Tonic vagal influences on inspiratory duration

Large Lung Volumes Delay the Onset of the Physiological Breaking Point During Simulated Diving

During breath holding after face immersion there develops an urge to breathe. The point that would initiate the termination of the breath hold, the "physiological breaking point," is thought to be primarily due to changes in blood gases. However, we theorized that other factors, such as lung volume, also contributes significantly to terminating breath holds during face immersion. Accordingly, nine naïve subjects (controls) and seven underwater hockey players (divers) voluntarily initiated face immersions in room temperature water at Total Lung Capacity (TLC) and Functional Residual Capacity (FRC) after pre-breathing air, 100% O2, 15% O2 / 85% N2, or 5% CO2 / 95% O2. Heart rate (HR), arterial blood pressure (BP), end-tidal CO2 (etCO2), and breath hold durations (BHD) were monitored during all face immersions. The decrease in HR and increase in BP were not significantly different at the two lung volumes, although the increase in BP was usually greater at FRC. BHD was significantly longer at TLC (54 ± 2 s) than at FRC (30 ± 2 s). Also, with each pre-breathed gas BHD was always longer at TLC. We found no consistent etCO2 at which the breath holding terminated. BDHs were significantly longer in divers than in controls. We suggest that during breath holding with face immersion high lung volume acts directly within the brainstem to actively delay the attainment of the physiological breaking point, rather than acting indirectly as a sink to produce a slower build-up of PCO2.

Strategies for the Integration of Cough and Swallow to Maintain Airway Protection in Humans

PURPOSE

Airway protective behaviors, like cough and swallow, deteriorate in many populations suffering from neurologic disorders. While coordination of these behaviors has been investigated in an animal model, it has not been tested in humans.

METHODS

We used a novel protocol, adapted from previous work in the cat, to assess cough and swallow independently and their coordination strategies in seven healthy males (26 ± 6 years). Surface electromyograms of the submental complex and external oblique complex, spirometry, and thoracic and abdominal wall kinematics, were used to evaluate the timing of swallow, cough, and breathing as well as lung volume (LV) during these behaviors.

RESULTS

Unlike the cat, there was significant variability in the cough-swallow phase preference; however, there was a targeted LV range in which swallow occurred.

CONCLUSION

These results give insight into the differences between the cat and human models in airway protective strategies related to the coordination of cough and swallow behaviors, allowing for better understanding of dystussia and dysphagia.

Neuronal activation of brain vagal-regulatory pathways and upper gut enteric plexuses by insulin hypoglycemia

Neuronal activation of brain vagal-regulatory nuclei and gastric/duodenal enteric plexuses in response to insulin (2 U/kg, 2 h) hypoglycemia was studied in rats. Insulin hypoglycemia significantly induced Fos expression in the paraventricular nucleus of the hypothalamus, locus coeruleus, dorsal motor nucleus of the vagus (DMN), and nucleus tractus solitarii (NTS), as well as in the gastric/duodenal myenteric/submucosal plexuses. A substantial number of insulin hypoglycemia-activated DMN and NTS neurons were choline acetyltransferase and tyrosine hydroxylase positive, respectively, whereas the activated enteric neurons included NADPH- and vasoactive intestinal peptide neurons. The numbers of Fos-positive cells in each above-named brain nucleus or in the gastric/duodenal myenteric plexus of insulin-treated rats were negatively correlated with serum glucose levels and significantly increased when glucose levels were lower than 80 mg/dl. Acute bilateral cervical vagotomy did not influence insulin hypoglycemia-induced Fos induction in the brain vagal-regulatory nuclei but completely and partially prevented this response in the gastric and duodenal enteric plexuses, respectively. These results revealed that brain-gut neurons regulating vagal outflow to the stomach/duodenum are sensitively responsive to insulin hypoglycemia.

Effects of abdominal distension on breathing pattern and respiratory mechanics in rabbits

The effects of acute abdominal distension (AD) on the electromechanical efficiency (Eff) of the inspiratory muscles were investigated in anesthetized rabbits by recording the electrical activity (A), pressure (P) exerted by the diaphragm (di) and parasternal intercostal muscles (ic), and lung volume changes when an abdominal balloon was inflated to various degrees. Eff,ic increased with increasing AD both in supine and upright postures. In upright rabbits Eff,di increased for intermediate but decreased at higher levels of AD, whilst it decreased at all levels of AD in supine rabbits. Tidal volume (VT) response followed that of Eff,di. Tonic Aic and Adi and inspiratory prolongation were elicited by AD. The effects of these neural mechanisms, acting to limit end-expiratory lung volume and VT changes, were however small since vagotomy prevented tonic Adi and inspiratory prolongation and reduced tonic Aic, but changed lung volume responses to AD only little. Hence, reduced respiratory system compliance and changes in inspiratory muscle electromechanical efficiency dominate lung volume responses to acute AD.

