Respiratory activity of genioglossus. Interaction between alcohol and the menstrual cycle

Alcohol consistently decreases genioglossal electromyographic (EMG) activity in awake men, but in women this response is more variable, possibly because of the menstrual cycle. To assess the interaction between alcohol and the menstrual cycle on genioglossal EMG activity, we measured ventilation and genioglossal EMG activity in 9 normal women before and after they drank 1 ml/kg alcohol. The effect of alcohol on ventilation and genioglossal EMG activity was studied twice in each subject: once during the follicular phase and again during the luteal phase of the menstrual cycle. Measurements were made while the subjects breathed room air and rebreathed a hypercapnic gas mixture. The ventilatory response to CO2 was significantly greater during the luteal phase of the menstrual cycle. Alcohol had no effect on resting ventilation or the ventilatory response to CO2 during either phase of the menstrual cycle. However, alcohol significantly decreased peak integrated genioglossal EMG activity during the follicular (low progesterone) phase but not during the luteal (high progesterone) phase of the cycle. The relative alcohol resistance of genioglossal EMG activity during the luteal phase may explain in part the low incidence of sleep-disordered breathing in premenopausal women and the benefit that some male patients with obstructive sleep apnea have derived from treatment with progesterone.     

The effect of diazepam on genioglossal muscle activity in normal human subjects

We examined the effect of diazepam on the respiratory electromyographic (EMG) activity of the genioglossal muscle using a double-blind, placebo-controlled, randomized protocol. Control measurements of minute ventilation, tidal volume, frequency, end-tidal CO2, and peak integrated inspiratory genioglossal EMG activity were made in 10 normal awake male subjects during quiet breathing and CO2 rebreathing. Subjects then received either 10 mg of diazepam orally or a placebo, and all respiratory measurements were repeated after 45 min. Each subject was studied on 2 separate days, receiving each treatment on a different day. The placebo had no effect on any of the measured variables. After diazepam, we observed an increase in end-tidal CO2 rebreathing, diazepam was associated with a reduction in minute ventilation, tidal volume, and frequency. When compared at equal end-tidal CO2 levels, genioglossal EMG activity and tidal volume were significantly reduced after diazepam. However, only older subjects demonstrated a reduction in EMG activity when compared at equal tidal volumes during CO2 rebreathing. We conclude that diazepam selectively decreases genioglossal EMG activity during CO2 rebreathing only in older subjects.     

Steady-state response of conscious man to small expiratory resistive loads

To determine the predominant steady-state ventilatory responses to mild expiratory flow-resistive loads, we subjected 14 normal subjects to expiratory resistances of 0-10 cm H2O/L/sec (R0-R3). Breathing patterns and abdominal muscle activity (EMG) were recorded during quiet breathing, and when ventilation was augmented by dead space breathing (7 subjects) or treadmill walking (7 subjects). Expiratory loading increased expiratory time (TE), tidal volume and mean inspiratory flow rate, while decreasing inspiratory duty cycle and respiratory frequency. Minute ventilation (VI) remained constant. These load responses were most prominent during quiet breathing, and were attenuated or abolished as VI increased. Abdominal EMG was negligible during quiet breathing, increased when VI increased, but showed no consistent response to R1-R3. Thus, the principal defense against mild expiratory loads is prolongation of expiration, accompanied by enhanced inspiratory drive. Abdominal muscle expiratory activity is elicited by increasing ventilation, but occurs only sporadically with expiratory loading of the magnitude studied.     

Pathogenesis of respiratory insufficiency in myotonic dystrophy: the mechanical factors

