Inferior pharyngeal constrictor electromyographic activity during permeability pulmonary edema in lambs

Diaz, Véronique, Irenej Kianicka, PatrickLetourneau, and Jean-Paul Praud. Inferior pharyngealconstrictor electromyographic activity during permeability pulmonaryedema in lambs. J. Appl. Physiol. 81(4): 1598-1604, 1996.Newborn mammals exhibit an active expiratory upper airwayclosure during the first hours of extrauterine life. We have recentlyshown that permeability pulmonary edema led to active expiratoryglottic closure in awake newborn lambs while hypoxia (inspiredO₂ fraction 8%; 15 min) did not. In the presentstudy, we tested the hypothesis that expiratory glottic closure wasaccompanied by an increase in pharyngeal constrictor muscle expiratoryelectromyographic (EMG) activity. We studied seven awake nonsedatedlambs aged 8-20 days. Airflow (facial mask + pneumotachograph),blood gases (arterial catheter), and EMG activity of both thethyroarytenoid muscle (a glottic adductor) and the inferior pharyngealconstrictor muscle were recorded before and after intravenous injectionof halothane (0.05 ml/kg) to induce a permeability pulmonary edema. Acentral apnea (duration 15 s to 5 min) with continuous thyroarytenoidand inferior pharyngeal constrictor activity was observed withinseconds after halothane injection. One lamb died despite rescuingmaneuvers. An expiratory phasic thyroarytenoid and inferior pharyngealconstrictor muscle activity with simultaneous zero airflow graduallytook place and, by 30 min after halothane injection, was present ateach expiration in the six remaining lambs. Expiratory glottic andpharyngeal constrictor muscle EMG activity was subsequently presentduring the whole study period (1.5-5 h), even after correction ofthe initial hypoxia. Permeability lung edema was present at postmortem examination in all seven lambs. We conclude that a permeability pulmonary edema induced by intravenous halothane in nonsedated lambsenhances both glottic and pharyngeal constrictor muscle expiratory EMG.We hypothesize that expiratory contraction of the inferior pharyngealconstrictor muscle could participate in the active expiratory upperairway closure; this, in turn, might improve alveolocapillary gasexchange by increasing the end-expiratory lung volume.

     

Laryngeal and abdominal muscle electrical activity during periodic breathing in nonsedated lambs

Kianicka, Irenej, Véronique Diaz, Sylvain Renolleau,Emmanuel Canet, and Jean-Paul Praud. Laryngeal and abdominal muscle electrical activity during periodic breathing in nonsedated lambs. J. Appl. Physiol. 84(2):669-675, 1998.We recently reported that glottic closure waspresent throughout central apneas in awake lambs. The present studytested whether glottic closure was also observed during periodicbreathing (PB). We attempted to induce PB in 21 nonsedated lambs onreturn from hypocapnic hypoxia to room air. Airflow and thyroarytenoid(a laryngeal constrictor, n = 16),cricothyroid (a laryngeal dilator, n = 10), and abdominal (n = 9) muscleelectrical activity (EMG) were monitored continuously. PB was observedin 16 lambs, with apneic phases in 8 lambs. Thyroarytenoid muscle EMGwas observed at the nadir of PB, either throughout apnea or withprolonged expiration during the lowest respiratory efforts. Phasicinspiratory cricothyroid muscle EMG and phasic expiratory abdominal EMGdisappeared at the nadir of PB. Active glottic closure at the nadir ofPB, without abdominal muscle contraction, could be a beneficialmechanism, preserving alveolar gas stores for continuing gas exchangeduring the apneic/hypopneic phase of PB. However, consequences ofactive glottic closure on ventilatory instability, either enhancing orreducing, are unknown.

     

Upper airway pressure-flow relationships and pharyngeal constrictor EMG activity during prolonged expiration in awake goats.