THE effects of tonic lung inflation on ventilation in the American bullfrog Rana catesbeiana Shaw

This study was designed to determine whether lung inflation stimulates or inhibits breathing in frogs by examining the effect of tonic lung inflation on the ‘fictive’ breathing pattern of decerebrate, unidirectionally ventilated bullfrogs. Neural discharge was monitored in the trigeminal nerve as an indication of the frequency and force of contraction of the buccal pump, and in the laryngeal branch of the vagus nerve as an indication of glottal opening, and hence fictive lung ventilation. Based on the temporal coordination of discharge in the trigeminal and vagus nerves during naturally occurring breaths it was possible to characterize the fictive breaths as inflation, deflation or balanced breaths. Increasing lung inflation increased absolute breathing frequency by reducing the duration of apnea between breaths and promoting a change in breathing pattern from no breathing to single breaths, breathing episodes and, finally, to continuous breathing. Associated with this was a decrease in the amplitude and area of the integrated trigeminal electroneurogram associated with the lung breaths, indicative of a reduction in the force of the buccal pump, and a shift in the timing of the trigeminal and vagal discharge, indicative of a shift from inflation to deflation breaths. Taken together the data suggest that lung deflation produces infrequent, large-amplitude inflation breaths or cycles, but that progressive lung inflation changes the breathing pattern to one of high-frequency attempts to deflate the lungs that are largely passive, and accompanied by contractions of the buccal pump that are no larger than those associated with normal buccal oscillations.

Acute cold exposure induces vagally mediated Fos expression in gastric myenteric neurons in conscious rats

Acute cold exposure-induced activation of gastric myenteric neurons in conscious rats was examined on longitudinal muscle-myenteric plexus whole mount preparations. Few Fos-immunoreactive (IR) cells (<1/ganglion) were observed in 24-h fasted rats semirestrained at room temperature. Cold exposure (4 degrees C) for 1-3 h induced a time-related increase of Fos-IR cells in corpus and antral myenteric ganglia with a maximal plateau response (17 +/- 3 and 18 +/- 3 cells/ganglion, respectively) occurring at 2 h. Gastric vagotomy partly prevented, whereas bilateral cervical vagotomy completely abolished, Fos expression in the myenteric cells induced by cold exposure (2 h). Hexamethonium (20 mg/kg) also prevented 3-h cold exposure-induced myenteric Fos expression by 76-80%, whereas atropine or bretylium had no effect. Double labeling revealed that cold (3 h)-induced Fos-IR myenteric cells were mainly neurons, including a substantial number of choline acetyltransferase-containing neurons and most NADPH-diaphorase-positive neurons. These results indicate that acute cold exposure activates cholinergic as well as nitrergic neurons in the gastric myenteric ganglia through vagal nicotinic pathways in conscious rats.

Lung vagal afferent activity in rats with bleomycin-induced lung fibrosis

Bleomycin treatment in rats results in pulmonary fibrosis that is characterized by a rapid shallow breathing pattern, a decrease in quasi-static lung compliance and a blunting of the Hering-Breuer Inflation Reflex. We examined the impulse activity of pulmonary vagal afferents in anesthetized, mechanically ventilated rats with bleomycin-induced lung fibrosis during the ventilator cycle and static lung inflations/deflations and following the injection of capsaicin into the right atrium. Bleomycin enhanced volume sensitivity of slowly adapting stretch receptors (SARs), while it blunted the sensitivity of these receptors to increasing transpulmonary pressure. Bleomycin treatment increased the inspiratory activity, while it decreased the expiratory activity of rapidly adapting stretch receptors (RARs). Pulmonary C-fiber impulse activity did not appear to be affected by bleomycin treatment. We conclude that the fibrosis-related shift in discharge profile and enhanced volume sensitivity of SARs combined with the increased inspiratory activity of RARs contributes to the observed rapid shallow breathing of bleomycin-induced lung fibrosis.