We have previously shown that the chemosensitivity of the respiratory centers is well preserved in myotonic dystrophy but that the ventilatory output is reduced. The present study was designed to determine at which degree of ventilatory performance weakness and fatigability of the respiratory muscles are interfering with ventilation and which mechanical factors contribute to the tachypnea of patients with myotonic dystrophy at rest and during low ventilatory output. We studied 10 patients with the disease and 10 normal control subjects. The strength of respiratory muscles was assessed by measurements of maximal pressure-volume diagrams generated against airway occlusion. Performance was evaluated during 1-min maximal voluntary ventilation (1-min MVV) test, during 7-min 7% CO2 breathing and during quiet breathing. Occlusion pressure (P0.1) in patients at rest was slightly higher than in control subjects, and during CO2 breathing, it was similar to that of control subjects. Maximal static pressure was reduced in patients to an average of 35% of that of control subjects. During the 1-min MVV test, there was a 50% reduction in esophageal and transdiaphragmatic pressure output (Pes, Pdi) in patients, resulting in similar reduction in ventilation (VE) and patients had rapid cycles of alternating dominant thoracic and abdominal volume displacements (Vrc/Vabd) suggesting respiratory muscle fatigue. During the 3- to 4-fold increase in breathing drive induced by hypercapnia, pressure output and the Vrc/Vabd were identical in both groups. However, ventilation was reduced in patients who had tachypneic respiration. In patients, tachypnea was also observed during quiet breathing. This tachypnea was associated with higher impedance of the respiratory system (Zrs) in patients and identical impedance of the lung (ZL) in both groups. In addition, Pdi during tidal volume was significantly higher in patients. These data demonstrate that the ventilatory output in out patients was altered predominantly by weakness and fatigability of the respiratory muscles during high ventilatory performance and by increased impedance of the respiratory system at lower degrees of ventilation.     

The effect of sleep deprivation on activity of the genioglossus muscle

Sleep deprivation appears to increase the severity of obstructive sleep apnea, and inadequate activation of the genioglossus muscle may play an important role in the pathogenesis of obstructive sleep apnea. Therefore, we investigated the effect of sleep deprivation on genioglossal electromyographic (EMG) activity. Eleven men were studied during room air breathing and CO2 rebreathing before sleep deprivation (control), after 1 night of sleep deprivation, and the day after sleep recovery. We measured inspired minute ventilation, tidal volume, respiratory frequency, and peak integrated inspiratory genioglossal EMG activity. After sleep deprivation, no significant changes in inspiratory minute ventilation or tidal volume occurred during room air breathing or CO2 rebreathing, but the breathing frequency during CO2 rebreathing increased significantly after sleep deprivation. Genioglossal EMG activity was diminished during CO2 rebreathing after sleep deprivation, but this was significant only in subjects 30 yr of age and older. The fall in EMG activity was independent of changes in tidal volume. All variables returned towards control levels after sleep recovery. We conclude that sleep deprivation selectively decreases genioglossal EMG activity during CO2 rebreathing in awake older subjects. This influence of sleep deprivation may play a role in the pathogenesis or severity of obstructive sleep apnea.     

Chest wall kinematics in patients with hemiplegia

Owing to difficulties in measuring ventilation symmetry, good evidence of different right/left respiratory movements has not yet been provided. We investigated VT differences between paretic and healthy sides during quiet breathing, voluntary hyperventilation, and hypercapnic stimulation in patients with hemiparesis. We studied eight patients with hemiparesis and nine normal sex- and age-matched subjects. Right- and left-sided VT was reconstructed using optoelectronic plethysmography. In control subjects, no asymmetry was found in the study conditions. VTs of paretic and healthy sides were similar during quiet breathing, but paretic VT was lower during voluntary hyperventilation in six patients and higher during hypercapnic stimulation in eight patients (p = 0.02). The ventilatory response to hypercapnic stimulation was higher on the paretic than on the healthy side (p = 0.012). In conclusion, hemiparetic stroke produces asymmetric ventilation with an increase in carbon dioxide sensitivity and a decrease in voluntary ventilation on the paretic side.     

Work of breathing and respiratory drive in obesity

Obesity, particularly severe central obesity, affects respiratory physiology both at rest and during exercise. Reductions in expiratory reserve volume, functional residual capacity, respiratory system compliance and impaired respiratory system mechanics produce a restrictive ventilatory defect. Low functional residual capacity and reductions in expiratory reserve volume increase the risk of expiratory flow limitation and airway closure during quiet breathing. Consequently, obesity may cause expiratory flow limitation and the development of intrinsic positive end expiratory pressure, especially in the supine position. This increases the work of breathing by imposing a threshold load on the respiratory muscles leading to dyspnoea. Marked reductions in expiratory reserve volume may lead to ventilation distribution abnormalities, with closure of airways in the dependent zones of the lungs, inducing ventilation perfusion mismatch and gas exchange abnormalities. Obesity may also impair upper airway mechanical function and neuromuscular strength, and increase oxygen consumption, which in turn, increase the work of breathing and impair ventilatory drive. The combination of ventilatory impairment, excess CO(2) production and reduced ventilatory drive predisposes obese individuals to obesity hypoventilation syndrome.     