We undertook the present investigation to establish whether narrowing/closure of the upper airway occurs during spontaneous and provoked respiratory rhythm disturbances and whether pharyngeal constrictor muscle recruitment occurs coincident with upper airway occlusion during prolonged expiratory periods. Upper airway pressure-flow relationships and middle pharyngeal constrictor (mPC) EMG activities were recorded in 11 adult female goats during spontaneous and provoked prolongations in expiratory time (Te). A total of 213 spontaneous prolongations of expiration were recorded. Additionally, 169 prolonged expiratory events preceded by an augmented breath were included in the analyses. In separate trials on different days, Te was prolonged by systemic administration of dopamine, by raising the inspired fraction of O(2) from 0.10 to 1.00 during poikilocapnic conditions or by systemic administration of clonidine. Continuous tonic activation of the mPC EMG was observed during each prolonged Te period regardless of the duration or initiating cause. However, significant increases in subglottic tracheal pressure, with expiratory airflow braking indicative of upper airway narrowing or closure, was only observed during spontaneous events without a preceding augmented breath and during clonidine-induced events. Tonic mPC activation proved an unreliable indicator of airway occlusion. Furthermore, mPC muscle activation alone is not sufficient to induce pharyngeal occlusion during prolonged expiration. Our data suggest that airway closure is not a common occurrence during provoked respiratory disturbances in awake goats. We propose that airway closure, when present during prolonged Te, is more likely dependent on activation of laryngeal adductor muscles with glottic braking independent of pharyngeal narrowing.     

Effects of hypoxia and hypercapnia on nonnutritive swallowing in newborn lambs.

The aim of the present study was to investigate the effect of hypercapnia and hypoxia on apnea and nonnutritive swallowing (NNS) frequency, as well as on the coordination between NNS and phases of the respiratory cycle in newborn lambs, while taking into account the potential effects of states of alertness. Six lambs were chronically instrumented for recording electroencephalogram, eye movements, diaphragm and thyroarytenoid muscle (a glottal adductor) activity, nasal airflow, and electrocardiogram. Polysomnographic recordings were performed in nonsedated lambs exposed to air (control), 10% O(2), and 5% CO(2) in a random order at 3, 4, and 5 days of age. Although hypercapnia decreased apnea frequency in wakefulness and active sleep (P = 0.002 vs. air and hypoxia), hypoxia had no significant effect on apnea. In addition, although hypercapnia increased NNS frequency during wakefulness and quiet sleep (P < 0.005 vs. air and hypoxia), hypoxia tended to decrease NNS frequency. Finally, only hypercapnia altered NNS-breathing coordination by increasing NNS at the transition from inspiration to expiration (ie-type NNS; P < 0.001 vs. air and hypoxia). In conclusion, whereas hypercapnia increases overall NNS frequency by specifically increasing ie-type NNS, hypoxia has the inverse tendency. Results were identical in all three states of alertness.     

Vagal afferents and active upper airway closure during pulmonary edema in lambs.

The present study was undertaken to gain further insight into the mechanisms responsible for the sustained active expiratory upper airway closure previously observed during high-permeability pulmonary edema in lambs. The experiments were conducted in nonsedated lambs, in which airflow and thyroarytenoid and inferior pharyngeal constrictor muscle electromyographic activity were recorded. We first studied the consequences of hemodynamic pulmonary edema (induced by impeding pulmonary venous return) on upper airway dynamics in five lambs; under this condition, a sustained expiratory upper airway closure consistently appeared. We then tested whether expiratory upper airway closure was related to vagal afferent activity from bronchopulmonary receptors. Five bivagotomized lambs underwent high-permeability pulmonary edema: no sustained expiratory upper airway closure was observed. Finally, we studied whether a sustained decrease in lung volume induced a sustained expiratory upper airway closure. Five lambs underwent a 250-ml pleural infusion: no sustained expiratory upper airway closure was observed. We conclude that 1) the sustained expiratory upper airway closure observed during pulmonary edema in nonsedated lambs is related to stimulation of vagal afferents by an increase in lung water and 2) a decrease in lung volume does not seem to be the causal factor.     