An overview of the anatomy and physiology of slowly adapting pulmonary stretch receptors

Since the original work of by Hering and Breuer in 1868 numerous studies have demonstrated that slowly adapting pulmonary stretch receptors (SARs) are the lung vagal afferents responsible for eliciting the reflexes evoked by moderate lung inflation. SARs play a role in controlling breathing pattern, airway smooth muscle tone, systemic vascular resistance and heart rate. Both anatomical and physiological studies support the contention that SARs, by their close association with airway smooth muscle, continuously sense the tension within the myoelastic components of the airways caused by lung inflation, smooth muscle contraction and/or tethering of small intrapulmonary airways to the lung parenchyma. In addition, intrapulmonary SAR discharge activity is sensitive to changes in P(CO2) within the physiological range. Despite this extensive characterization of SARs, their role in determining breathing pattern and airway tone in individuals with respiratory diseases is only recently being appreciated.

Correlation structure of end-expiratory lung volume in anesthetized rats with intact upper airway

The correlation structure of breath-to-breath fluctuations of end-expiratory lung volume (EEV) was studied in anesthetized rats with intact airways subjected to positive and negative transrespiratory pressure (i.e., PTRP and NTRP, correspondingly). The Hurst exponent, H, was estimated from EEV fluctuations using modified dispersional analysis. We found that H for EEV was 0.5362 +/- 0.0763 and 0.6403 +/- 0.0561 with PTRP and NTRP, respectively (mean +/- SD). Both H were significantly different from those obtained after random shuffling of the original time series. Also, H with NTRP was significantly greater than that with PTRP (P = 0.029). We conclude that in rats breathing through the upper airway, a positive long-term correlation is present in EEV that is different between PTRP and NTRP.

Control of ventilation during lung volume changes and permissive hypercapnia in dogs

We investigated the effect changes in end-expiratory lung volume (EEVL) had on the response to progressive hypercapnia (CO2-response curve) in eight open-chest, anesthetized dogs, in order to clarify the role that vagal lung mechanoreceptors have in altered respiratory drive during permissive hypercapnia. The dogs were ventilated using a positive-pressure ventilator driven by phrenic neural activity. Systemic arterial CO2 tension (PaCO2) was elevated by increasing the fraction of CO2 delivered to the ventilator. EEVL was altered from approximated functional residual capacity ("FRC") to 1.5 and 0.5 "FRC" by changing positive end-expiratory pressure. Although the tidal volume (VT)-PaCO2 and inspiratory time (TI)-PaCO2 relationships were not affected, decreasing EEVL from 1.5 "FRC" to "FRC" and then to 0.5 "FRC" caused a significant (p < 0.01) upward shift in the CO2-response curves for minute ventilation (V I) and frequency (f ), and a significant (p < 0.01) downward shift in the CO2- response curve for expiratory time (TE). We conclude that these shifts were explained by a decrease in the inhibitory activity of slowly adapting pulmonary stretch receptors (PSRs) as EEVL was lowered. In addition, increases in EEVL from 0.5 "FRC" to 1.5 "FRC" caused a significant (p < 0.05) increase in the apneic threshold, which we attribute to an inhibitory effect on central drive caused by increased PSR activity.

Influence of increasing postnatal age on respiratory timing and reflex activity in preterm ventilated infants

The influence of postnatal age on spontaneous respiratory time, measured both on and off continuous positive airways pressure (CPAP), and the occurrence of the Hering Breuer reflex has been investigated. Consecutive ventilated infants were recruited and only studied when making respiratory efforts during mechanical ventilation. Fifty-three infants were studied on 119 occasions, their median gestational age was 29 weeks and birthweight 1142 gms. All the infants were initially ventilated for the respiratory distress syndrome. Inspiratory and expiratory times were measured from simultaneous flow and oesophageal pressure recordings during a 20-second period of disconnection and during a similar period on 3 cmH2O CPAP. Prolongation of the inspiratory and expiratory time on CPAP compared to that measured during disconnection of more than 10% was evidence of the Hering Breuer reflex. No significant change in the inspiratory or expiratory time either on or off CPAP was noted either between days 1 to 5 or weeks 1 to 4. Both inspiratory and expiratory time tended to be longer on CPAP than during disconnection and these differences reached significance on days 1 and 2 and weeks 1 and 2. No influence of postnatal age was demonstrated on the proportion of infants in whom the Hering Breuer reflex was demonstrated. Our results suggest that, during the neonatal period, there is no influence of postnatal age on respiratory timings or reflex activity amongst ventilated infants who make spontaneous respiratory efforts during ventilation. These results have important implications regarding the optimum rate at which such infants should be ventilated.