Efficacy of positive vs negative pressure ventilation in unloading the respiratory muscles

We compared the efficacy of positive pressure ventilation (PPV) vs negative pressure ventilation (NPV) in providing ventilatory muscle rest for five normal subjects and six patients with chronic obstructive pulmonary disease (COPD). All participants underwent measurement of transdiaphragmatic pressure (Pdi), pressure time integral of the diaphragm (PTI), integrated diaphragmatic electromyogram (iEMG), minute ventilation (Ve), tidal volume (Vt), and end-tidal CO2 (etCO2) during 15 minutes of PPV and NPV. For each subject, ventilator adjustments were made to obtain Ve similar to levels measured during quiet breathing (QB). We found that the iEMG, Pdi, PTI, and average coefficient of variation of the tidal volume (CV-Vt) were consistently lower during PPV as compared with NPV (p = 0.01). The iEMG normalized for Ve and Vt was also significantly lower during PPV (p = 0.01). During PPV, subjects were mildly hyperventilated (lower etCO2 and higher Ve) compared with QB and NPV, but no significant correlation was noted between the change in etCO2 and the change in iEMG. The change in PTI was significantly correlated with the change in iEMG (p less than 0.01). We conclude that in the short term, PPV is more effective than NPV in reducing diaphragmatic activity. Positive pressure ventilation may be the preferred method of assisted ventilation in future studies of ventilatory muscle rest therapy.     

The effect of a single breath of 100% oxygen on breathing in infants at 1, 2, and 3 months of age

Sequential measurements of the ventilatory response to a single breath of oxygen delivered during quiet sleep were made in 16 healthy infants between 1 and 3 months of age, alternately breathing air and 16% oxygen in nitrogen. At 1 month the response to a single breath of oxygen during normoxia was a decrease in minute ventilation of 264 +/- 34.2 (SEM) ml.min-1 during the 10-s period following the stimulus (p less than 0.001). During mild hypoxia the decrease in ventilation averaged 471 +/- 49.1 (SEM) ml.min-1 (p less than 0.001). The difference in response between measurements in air and mild hypoxia was significant (p less than 0.001). By the age of 3 months, the absolute ventilatory response to a single breath of oxygen increased significantly in normoxia by 118 +/- 35.2 ml.min-1 (p less than 0.01); the test response to breathing 16% oxygen paralleled the response to normoxia and was on average 254 +/- 26.6 ml.min-1 larger than the response when breathing air (p less than 0.001). When the three age groups were compared, calculating the response per killigram body weight showed that the response was similar at all three ages tested. These data provide a reference baseline for normal infants.     

The impact of morbid obesity on oxygen cost of breathing (VO(2RESP)) at rest.

Oxygen consumption dedicated to respiratory work (V O(2RESP)) during quiet breathing is small in normal patients. In the morbidly obese, at high minute ventilations, VO(2RESP) is greater than in normal patients, but VO(2RESP) during quiet breathing in these patients is not known. We postulated that such patients have increased VO(2RESP) at rest which may predispose them to respiratory failure when additional respiratory workloads are imposed. We measured baseline VO(2) in morbidly obese patients immediately prior to gastric bypass surgery and again after intubation, mechanical ventilation, and paralysis, and compared their change in VO(2) to nonobese patients scheduled for elective abdominal surgery. Baseline VO(2) was higher in the obese patients compared with control patients (354.6 versus 221.4 ml/min; p = 0.0001) and the change in VO(2) from spontaneous breathing to mechanical ventilation was significant in the obese patients (354.6 versus 297.2 ml/min; p = 0.0002) but not the control patients (221.4 versus 219.8 ml/min; p = 0.86). We conclude that morbidly obese patients dedicate a disproportionately high percentage of total VO(2) to conduct respiratory work, even during quiet breathing. This relative inefficiency suggests a decreased ventilatory reserve and a predisposition to respiratory failure in the setting of even mild pulmonary or systemic insults.     