Coordination between glottic adductor muscle and diaphragm EMG activity in fetal lambs in utero

It haspreviously been reported that active glottic adduction is presentduring prolonged apneas but absent during periods of breathingmovements in fetal lambs in utero. The present study was aimed atexamining the precise coordination between fetal breathing movements[diaphragm electromyographic (EMG) activity (Di EMG)] andglottic adduction [thyroarytenoid muscle EMG activity (TAEMG)]. Electrodes for electroencephalogram, eye movements, TAEMG, and Di EMG and an arterial catheter were surgically implanted infetal lambs 123-142 days postconception. Polygraphic recordings were performed without sedation while the ewe breathed room air (n = 11) or various gas mixtures(hypoxia, n = 5; hyperoxia,n = 4; hypercapnia,n = 5; hypercapnia+hyperoxia,n = 5). Tonic TA EMG was observedthroughout >90% of apneas (>6 s) in both non-rapid-eye-movement and rapid-eye-movement sleep, and when Di EMG frequency decreased inrapid-eye-movement sleep. In all but two fetuses, TA EMG was immediately inhibited when Di EMG appeared. Altering blood gases did not modify these results. In conclusion, Di EMG and TAEMG are well coordinated in late gestation in fetal lambs,except in a few cases. These findings may have consequencesfor understanding the pathogenesis of mixed/obstructiveapneas of prematurity.

     

Chemoreceptor and vagal influences on thyroarytenoid muscle activity in awake lambs during hypoxia.

This study was designed to identify the various controllers of thyroarytenoid (TA) activity in lambs during resting breathing, hypocapnic hypoxia, and isocapnic hypoxia. The TA muscle is known as the major adductor of the laryngeal aperture. We assumed that both the chemoreceptors and vagal nerves would interact to inhibit TA activity during hypoxia and to favor the occurrence of hyperpnea as a defense against hypoxia. We recorded TA activity directly in 11 awake lambs, aged 11 to 22 days, and studied them in three groups: four normals, four carotid body denervated, and three vagotomized. To test the contribution of the chemoreceptors to TA activity, we used pure O2 tests (Dejours' test) to silence the effects of the peripheral arterial chemoreceptors on the larynx during resting breathing and during the course of two hypoxia tests (the first: hypocapnic hypoxia; the second: isocapnic hypoxia). Our results confirmed 1) that both the peripheral arterial chemoreceptors and the vagal nerves inhibit the TA activity of 15-day-old lambs, during both resting and hypocapnic hypoxia conditions, and 2) that their effects override the hypocapnic effects that would otherwise recruit the TA muscle and close the glottis during hypocapnic hypoxia. We also found that vagotomy, or the pure O2 test, causes major recruitment of TA activity. These findings confirm that 15-day-old lambs are capable of using sustained hyperventilation as a means of fighting hypoxia, and that, because of the control of both the vagus nerves and the chemoreceptors, the laryngeal dynamic is able to keep the glottis aperture actively open, thereby favoring the hyperpnea.     

Diphasic ventilatory response to hypoxia in newborn lambs

The ventilatory response of newborn lambs to hypoxemia was evaluated in two groups of seven awake lambs studied at 2 and 7 days of life. Minute ventilation (VE) and airway occlusion pressure (P0.1) were monitored as the animals were exposed in sequence to room air, 12% O2 (15 min), 7% O2 (15 min), and room air. On 12 and 7% O2, 2-day-old lambs experienced a brisk hyperventilation followed by a VE depression, previously described in newborns of other species (diphasic response). The 7-day-old lambs had a clear diphasic VE response only on 7% O2 breathing. In the 2-day-old lambs, at the time of the relative VE depression to 12% O2, the respiratory centers showed a persisting responsiveness to further hypoxia; switching to 7% O2 caused a brisk increase in VE and P0.1 of 70 and 130%, respectively, which was followed again by a VE depression. The magnitude of the immediate VE response to hypoxia, taken as an index of the chemoreceptor strength, was inversely related to the magnitude of the VE depression (R = 0.81, P less than 0.001). It was concluded that 1) lambs as well as other neonates have an age-related diphasic VE response to hypoxia; 2) at the time of the VE depression, the respiratory centers maintain their responsiveness to further acute hypoxia; and 3) the weakness of the chemoreceptors in the newborn is a major determinant of the diphasic response.     