Quantitative EEG changes under various conditions of hyperventilation in the sensorimotor cortex of the anaesthetized cat

The effects on the EEG rhythms recorded from the sensorimotor cortex (post-sigmoid gyrus) of anaesthetized cats were studied under 4 conditions of artificial mechanical hyperventilation (HV) before and after cervical bilateral vagotomy. In animals with intact vagus nerves, using visual examination, EEG changes were only observed within the 2nd min during HV produced by increased stroke volume (delta V) with associated hypocapnia. Quantitative EEG (qEEG) showed that, for the same increase in minute ventilation and the same degree of hypocapnia, delta V induced a greater and earlier relative decrease (2nd min) in the power density of delta, theta and alpha bands, than increased pump frequency (delta F). The delta F tests produced a fall only in the theta band and within the 3rd min. With constant paCO2, transient modifications occurred only with delta V and were limited to the first 30 sec. In bivagotomized cats, moderate EEG responses to delta V plus associated hypocapnia persisted partly in the alpha band. Finally, no changes appeared with delta V or delta F when the vagus nerves were cut and paCO2 was maintained constant. The present data suggest strongly that, in anaesthetized cats, peripheral vagal afferents from the respiratory system play a major role in the EEG changes caused by artificial hyperventilation.

Distribution of motor activity to expiratory muscles during sciatic nerve stimulation in the dog

The present study examined the effect of increasing sensory input from the lower limbs (assessed from the response to electrical stimulation of the sciatic nerve) on the distribution of electrical activity to the expiratory muscles. Expiratory muscle response to sciatic nerve stimulation (SNS) was compared to the response of the inspiratory muscles, and to their response to hypercapnia. In 16 anesthetized dogs afferent SNS increased ventilation and augmented the integrated EMG of all six expiratory muscles studied. Increases in abdominal muscle electrical activity were not uniform, being greater in the transversus abdominis and external oblique as compared to the internal oblique and the rectus abdominis. Increases in thoracic expiratory and inspiratory muscle activity during SNS were similar in magnitude. SNS performed while dogs were breathing 7% CO2, produced increased neural activity similar to those observed during O2 breathing. During CO2 rebreathing, at equal levels of minute ventilation, expiratory muscle responses to SNS and to CO2 were similar. In contrast, the rate of rise of the inspiratory muscle EMGs was greater during SNS. The present study indicates that the abdominal muscles participate in the respiratory response to afferent neural drive from skeletal muscles. The magnitude of their response is independent of their pre-stimulation level of activity and is similar to that observed during CO2 stimulated breathing.

Activities of pulmonary stretch receptors during ventilatory cycles without lung inflation

When lung inflation is temporarily withheld in paralyzed, ventilated cats with intact vagi, the activities of inspiratory motor nerves are greater during the second cycle without inflation than during the first. This response is not easily attributable to increasing drive from chemoreceptors as it is abolished by vagotomy. We examined the hypothesis that the increasing inspiratory activity is the result of decreasing inhibitory feedback from pulmonary stretch receptors (PSRs). Decerebrate, paralyzed cats were ventilated by a servo-respirator in accordance with their own phrenic nerve activity. Afferent activities from individual PSRs were recorded from a few cut fibers of one vagus nerve; the vagi were otherwise intact. When lung inflation was withheld, phrenic and hypoglossal nerve activities and the durations of inspiration and expiration all increased and were significantly greater during the second cycle without inflation than during the first. The frequency of PSR discharge was also greater during the second cycle and thus did not account for the responses recorded from the motor nerves. We conclude that the latter responses probably reflect neural processes within the brain stem, involving a persistent inhibitory influence from lung inflation, which outlasts the inflation itself.