Clinical and physiologic evaluation of respiratory muscle function

The ventilatory muscles are of primary importance in the maintenance of ventilation. This rather complex system of muscles centers around the diaphragm. As diaphragmatic function becomes compromised with the progression of different lung diseases, the participation of other muscles becomes necessary. This is clinically manifested by the recruitment of many of these muscles even during quiet breathing. The use of simple questions during a medical history, determination of the respiratory rate, assessment of the pattern of breathing, and observation of thoracoabdominal movements are helpful in the initial evaluation. Measurement of the FVC, lung volumes, and tidal breathing help direct attention to more specific investigation of the ventilatory muscles. Decreased respiratory muscle strength can be confirmed by measurement of PImax and PEmax. Decreased respiratory muscle endurance can be readily ascertained by measuring the MVV. Use of these simple techniques, available in most laboratories, is appropriate for initial evaluation and establishing a diagnosis. The additional measurements of esophageal and gastric pressures have added a new dimension to the study of the diaphragm; these techniques, however, remain a research tool.     

Ventilatory and waking responses to laryngeal stimulation in sleeping mature lambs

Ventilatory and waking responses to laryngeal stimulation were studied in six chronically tracheostomized lambs breathing through an endotracheal tube. A balloon catheter inserted in the rostral tracheal segment allowed application of distilled water onto the larynx. Apnea, the main primary ventilatory response, was shorter in wakefulness (7.9 sec) than in quiet (10.7 sec) or active sleep (10.6 sec, residual variance = 3.29), where the response to laryngeal stimulation was poorly reproducible. Arousal delay measured from the neck muscle EMG was longer in active (21.1 sec) than in quiet sleep (5.4 sec, residual variance = 9.05). Arousal preceded apnea termination more often in quiet than in active sleep. When breathing resumed a sigh frequently occurred following prolonged apneas. We conclude that laryngeal stimulation elicits apnea in all states in mature lambs. The termination of apnea is related to waking up in quiet but not in active sleep, where arousal is depressed. A comparison of our results with data from preterm and adult mammals strongly suggests that the ventilatory response to laryngeal stimulation during active sleep is unaffected by maturation.     

Respiratory pauses during sleep in near-miss sudden infant death syndrome

To study transient ventilatory changes in infants with the near-miss sudden infant death syndrome (SIDS), we examined the distribution, frequency, and mean duration of all respiratory pauses defined as expiratory time (Te) greater than 2 s in 12 infants with near-miss SIDS and 10 age-matched normal infants during REM and quiet sleep at 1, 2, 3, and 4 months of age. Using the barometric method, we monitored ventilation and respiratory timing while these infants breathed (1) ambient gas concentrations and (2) 2% CO2. We found that infants with near-miss SIDS did not have more frequent or prolonged respiratory pauses than did normal infants at any age in either REM or quiet sleep breathing ambient gas. With 2% CO2, respiratory pauses decreased in number or were eliminated and their mean duration was shorter in both groups. If these infants have hypoxemia during sleep, these data do not support the hypothesis that hypoxemia is secondary to prolonged and more frequent respiratory pauses.     

Ventilatory and arousal responses to respiratory stimuli of full term, intrauterine growth restricted lambs

We aimed to determine the effect of intrauterine growth restriction (IUGR) on the control of breathing and arousal in sleeping postnatal animals. We measured ventilatory and arousal responses to respiratory challenges during sleep in normally grown (birthweight 5.17+/-0.48 kg) and IUGR (2.64+/-0.19 kg) full term lambs. During wakefulness, IUGR lambs had significantly lower arterial pH and higher Pa(CO(2)) levels. During quiet sleep, but not active sleep, end tidal CO(2) was elevated in IUGR lambs (P=0.08). During active and quiet sleep, minute ventilation (per kg body weight) was significantly higher in IUGR lambs than controls. Ventilatory responses to hypercapnia and/or hypoxia were not different between control and IUGR lambs during active and quiet sleep but end tidal CO(2) at arousal was consistently higher in IUGR lambs; other indices of arousal were not affected by IUGR. Our findings suggest IUGR lambs require an elevated level of ventilation to maintain respiratory homeostasis and that alterations in lung function are likely consequences of IUGR.     