Thyroarytenoid muscle activity during loaded and nonloaded breathing in adult humans

Previous fiber-optic studies in humans have demonstrated narrowing of the glottic aperture in expiration during application of expiratory resistive loads. Nine healthy subjects were studied to determine the effect of expiratory resistive loads on the electromyographic activity of the thyroarytenoid (TA) muscle, a vocal cord adductor. Four of the nine subjects also underwent the application of inspiratory resistive loads and voluntary prolongation of either inspiratory (TI) or expiratory (TE) time. TA activity was recorded by intramuscular hooked-wire electrodes. During quiet breathing in all subjects, the TA was phasically active on expiration and often tonically active throughout the respiratory cycle. TA expiratory activity progressively increased with increasing levels of expiratory load. Inspiratory loads resulted in increased TA "inspiratory" activity. Voluntary prolongation of TE to times similar to those reached during loaded breathing induced increases in TA expiratory activity similar to those reached during the loaded state. Voluntary prolongation of TI was associated with an increase in TA inspiratory activity. Similar increases in TI during inspiratory loading or voluntary conditions were associated with comparable increases in TA inspiratory activity in three of the four subjects. In conclusion, increased activation of TA during the application of expiratory resistive loads implies that the reported narrowing of glottic aperture during expiratory loading is an active phenomenon. Changes in activation of the TA with resistive loads appear to be related to changes in respiratory pattern.     

Dynamics of breathing in the hypoxic awake lamb

Newborn mammals respond to hypoxia with an immediate hyperventilation that is rapidly dampened. Changes in mechanical properties of the respiratory system during hypoxia have been considered an important reason for this fall in minute ventilation (VE). We have studied the dynamic mechanical behavior of the respiratory system in eight unanesthetized intact newborn lambs (mean age 2 days) during normoxia and hypoxia (FIO2 = 0.08). Mouth pressure (P), airflow (V), and volume (V) were recorded while lambs were breathing through a leak-proof face mask and a pneumotachograph. Active compliance (C') and resistance (R') of the respiratory system were computed from P developed during an inspiratory effort against airway closure at end expiration and V and V of the preceding breaths. Tidal expiratory V-V curves were analyzed to estimate the elevation in functional residual capacity (FRC) over resting volume (Vr). After hypoxia, there was an immediate increase in VE in the first 2 min, from 0.49 to 1.13 l.kg-1.min-1, followed by a rapid decrease to 0.80. After 8 min of hypoxia, C' was unchanged. The inspiratory R' decreased during hypoxia, probably reflecting a drop in inspiratory laryngeal resistance. The expiratory V-V curves during hypoxia showed considerable braking, often with a double peak in expiratory V. This pattern was only occasionally seen during normoxia. In animals with a linear segment of the expiratory V-V curves the FRC-Vr difference could be calculated and averaged 1.93 ml/kg during normoxia and 3.47 during hypoxia. The recoil P of the respiratory system at end expiration was 0.75 cmH2O during normoxia vs. 1.63 cmH2O during hypoxia (P less than 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)     

Changes in respiratory movements of the human vocal cords during hyperpnea

Five healthy young subjects were studied to assess the changes in vocal cord movements that occur between resting breathing and hyperpnea. Both hypercapnia and exercise induced decreases in the extent of narrowing of the glottic aperture occurring during expiration. In addition, four of the subjects showed a significant positive rank correlation between the extent of narrowing of the glottis and the observed length of the expiratory phase of the respiratory cycle. These results indicate that the braking of expiratory airflow by movements of the vocal cords toward the midline is reduced during hyperpnea at the same time that expiratory time is decreased.     