Vagal influences on respiratory mechanics, pressures, and control in rats

In eight spontaneously breathing anesthetized rats airflow, volume, and tracheal pressure were measured. The passive and active mechanical properties of the respiratory system, the shape of the tracheal occlusion pressure wave (Potr), the decay of inspiratory muscle pressure during expiration, and parameters related to the control of breathing were computed both before and after bilateral cervical vagotomy. Pre- and post-vagotomy values of passive elastance, resistance, and time constant were similar. Active mechanics disclosed an increase of elastance and a decrease in resistance and in the time constant after vagotomy. The time course of Potr showed a downward concavity and was not modified by vagotomy in the range of control inspiratory times, whereas the shape of inspiratory muscle pressure decay during expiration was changed. The present data help to explain why after vagotomy the load-compensatory mechanisms are less effective.

Effects of end-expired pressure on phrenic output in servo-ventilated dogs

The pattern of breathing induced by increases in end-expired lung volume (EEVL) was determined in 9 anesthetized dogs. The pulmonary and systemic circulations were separately pump-perfused and the lungs were ventilated with a servo-ventilator actuated from the phrenic neurogram. EEVL was increased as a continuous ramp by slowly raising end-expired transpulmonary pressure from 1.5 to 12 cm H2O. Tidal volume (VT), inspiratory time (TI), and expiratory time (TE) were measured at vagal temperatures of 39 degrees C and 7 degrees C and following vagotomy. At a vagal temperature of 39 degrees C, increasing EEVL produced significant reductions in VT and TI while greatly prolonging TE. Vagal cooling to 7 degrees C, substantially altered the reflex response to increased EEVL. At 7 degrees C, VT decreased as EEVL increased, but the reduction was not so pronounced as at 39 degrees C. In addition, both TI and TE shortened. Increasing EEVL following vagotomy had no consistent effects on breathing pattern. We conclude that increasing EEVL stimulates tachypneic promoting pulmonary afferent nerves, most likely pulmonary C-fibers, but at normal vagal temperature their effect is masked by the stronger reflex inhibition of slowly adapting pulmonary stretch receptors.

Verification of a model for the mechanisms controlling expiratory duration in rabbits under various conditions

A mathematical model for the mechanisms controlling expiratory (E) duration was verified through comparison of its prediction with the relationships between TE and waveform parameters of various input patterns obtained by bilateral, simultaneous electrical stimulation of the largest vagal afferent fibers in vagotomized, paralyzed rabbits at normal or elevated chemical drive under light or deep barbiturate anesthesia. The model accurately reproduced experimental results in each animal and condition; it suggests that in the absence of vagal input (v.i.) an exponentially decaying central activity (phi) prevents inspiratory (I) onset until a time independent threshold (phi thr) is reached; the vagal component of phi results from fixed gain, long time constant (tau = 1.07 +/- 0.03 sec; mean +/- SE for N = 37 for N = 37 animals) temporal summation of expiratory v.i., being unaffected by inspiratory v.i.; central and vagal components share a common mechanism, the same value of tau applying to v.i. integration and to phi decay in the absence of v.i. under all conditions; the amplitude of the central component is proportional to tidal changes in central I activity, independently of the condition studied; and phi thr increases at elevated chemical drive, is unaffected by v.i., and decreases under deep anesthesia.

Respiratory volume-timing relationship during sustained elevation of functional residual capacity

In 7 spontaneously breathing dial-urethane anesthetized cats a negative pressure was produced around the thorax and abdomen to increase the functional residual capacity (FRC) by about 1 tidal volume for up to 60 min. A tracheal cannula was connected to a resistive manifold for selective loading of inspiration or expiration. Two resistive loads and tracheal occlusion were presented six times each at control FRC (FRCc), after 60 min at elevated FRC (FRCe) and 30 min after return to FRCc. Inspiratory and expiratory durations (TI and TE) were measured from diaphragmatic EMG. We observed that TI at FRCe (0.88 +/- 0.11 sec) was not significantly shorter than TI at FRCc (1.06 +/- 0.14 sec). Tracheal occlusion at FRCe caused a shorter TI (1.37 +/- 0.15 sec) than at FRCc (1.79 +/- 0.21 sec) (P less than 0.05). The slope (m) of the VI-TI relationship generated by the resistive loads at FRCe was steeper (m = -65 +/- 7 ml X sec-1) and shifted upward from the VI-TI curve at FRCc (-50 +/- 6 ml X sec-1) (P less than 0.05). The VE-TE relationship at FRCe was not significantly changed from control. Thirty minutes following return to FRCc, TI was still slightly shorter (0.96 +/- 0.11 sec) than the initial TI at FRCc. We conclude: (1) The slope of the VI-TI relationship is determined to a great extent by the total lung volume. However, under the conditions of sustained elevation of FRC, this relationship is influenced by the partial adaptation of slowly adapting pulmonary receptors SARs. (2) The increased SAR activity at end expiration during FRCe may not influence the control of TE.

