Stimulation of all three receptor types produced bradycardia, evoked discharges in the recurrent laryngeal and hypoglossal motor outflows during the post-inspiratory period and caused swallowing. Stimulation of pharyngoesophageal receptors and peripheral chemoreceptors evoked an increase in laryngeal resistance during the post-inspiratory phase indicative of laryngeal adductor motoneurone activation. Although this reflex response cannot be evaluated during UANPR stimulation, some post-inspiratory neurones were powerfully activated suggesting that UANPR probably drive laryngeal adductor muscles. Our data show that motor outflows controlling cardiac rate and laryngeal patency are concurrently activated by these sensory inputs. This may constitute the basis for a stereotyped defensive reflex response which maintains end expiratory lung volume, thus conserving oxygen in conditions of upper airway obstruction. Our observations lend further support to models of cardiorespiratory control which propose close coupling and shared central mechanisms for the regulation of the cardiovascular and respiratory systems.     

Influence of reticular mechanisms upon hypoglossal, trigeminal and phrenic activities

Studies were undertaken to evaluate the hypothesis that mechanisms within the reticular formation influence activities of nerves to muscles of the upper airways more than the bulbospinal-phrenic system. In decerebrate, vagotomized, paralyzed and ventilated cats, activities of the phrenic, trigeminal, and the hypoglossal nerves were monitored. Activity of the pontile and medullary reticular formation was increased directly by electrical stimulation within the brainstem and indirectly by stimulating the sciatic nerve. Trigeminal and hypoglossal discharges increased more than phrenic during stimulations at many brainstem loci. Changes were typically maintained for one or more respiratory cycles following termination of stimulation. At some loci, activation of neurons by microinjections of glutamate increased trigeminal and hypoglossal activities more than phrenic. Although responses were extremely variable, activities of the trigeminal and/or hypoglossal nerves usually increased more than phrenic during stimulations of the sciatic nerve or upon termination of stimulation. The results support the conclusion that respiratory-modulated trigeminal and hypoglossal discharges are dependent upon reticular mechanisms for their expression.     

Effects of focal cooling in the ventrolateral medulla on chemoresponsiveness in dogs

Studies in cats and dogs have shown that the ventrolateral region of the medulla participates significantly in the shaping of the respiratory rhythm. The purpose of this study was to examine the effects of unilateral focal cooling (15-20 degrees C) in the ventrolateral medullary region on respiratory responses to hypercapnia and hypoxia in dogs. A cryoprobe was used to cool selected locations in the ventrolateral medulla in 9 anesthetized and vagotomized dogs. Diaphragmatic electromyogram (EMG) was measured with implanted electrodes. The animals were ventilated artificially at a constant rate with 100% O2 and the inspired gas was switched to 7% CO2 in O2 or 10% O2 in N2 to determine the response to hypercapnia or hypoxia. The sites cooled ranged 4.0-8.0 mm rostral to obex, 3.0-5.5 mm lateral to midline, and within 1.5 mm deep from the ventral surface of the medulla. Unilateral focal cooling in this region significantly decreased the responses of both the amplitude and the rate of rise of diaphragmatic EMG to hypercapnia and hypoxia. These results support the hypothesis that neural structures in the ventrolateral medulla are important in the respiratory responses to hypoxia and hypercapnia as well as for the setting of respiratory drive and timing.     

Responses of hypoglossal and phrenic nerves to decreased respiratory drive in cats

Agents which depress respiration, such as alcohol, seem to increase the occurrence of obstructive apneas during sleep. It has been proposed that upper airway obstruction can result from an imbalance in the activity (or forces) produced by the upper airway muscles versus the chest wall muscles so that upper airway passages might be blocked when a disproportionate decrease in upper airway muscle activity occurs. This study examines the hypothesis that depression of respiration affects the activity of the hypoglossal nerve (the motor nerve to the tongue) more than the activity of the phrenic nerve (the motor nerve to the diaphragm). In addition, we examined the role of the putative central chemoreceptor area on the ventrolateral medullary surface (VMS) in maintaining phrenic and hypoglossal discharge. In chloralose-anesthetized, artificially ventilated, paralyzed cats, three methods of reducing respiratory drive were studied: hyperoxic hypocapnia (produced by mechanical hyperventilation), the application to the intermediate area of the ventral medullary surface of the respiratory depressant GABA and its agonist muscimol, and cooling the same area of the VMS (using a water-cooled thermode). All these interventions decreased hypoglossal nerve activity more than phrenic nerve activity (range of p values: p less than 0.001 to p less than 0.01). Moreover, the reduction in hypoglossal activity was greater with GABA and muscimol than with the other two maneuvers; this was statistically significant for both GABA versus VMS cooling (p less than 0.02) and muscimol versus VMS cooling (p less than 0.01). These results show that respiratory depression can differentially affect hypoglossal and phrenic nerve activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Influence of lung volume on phrenic, hypoglossal and mylohyoid nerve activities

In decerebrate, paralyzed cats, ventilated by a servo-respirator in accordance with phrenic nerve activity, we examined the influence of lung volume on the activities of the phrenic, hypoglossal and mylohyoid nerves. When lung inflation was briefly withheld, the durations of inspiration (TI) and expiration (TE) and the activities of all three nerves increased. The relative increase in hypoglossal activity greatly exceeded that of phrenic activity and was apparent earlier in the course of inspiration. This hypoglossal response was enhanced by hypercapnia and isocapnic hypoxia. The responses of mylohyoid activity were quite variable: withholding lung inflation augmented inspiratory activity in some cats, but expiratory discharge in others. Sustained increases in end-expiratory lung volume were induced by application of 3-4 cm H2O of positive end-expiratory pressure (PEEP). Steady-state PEEP did not influence nerve activities or the breathing pattern. Bilateral vagotomy increased TI, TE, and the activities of all three nerves. No response to withoholding lung inflation could be discerned after vagal section. The results provide further definition of the influence of vagally mediated, lung volume dependent reflexes on the control of upper airway muscles. These reflexes are well suited to relieve or prevent upper airway obstruction.     

The effects of hypercapnia and hypoxia on single hypoglossal nerve fiber activity

The respiratory related modulation of hypoglossal nerve activity has been studied at the single fiber level in cats under hyperoxic hypercapnia and hypoxic conditions and their conduction velocities determined. Changes in fiber activity were compared to simultaneous changes occurring in phrenic activity. Three different kinds of discharge patterns were observed: (a) inspiratory, (b) phasic activity during both inspiration and expiration, and (c) continuous random activity with no respiratory modulation. These fibers could be grouped into three categories according to their pattern of discharge during CO2 breathing. Type I fibers, mean conduction velocity of 30.0 m/sec, exhibited only an inspiratory phasic discharge during 100% O2 breathing. Their discharge frequency increased rapidly with higher levels of CO2 and hypoxia. Type II fibers, mean conduction velocity of 36.7 m/sec, had three different kinds of inspiratory-expiratory discharge patterns during 100% O2 breathing. With increasing hypercapnia or hypoxia fibers of this group discharged phasically during inspiration and discharge at low frequency during expiration. Type III fibers had a non phasic discharge pattern at 100% O2 breathing and at all levels of CO2 tested (up to 10%). Discharge frequency rose during CO2 rebreathing and hypoxia, but the rate of increase was much less than Type I and Type II fibers. Their mean conduction velocity was 41.3 m/sec. The inspiratory activity of Type I and II fibers increased their activity more than the phrenic during hypercapnia and hypoxia. Type II and Type III fibers are responsible at least in part for the tonic activity of the nerve.