Regulation of end-expiratory lung volume during sleep in premature infants

To investigate the regulation of end-expiratory lung volume (EEV) in premature infants, we recorded airflow, tidal volume, diaphragm electromyogram (EMG), and chest wall displacement during sleep. In quiet sleep, EEV during breathing was 10.8 +/- 3.6 (SD) ml greater than the minimum volume reached during unobstructed apneas. In active sleep, no decrease in EEV was observed during 28 of 35 unobstructed apneas. Breaths during quiet sleep had a variable extent of expiratory airflow retardation (braking), and inspiratory interruption occurred at substantial expiratory flow rates. During active sleep, the expiratory flow-volume curve was nearly linear, proceeding nearly to the volume axis at zero flow, and diaphragm EMG activity terminated near the peak of mechanical inspiration. Expiratory duration (TE) and inspiratory duration (TI) were significantly shortened in quiet sleep vs. active sleep although tidal volume was not significantly different. In quiet sleep, diaphragmatic braking activity and shortened TE combined to maintain EEV during breathing substantially above relaxation volume. In active sleep, reduced expiratory braking and prolongation of TE resulted in an EEV that was close to relaxation volume. We conclude that breathing strategy to regulate EEV in premature infants appears to be strongly influenced by sleep state.     

Smooth muscle dynamics and maximal expiratory flow in asthma.

A computational model for maximal expiratory flow in constricted lungs is presented. The model was constructed by combining a previous computational model for maximal expiratory flow in normal lungs and a previous mathematical model for smooth muscle dynamics. Maximal expiratory flow-volume curves were computed for different levels of smooth muscle activation. The computed maximal expiratory flow-volume curves agree with data in the literature on flow in constricted nonasthmatic subjects. In the model, muscle force during expiration depends on the balance between the decrease in force that accompanies muscle shortening and the recovery of force that occurs during the time course of expiration, and the computed increase in residual volume (RV) depends on the magnitude of force recovery. The model was also used to calculate RV for a vital capacity maneuver with a slow rate of expiration, and RV was found to be further increased for this maneuver. We propose that the measurement of RV for a vital capacity maneuver with a slow rate of expiration would provide a more sensitive test of smooth muscle activation than the measurement of maximal expiratory flow.     

Laryngeal muscle response to phasic and tonic upper airway pressure and flow.

The hypothesis that respiratory modulation due to upper airway (UA) pressure and flow is dependent on stimulus modality and respiratory phase-specific activation was assessed in anesthetized, tracheotomized, spontaneously breathing piglets. Negative pressure and flow applied to the isolated UA at room or body temperature during inspiration only enhanced posterior cricoarytenoid muscle activity from that present without UA pressure and flow (baseline) by 15--20%. Time shifting the onset of UA flow relative to tracheal flow decreased this enhancement. The same enhancement was observed with oscillatory or constant airflow. UA positive pressure and flow at room or body temperature applied during expiration only enhanced thyroarytenoid muscle activity from baseline by 50--160%. The same enhancement was observed with oscillatory or constant airflow at body temperature. Constant positive pressure and flow enhanced thyroarytenoid muscle activity more than oscillatory pressure and flow at room temperature. We conclude that the respiratory modulation of UA afferents is processed in a phase-specific fashion and is dependent on stimulus modality (tonic vs. phasic).     

Modulation of laryngeal and respiratory pump muscle activities with upper airway pressure and flow.