Central nervous control of gill filament muscles in channel catfish

The gills of fish are innervated by cranial nerves IX and X. There have been a number of studies on the characteristics of sensory activity carried by these nerves but remarkably little is known about motor control of the gills. Efferent, motor activity to the first gill arch was recorded from the glossopharyngeal nerve in spontaneously breathing channel catfish, Ictalurus punctatus. This study addressed two objectives. The first objective was to characterize efferent branchial nerve activity in spontaneously breathing fish. Nerve recordings show bursts of activity firing in synchrony with ventilation. These bursts occurred once during either abduction or adduction of the operculum with each breath. The observed patterns of neural activity indicate that it represents motor control of gill filament abductor and adductor muscles. The data show that rhythmic output from a central pattern generator controls filament musculature during the ventilatory cycle. The second objective was to use this efferent branchial nerve activity as an index of ventilation (fictive ventilation) in fish before and after paralysis to determine if feedback from phasic mechanoreceptors affects ventilatory timing. Breath-to-breath intervals measured before and after paralysis with gallamine were not significantly different, demonstrating that rhythmic feedback from phasic mechanoreceptors in the gills and/or ventilatory musculature is not involved in the breath-to-breath timing of the normal ventilatory cycle. During the course of these experiments many fish exhibited coughing. Coughs were characterized by a distinctive pattern of nerve activity that was not altered by paralysis. Overall, the data indicate that phasic mechanoreceptor feedback during normal breathing has no effect on the pattern of central motor control of gill filament muscles.     

Costal and crural diaphragm, and intercostal and genioglossal electromyogram activities during spontaneous augmented breaths (sighs) in kittens

Spontaneously occurring augmented breaths (sighs) are common in infants. The pattern of electrical activity of the inspiratory muscles of the thorax and upper airway during augmented breaths, however, has not been fully characterized in this less than fully mature age group. We therefore examined costal and crural diaphragm and external intercostal and genioglossal EMG activities during spontaneous augmented breaths (n = 46) in 10 anesthetized (1.35% halothane) 1-month-old kittens breathing room air. EMG responses were assessed by comparing the spontaneous augmented breaths (AB) to the five immediately preceding breaths (control). The peak moving time average EMG activity observed during the AB was 240 +/- 32% (mean +/- SD) of control for the costal diaphragm, 279 +/- 66% of control for the crural diaphragm, and 274 +/- 68% of control for the external intercostal muscle. The mean increase in EMG activity during the AB was not significantly different among these three muscle groups (P greater than 0.25). Genioglossal EMG activity during AB was observed in only 1 of 10 study animals. These results document that during AB in anesthetized kittens, activity of the thoracic inspiratory muscles (costal/crural diaphragm and external intercostal muscles) increase in parallel, suggesting that they are modulated in a uniform manner. The infrequent observance of genioglossal activity during AB suggests that either 1) halothane anesthesia depresses genioglossal activity more than diaphragmatic and intercostal activity during AB or 2) that genioglossal recruitment is not necessary to maintain upper airway patency during this period of heightened respiratory drive.     

Ventilatory muscle support in respiratory failure with nasal positive pressure ventilation

Long-term intermittent mechanical ventilation results in improvements in ventilatory performance and clinical status between ventilation sessions in patients with chronic respiratory failure. The application of intermittent positive pressure ventilation through a nasal mask (NPPV) is a simple, noninvasive method for the provision of chronic intermittent ventilatory support. We investigated the effects of NPPV on inspiratory muscle activity in three normal subjects and nine patients with acute or chronic ventilatory failure due to restrictive (four subjects) or obstructive (five subjects) respiratory disorders. NPPV resulted in reductions of phasic diaphragm electromyogram amplitude to 6.7 +/- 0.7 percent (mean +/- SEM) of values obtained during spontaneous breathing in the normal subjects, 6.4 +/- 3.2 percent in the restrictive group, and 8.3 +/- 5.1 percent in the obstructive group. Simultaneous decreases in activity of accessory respiratory muscles were observed. The reductions in inspiratory muscle activity were confirmed by the finding of positive intrathoracic pressure swings on inspiration in all subjects. With NPPV, oxygen saturation and PCO2 remained stable or improved as compared with values obtained during spontaneous breathing. These results indicate that NPPV can noninvasively provide ventilatory support while reducing inspiratory muscle energy expenditure in acute and chronic respiratory failure of diverse etiology. Long-term assisted ventilation with NPPV may be useful in improving ventilatory performance by resting the inspiratory muscles.     