Respiratory effects of cold air breathing in anesthetized cats

Respiratory effects of cold air breathing were studied in anesthetized cats. Two different protocols were used: the air temperature was either lowered in an isolated segment, constituted by the larynx and oropharynx or in lower airways, so that the cats inspired the cold air directly. Temperatures ranged between 37 and 8 degrees C (first protocol) or between 37 and 15 degrees C (second protocol). When the temperature fell below 15 degrees C in the upper segment, marked increase in lung resistance occurred, without any significant changes in ventilatory variables nor in diaphragmatic electrical activity. The section of superior laryngeal nerves abolished this bronchomotor effect. In present experimental circumstances, thermal changes measured in lower airways when cats breathed cold air were mainly located in the cervical trachea. An increase in lung resistance and weak but significant changes in the diaphragmatic electromyogram began when the inspired air temperature fell below 25 degrees C. A selective local block of conduction in small vagal fibres by procaine or section of vagus nerves suppressed all these effects. In all cases the cold-induced changes in lung mechanics began very early (less than 10 sec) but continued for few minutes after the physiological temperature range had been restored in airways. The present data strongly suggest that the bronchomotor response to cold air breathing is a reflex, mediated by afferent fibres in the superior laryngeal nerves and in the vagus nerves.

Response of pulmonary stretch receptors to shifts of functional residual capacity

The response of slowly adapting pulmonary stretch receptors (PSRs) to sustained elevations of functional residual capacity (FRC) was investigated in spontaneous breathing anesthetized cats. A subatmospheric pressure was produced around the thorax and abdomen to increase FRC by approximately one tidal volume (VT) for up to 60 min. During eupneic breathing the PSR frequency (fPSR) was closely related to changes in transpulmonary pressure (PTP), but occasionally hysteresis was observed in the FPSR - PTP relationship. Elevation of FRC caused most phasic PSRs to discharge continuously for a few breaths before returning to a phasic discharge pattern. During the shift in FRC there were increases in mean fPSR, peak fPSR firing threshold which were sustained throughout the period of elevated FRC. PSRs that normally showed discharges at FRC similarly increased their mean and peak firing rates. For all PSRs the y-intercept (fPSR at PTP = 0) of the fPSR - PTP relationship was decreased but the sensitivity of the PSR as defined by delta fPSR/delta PTP was not changed until the period of elevated FRC exceeded 30 min. Thereafter, PSR sensitivity tended to decline. These results suggest that PSRs undergo some modification of their discharge parameters during prolonged elevation of FRC.

Inspiratory muscle activity during rebreathing in intact and vagotomized rabbits

The relation between relative peak 'integrated' diaphragmatic (Adi) and cranial (u) or caudal (1) inspiratory intercostal activity (Aic) was assessed in intact and vagotomized rabbits during rebreathing. During unloaded rebreathing Aic increased markedly more than Adi, and Aicu more than Aicl, independently of intact vagi. Vagal signals facilitated inspiratory intercostals, since vagotomy or vagal blocks increased Adi more than Aic without changing diaphragm activity time course, and delta Aic/delta Adi in the same range of Adi values was greater before than after vagotomy. Reflexes from the chest wall were not involved since phrenic block after vagotomy modified rib cage motion without changing Aic, independently of chemical drive. Possibly chemical and vagal dependent changes in fusimotor activity contribution to VT, as the latter increases. Obstruction at FRC shifted postvagotomy Aic vs. Adi relationship upwards, suggesting reflex facilitation of intercostals by chest wall receptors. The strength of this reflex was largely independent of intact vagi, since pre- and postvagotomy Aic vs. Adi relations coincided, and of chemical drive, since postvagotomy delta Aic/delta Adi for obstructed and unimpeded rebreathing were similar.