The hypothesis that upper airway (UA) pressure and flow modulate respiratory muscle activity in a respiratory phase-specific fashion was assessed in anesthetized, tracheotomized, spontaneously breathing piglets. We generated negative pressure and inspiratory flow in phase with tracheal inspiration or positive pressure and expiratory flow in phase with tracheal expiration in the isolated UA. Stimulation of UA negative pressure receptors with body temperature air resulted in a 10--15% enhancement of phasic moving-time-averaged posterior cricoarytenoid electromyographic (EMG) activity above tonic levels obtained without pressure and flow in the UA (baseline). Stimulation of UA positive pressure receptors increased phasic moving-time-averaged thyroarytenoid EMG activity above tonic levels by 45% from baseline. The same enhancement of posterior cricoarytenoid or thyroarytenoid EMG activity was observed with the addition of flow receptor stimulation with room temperature air. Tidal volume and diaphragmatic and abdominal muscle activity were unaffected by UA flow and/or pressure, whereas respiratory timing was minimally affected. We conclude that laryngeal afferents, mainly from pressure receptors, are important in modulating the respiratory activity of laryngeal muscles.     

Posterior cricoarytenoid activity and glottic size during hyperpnea in humans.

We measured the electromyographic activity of the posterior cricoarytenoid (PCA) muscle simultaneously with glottic width (dg) in five normal human subjects during hyperpnea induced by hypoxia (7% CO2 in N2) or hypercapnia (9% CO2 in 50% O2). The glottic aperture was measured during inspiration at the time corresponding to peak inspiratory PCA activity and during expiration at the time corresponding to the minimum tonic activity. During hyperpnea, peak and tonic PCA activity increased simultaneously with widening of the vocal cords in both phases of the respiratory cycle. The PCA activity during both inspiration and expiration showed a single curvilinear relationship with dg of the form dg = A - Be-k.PCA (where A, B, and k are constants) in three of the five subjects. At 50% of maximum PCA activity, dg already reached 95% of its maximum value, which was less than that recorded during a voluntary forced expiratory maneuver. The single curvilinear relationship between PCA activity and dg could be due to the length-tension relationship of the PCA muscle and/or changes in its mechanical coupling, as well as simultaneous agonist and antagonist laryngeal muscle activity during progressive chemical stimulation. Also, further widening of the glottis during forced expiration suggests recruitment of additional muscles, e.g., the arytenoideus.     

Respiratory activities of intralaryngeal branches of the recurrent laryngeal nerve

To distinguish experimentally between motor nerve activity destined for vocal cord abductor muscles and that bound for muscles that adduct the cords, we recorded efferent activities of intralaryngeal branches of the recurrent laryngeal nerve (RLN) in decerebrate, vagotomized, paralyzed, ventilated cats. Activities of the whole RLN and phrenic nerve were also recorded. Nerve activities were assessed at several steady-state end-tidal O2 and CO2 concentrations. The nerve to the thyroarytenoid (TA) muscle, a vocal cord adductor, was only slightly active under base-line (normocapnic, hyperoxic) conditions but in most cats developed strong activity during expiration in hypocapnia or hypoxia. In severe hypocapnia, phasic expiratory TA activity persisted even during phrenic apnea, indicating continuing activity of the respiratory rhythm generator. The nerve to the posterior cricoarytenoid (PCA) muscle, the vocal cord abductor, was always active in inspiration but often showed expiratory activity as well. This expiratory activity was usually enhanced by hypercapnia and often inhibited by hypoxia. The results are consistent with previous electromyographic findings and emphasize the importance of distinguishing abductor from adductor activity in studies of laryngeal control.     