Vagal feedback is essential for breathing in unanesthetized ground squirrels

The roles of vagal afferent feedback in terminating inspiration and modulating breathing pattern and ventilatory responses to hypoxia and hypercapnia were assessed in the golden-mantled ground squirrel, Spermophilus lateralis, during wakefulness and urethane anesthesia. Hypoxia increased ventilation primarily through increases in breathing frequency (f(R)) while hypercapnia increased ventilation primarily through increases in tidal volume (V(T)) in both anesthetized and unanesthetized animals. Vagotomy resulted in an increase in tidal volume, a decrease in breathing frequency and ventilation, and depressed ventilatory responses to both hypoxia and hypercapnia in anesthetized animals. In unanesthetized animals vagotomy produced a transient 'gasp-like' breathing pattern that rapidly progressed to a non-obstructive central apnea. These data indicate that vagal feedback shapes ventilation on a breath-by-breath basis during anesthesia and is essential for ventilation in unanesthetized animals. The mechanisms that transform the influences of vagal input on breathing between anesthetized and unanesthetized states remain unclear. Changes in breathing pattern induced by the removal of vagal feedback compromise chemoreflexes.     

Acute myocardial infarction complicated by respiratory failure. The effects of mechanical ventilation

The cardiopulmonary effects of ventilatory support were studied in 12 patients with an acute myocardial infarction complicated by respiratory failure. At constant end-expiratory pressure, controlled mechanical ventilation, intermittent mandatory ventilation with 50 percent mechanical support, and spontaneous breathing all resulted in acceptable blood gas values. Intermittent mandatory ventilation offered hemodynamic advantages over controlled mechanical ventilation, as evidenced by a higher cardiac index and a lower arteriovenous oxygen content difference. Electrocardiographic evidence of myocardial ischemia was observed in one patient during controlled mechanical ventilation, in one during partial ventilatory support, and in five patients during spontaneous breathing. Myocardial ischemia should be one of the major determinants of mechanical ventilation when a patient with ischemic heart disease is subjected to ventilator treatment. The total withdrawal of ventilatory support carries a risk of marked ischemia and is not recommended until the patient can be extubated.     

Noninvasive proportional assist ventilation and pressure support ventilation during arm elevation in patients with chronic respiratory failure. A preliminary, physiologic study

BACKGROUND: It has been shown that upper limbs activity increases the respiratory workload in patients with chronic respiratory failure (CRF). The object of the present study was to investigate whether, in these patients: (i) noninvasive positive pressure ventilation (NPPV) could sustain the inspiratory muscles to meet the greater ventilatory demand during upper limbs activity with the arm elevation test (AE); (ii) proportional assist ventilation (PAV) might be superior to pressure support ventilation (PSV) during AE, because of its potential more adaptable response to sudden changes in the ventilatory pattern. METHODS: The study was performed in the pulmonary function laboratory of the Pulmonary Division in Verona General Hospital, Verona, Italy. We studied 8 male patients with CRF due to chronic obstructive pulmonary disease (COPD). Each patient received 2 treatment in random order with a crossover design: spontaneous breathing (SB), SB with AE, either PSV or PAV without and with AE, SB without and with AE, either PSV or PAV without and with AE. We measured: lung function tests, lung mechanics, ventilatory pattern and diaphragmatic effort (pressure time product, PTP(di)). RESULTS: (i) AE increases minute ventilation (+14%) and PTP(di) (+64%); (ii) ventilatory support, both with PSV and PAV unloads the diaphragm both at rest (PTP(di) -77% and -54%, respectively) and during arm elevation (PTP(di) -54% and -44%, respectively). CONCLUSIONS: PAV and PSV unloads the diaphragm in patients with CRF due to COPD both during SB and AE; PAV can be more efficient than PSV in assisting the diaphragm during AE in producing a greater level of minute ventilation for a similar rise in PTP(di) compared to PSV. Noninvasive ventilatory support should be considered in rehabilitation programs for training of upper limbs activity.