Effects of pulmonary stretch receptor blockade on laryngeal responses to hypercapnia and hypoxia

Electromyographic patterns of the diaphragm and a posterior cricoarytenoid (PCA) muscle were evaluated in anesthetized rabbits with and without reversible blockade of pulmonary stretch receptors by inhalation of 200 ppm sulfur dioxide (SO2). Inspiratory activity of both muscles was increased by hypercapnia and by isocapnic hypoxia, with or without receptor blockade. Expiratory diaphragmatic activity was diminished by these stimuli and was likewise not qualitatively affected by SO2 exposure. Expiratory PCA activity was increased by hypercapnia and hypoxia prior to SO2 exposure, but decreased by these stimuli during stretch receptor blockade. These results are consistent with the previous finding that vagal afferents facilitate expiratory PCA activity, thus maintaining a patent laryngeal airway, even in the face of increased carotid chemoreceptor afferents, which inhibit expiratory activity of the PCA muscle. The results further indicate that some or all of the afferents responsible for this effect are from pulmonary stretch receptors.

Control of breathing during acute hemorrhage in anesthetized cats

We studied in anesthetized cats the ventilatory response to acute blood loss under hyperoxic iso-capnic conditions. From a blood pressure, of approximately 150 down to approximately 70 mm Hg ventilation increased on the average by 2.5 times. The ventilatory response was characterized by two phases: there was an initial phase (down to a PB approximately 100 mm Hg) of increase in frequency due to an excitatory effect on bulbo-pontine respiratory timing which was estimated from the duration of breaths following occlusion of the airways at the end expiratory volume. This effect was mainly due to the withdrawal of inhibitory afferents from the baroreceptors of the aortic arch. To this phase corresponded the phase of vasomotor compensation. Subsequently there was a phase of excitatory effect on the respiratory output which was estimated from the rate of change of the pressure developed in the airways during occluded breaths. This effect was mainly due to afferents from carotid sinuses; a minor role was due to the decrease in inhibitory afferents from carotid baroreceptors while the greater part was likely to be due to the hypoxic stimulation of glomus cells due to reduced blood flow. Following vagotomy above the superior laryngeal and sinus denervation the excitatory effect on respiratory timing and output were reduced to about 30% of that observed in intact cats.

Resting ventilatory pattern, mouth occlusion pressure, and the effects of aminophylline in asthma and chronic airways obstruction

Patients with obstruction of the airways can maintain normocapnia either by increasing the central inspiratory neuromuscular output or by altering the central timing of each breath. This point and the effects of administration of aminophylline on ventilatory regulation were studied in six normal subjects, seven asthmatic patients, and eight patients with unresponsive chronic obstruction of the airways. Spirometric and body plethysmographic values, the ventilatory pattern, and the mouth occlusion pressure did not differ between the two groups of patients. The results indicate that in these patients, normocapnia is maintained at rest by increased central inspiratory neuromuscular output; central respiratory timing is not altered. Intravenous administration of aminophylline (5.6 mg/kg of body weight) increased alveolar ventilation in all three groups, without increasing the uptake of oxygen. In normal subjects, there was no significant effect on ventilatory regulation or drive. In asthmatic patients the central timing of each breath was altered, with no significant effect on central inspiratory output. In unresponsive obstruction of the airways, the central inspiratory output increased transiently, with no effect on central timing.

Pentobarbital-induced apneusis in intact, vagotomized, and pneumotaxic-lesioned cats

While recording several respiratory parameters, sodium pentobarbital (PB) was infused into the inferior vena cava of spontaneously breathing, PB anesthetized cats. Three cat groups were investigated: intact control (group A); vagotomized (group B); pneumotaxic center-lesioned (group C). With a few exceptions, all cats developed PB-induced inspiratory apneusis. Groups B and C exhibited 10-sec inspiratory hold pattern at significantly lower PB levels than group A cats. All groups developed apnea at different PB levels. Ventilation was consistently depressed, predominantly by breathing frequently attenuation. Tidal volume remained comparable to control, but decreased in vagotomized cats at high PB levels. These results are interpreted to signify that (1) inspiratory inhibitory inputs are more susceptible to depression by PB than inspiratory drive mechanisms; (2) the breathing pattern of apneusis results when summed inspiratory inhibition is reduced below a critical minimum level; (3) vagal and pneumotaxic center inhibitions on inspiration are equally weighted at apneusis, but not at apnea. These results are further discussed in terms of the inspiratory off-switch model. A possible model of Biot respiration is also introduced.