Respiratory-related pharyngeal constrictor muscle activity in decerebrate cats

Kuna, Samuel T., and Christi R. Vanoye.Respiratory-related pharyngeal constrictor muscle activity indecerebrate cats. J. Appl. Physiol.83(5): 1588-1594, 1997.Respiratory-related activity of thehyopharyngeus (middle pharyngeal constrictor) and thyropharyngeus(inferior pharyngeal constrictor) muscles was determined indecerebrate, tracheotomized adult cats and compared with theelectromyographic activity of the thyroarytenoid, a vocal cordadductor. During quiet breathing, the hyopharyngeus and usually thethyroarytenoid exhibited phasic activity during expiration and tonicactivity throughout the respiratory cycle. Respiratory-related thyropharyngeus activity was absent under these conditions. Progressive hyperoxic hypercapnia and progressive isocapnic hypoxia increased phasic expiratory activity in both pharyngeal constrictor (PC) musclesbut tended to suppress thyroarytenoid activity. Passively inducedhypocapnia and the central apnea that followed the cessation of themechanical hyperventilation were associated with tonic activation ofthe hyopharyngeus and thyroarytenoid but no recruitment inthyropharyngeus activity. The expiratory phase of a sigh and progressive pneumothorax were associated with an increase in phasic thyroarytenoid activity but no change in phasic PC activity. The results indicate that a variety of stimuli modulate respiratory-related PC activity, suggesting that the PC muscles may have a role in theregulation of upper airway patency during respiration.

     

Breathing strategy of the adult horse (Equus caballus) at rest

To investigate the mechanism underlying the polyphasic airflow pattern of the equine species, we recorded airflow, tidal volum, rib cage and abdominal motion, and the sequence of activation of the diaphragm, intercostal, and abdominal muscles during quiet breathing in nine adult horses standing at rest. In addition, esophageal, abdominal, and transdiaphragmatic pressures were simultaneously recorded using balloon-tipped catheters. Analysis of tidal flow-volume loops showed that, unlike humans, the horse at rest breathes around, rather than from, the relaxed volume of the respiratory system (Vrx). Analysis of the pattern of electromyographic activities and changes in generated pressures during the breathing cycle indicate that the first part of expiration is passive, as in humans, with deflation toward Vrx, but subsequent abdominal activity is responsible for a second phase of expiration: active deflation to below Vrx. From this end-expiratory volume, passive inflation occurs toward Vrx, followed by a second phase of inspiration: active inflation to above Vrx, brought about by inspiratory muscle contraction. Under these conditions the abdominal muscles appear to share the principal pumping duties with the diaphragm. Adoption of this breathing strategy by the horse may relate to its peculiar thoracoabdominal anatomic arrangement and to its very low passive chest wall compliance. We conclude that there is a passive and active phase to both inspiration and expiration due to the coordinated action of the respiratory pump muscles responsible for the resting adult horse's biphasic inspiratory and expiratory airflow pattern. This unique breathing pattern perhaps represents a strategy of minimizing the high elastic work of breathing in this species, at least at resting breathing frequencies.     

Arytenoideus muscle activity in normal adult humans during wakefulness and sleep

The respiratory-related activity of the arytenoideus (AR) muscle, a vocal cord adductor, was investigated in 10 healthy adults during wakefulness and sleep. AR activity was measured with intramuscular hooked-wire electrodes implanted by means of a fiber-optic nasopharyngoscope. Correct placement of the electrodes was confirmed by discharge patterns during voluntary maneuvers. The AR usually exhibited respiratory-related activity during quiet breathing in all awake subjects. Tonic activity was frequently present throughout the respiratory cycle. The pattern of phasic discharge during wakefulness exhibited considerable intrasubject variability both in timing and level of activity. Phasic activity usually began in midinspiration and terminated in mid- to late expiration. Periods of biphasic discharge were observed in four subjects. Phasic discharge primarily confined to expiration was also commonly observed. During quiet breathing in wakefulness, the level of phasic AR activity appeared to be directly related to the time of expiration. The AR was electrically silent in the six subjects who achieved stable periods of non-rapid-eye-movement sleep. Rapid-eye-movement sleep was observed in three subjects and was associated with sporadic paroxysmal bursts of AR activity. The results during wakefulness indicate that vocal cord adduction in expiration is an active phenomenon and suggest that the larynx may have an active role in braking exhalation.