Effects of upper airway pressure on abdominal muscle activity in conscious dogs.

We have examined arousal and abdominal muscle electromyogram (EMGabd) responses to upper airway pressure stimuli during physiological sleep in four dogs with permanent side-hole tracheal stomata. The dogs were trained to sleep with a tightly fitting snout mask, hermetically sealed in place, while breathing through a cuffed endotracheal tube inserted through the tracheostomy. Sleep stage was determined by behavioral and electroencephalographic criteria. EMGabd activity was measured using bipolar fine-wire electrodes inserted into the abdominal muscle layers. Static increases or decreases in upper airway pressure (+/- 6 cmH2O), when applied at the snout mask or larynx (upper trachea), caused an immediate decrease in EMGabd on the first two to three breaths; EMGabd usually returned to control levels within the 1-min test interval. In contrast, oscillatory pressure waves at 30 Hz and +/- 3 cmH2O amplitude (or -2 to -8 cmH2O amplitude) produced an immediate and sustained reduction in IMGabd in all sleep states. Inhibition of EMGabd could be maintained over many minutes when the oscillatory pressure stimulus was pulsed by using a cycle of 0.5 s on and 0.5 s off. Oscillatory upper airway pressures were also found to be powerful arousal-promoting stimuli, producing arousal in 94% of tests in drowsiness and 66% of tests in slowwave sleep. The results demonstrate the presence of breath-by-breath upper airway control of abdominal muscle activity.

Abdominal muscle activity in conscious dogs: effect of sleep and route of breathing.

Abdominal muscle activity (EMGabd) was studied in 4 adult dogs during wakefulness and sleep. The dogs were previously prepared with a permanent side-hole tracheal stoma, and were trained to sleep with a tightly-fitted snout mask, hermetically sealed in place. They breathed either through a cuffed endotracheal tube inserted distally into the tracheal stoma (tracheal), or through the upper airway, with the tracheal stoma plugged (nasal). Sleep state was determined by behavioural, electroencephalographic and electromyographic criteria. EMGabd activity was measured using fine bipolar needles inserted into the abdominal muscle layers. Expiratory EMGabd augmented progressively from sleep onset to SWS regardless of route of breathing, and without major changes in the animal's ventilation. Maximal EMGabd occurred in SWS during nasal breathing; EMGabd increased from a mean of 16.6 +/- 0.3 mV awake, to 23.8 +/- 0.3 mV in SWS, representing an overall increase of 55.0 +/- 7.5% from the awake level. EMGabd increased similarly during tracheal breathing, with an overall increase of 62.0 +/- 15.4% in SWS. We conclude that the consistent augmentation of expiratory EMGabd activity in sleep indicates that expiration in the dog is an active process, which is enhanced during nasal breathing and NREM sleep.

Waking and genioglossus muscle responses to upper airway pressure oscillation in sleeping dogs.

We studied waking and genioglossus electromyographic (EMGgg) responses to oscillating pressure waves applied to the upper airways of three sleeping dogs. The dogs were previously prepared with a permanent side-hole tracheal stoma and were trained to sleep with a tight-fitting snout mask, hermetically sealed in place, while breathing through a cuffed endotracheal tube inserted through the tracheostomy. Sleep state was determined by behavioral, electroencephalographic, and electromyographic criteria, and EMGgg activity was measured using fine bipolar electrodes inserted directly into the muscle. Oscillatory pressure waves of 30 Hz and +/- 3 cmH2O (tested at atmospheric and subatmospheric upper airway pressures) were applied at the dog's nostrils or larynx, either constantly for a period of 1 min or in 0.5-s bursts. We found that the pressure stimulus had two major effects. First, it was a potentially powerful arousal-promoting stimulus. Arousal occurred in 78% of tests in slow-wave sleep (SWS) and 55% of tests in rapid-eye-movement (REM) sleep, with swallowing and sighing accompanying many of the arousals. Second, it produced an immediate and sustained augmentation of EMGgg, in wakefulness, SWS, and REM sleep. We conclude that oscillatory pressure waves in the upper airway, as found in snoring, produce reflex responses that help maintain upper airway patency during sleep. Loss of this type of reflex might contribute to the onset of obstructive sleep apnea in chronic snorers.

Tracheal smooth muscle responses to upper airway pressure in conscious dogs.

We studied the influence of changes in pressure applied to the isolated upper airway of four conscious dogs on tracheal smooth muscle tone and breathing pattern. The dogs were prepared with a permanent side-hole tracheal stoma and were trained to sleep with a snout mask hermetically sealed in place while breathing through a cuffed endotracheal tube inserted distally into the tracheal stoma. Changes in tracheal smooth muscle tone were continuously monitored by measuring the pressure in the water-filled cuff that distended the tracheal airway while pressure changes were introduced in the upper airway independently of breathing. Increases or decreases of upper airway pressure (+/- 10 cmH2O) had little effect on tracheal airway smooth muscle tone. In contrast, an oscillating pressure wave at 30 Hz and +/- 3 cmH2O amplitude (or -3 to -7 cmH2O amplitude) caused a marked increase in tracheal airway smooth muscle tone. An elevated tracheal airway tone could be maintained over many minutes when the oscillating pressure stimulus was pulsed so that there was a cycle of 0.5 s on, 0.5 s off. This stimulus did not change the functional residual capacity but resulted in coughing, swallowing, or sighing in 54% of the tests. In the remaining tests, the pressure stimulus produced a rapid, shallow, and erratic breathing pattern. The tracheal airway constrictor response (but not the ventilatory response) was completely abolished by intravenous atropine. We suggest that upper airway vibration is a potentially powerful mechanism of reflex airway smooth muscle constriction.

Genioglossus and breathing responses to airway occlusion: effect of sleep and route of occlusion.

We examined the effect of sleep state on the response of genioglossus muscle (EMGgg) activity to total airway occlusion applied at 1) nasal (N) airway [and thus exposing the upper airway (UAW) to pressure changes] and 2) tracheal (T) airway (thus excluding UAW from pressure changes). A total of 233 tests were performed during wakefulness (W), 98 tests in slow-wave sleep (SWS), and 72 tests in rapid-eye-movement (REM) sleep. Prolongation of inspiratory time (TI) of the first occluded effort occurred in all tests irrespective of behavioral state, with the greatest increase seen in awake N tests. Nasal tests augmented EMGgg activity in the first occluded breath and produced a linear increase in EMGgg during occlusion. The EMGgg activity at any given time during nasal occlusion in SWS was less than that recorded during W tests. There was a marked reduction in EMGgg response to N occlusion during REM sleep. The EMGgg activity during awake T tests was significantly less than that of N tests at any given time during occlusion. There was no relationship between the level of EMGgg activity and asphyxia in T tests performed during SWS and REM sleep. Nasal tests decreased the force generated by the inspiratory pump muscles and the central drive to breathing compared with T tests. These results confirm the important role of the UAW in regulating breathing pattern and indicate that both immediate and progressive load-compensating responses during nasal occlusion are influenced by information arising from the UAW.