Pulmonary receptor chemosensitivity and the ventilatory response to inhaled CO2 in the turtle

Ventilatory responses of unanesthetized turtles to changes in the intrapulmonary CO2 content of a vascularly isolated and an intact lung were measured during spontaneous breathing. The hyperpnea associated with inhalation of CO2 by the vascularly isolated lung was 19% of that associated with inhalation of CO2 by the intact lung. Transection of the vagus nerve supplying the isolated lung abolished this response. We conclude that both inhibition of pulmonary stretch receptor discharge with increasing levels of FICO2 and a functional increase in central inspiratory volume threshold during hypercapnia contribute to tidal volume increases following CO2 inhalation in normal animals. The major component of the ventilatory response of intact turtles to increasing levels of FICO2, however, was an increase in respiratory frequency. When CO2 was inspired only by the vascularly isolated lung the increase in respiratory frequency was only 21% of that recorded when the same levels of CO2 were inspired by the intact lung. Thus the ventilatory response of turtles to increasing levels of FICO2 is primarily dependent upon concomitant hypercapnia.

Central and direct vagal dependent control of expiratory duration in anaesthetized rabbits

In anaesthetized rabbits, total or partial (only inflation reflex nearly abolished) DC current vagal block was performed during inspiration (ITB and IPB), or expiration (ETB and EPB), or throughout the breathing cycle (CTB and CPB). During CTB inspiratory (Ti) and expiratory duration (Te) increased as after vagotomy. With ITB Ti equally Tivag; Te increased, but remained shorter than Tevag. During ETB, Ti was unchanged, Te increased, but remained shorter than Tevag. The sum of deltaTe during ITB and ETB equalled deltaTevag. During CPB and IPB, Ti and Te behaved as during ITB. With EPB, Ti was unchanged and Te shortened. Preferential stimulation of large myelinated fibers in the central vagal stumps during expiration lengthened Te. Inspiratory stimulation shortened both Ti and Te, restored breath timing of ETB, but not that of pre-vagotomy control. Hence, Te of eupneic breaths should depend on a central mechanism relating Te to preceding Ti and on expiratory vagal discharge, having both a small lengthening (from stretch receptors) and a variable shortening effect (from irritant receptors). Both central and peripheral mechanisms are affected by CO2 breathing.

The mechanism of rapid shallow breathing due to histamine and phenyldiguanide in cats and rabbits

In anaesthetized cats and rabbits we analyzed the rapid shallow breathing following exposure to histamine aerosol (mainly an irritant receptor stimulant) and i.v. injection of phenyldiguanide (mainly a J receptor stimulant). Both drugs caused a marked leftward displacement of the tidal volume (VT) vs inspiratory time (TI) relationship (Hering-Breuer threshold curve) without a corresponding increase in inspiratory flow rate so that inspiration was cut off at a lower VT and TI. The leftward displacement of the VT vs TI relationship occurred with a great shortening of the duration of inspiration during occluded breaths (T0I) accompanied by a shortening of the expiratory phase (T0E). These parameters monitored the central respiratory rhythm in absence of the phasic lung volume related vagal loop. It is suggested that the increased central respiratory frequency was due to the augmented firing of fibers from stimulated irritant and J receptors. Stimulation of these endings also caused the TE vs TI relationship to become steeper in cats and to be displaced downwards in rabbits.

Effects of single breath lung inflation on the pattern of subsequent breaths

In rabbits, on release of lung inflations 0.4 to 3.3 times control VT and lasting 1 to 30 sec, VT, peak diaphragmatic activity (Ep) and inspiratory duration (Ti) increased, whereas expiratory duration (Te) decreased relative to pre-inflation values. Similar changes occurred between pre- and postinflation occluded breaths. These changes lasted from a few breaths up to 30 sec, and were positively correlated with magnitude and duration of inflations. Postinflation changes of pulmonary stretch receptor activity were relatively small and limited to 1-3 breaths. At chemical drive close to control: (a) postinflation VT vs Ti relationship moved to the right without changing its slope, Ti occluded eventually exceeding Ti after vagotomy; (b) the Te vs Ti relationship moved downwards, its slope being decreased and eventually abolished; (c) the average rate of rise of E was decreased. An increase of VT, Ep and Ti, and a decrease Te also occurred on release of stimulation of the central ends of the cut vagi producing apnea at FRC in mono- and bilateral vagotomized rabbits. Postinflation effects were mainly of central origin and tentatively explained as rebound phenomena within the respiratory center.

Effects of uneven elastic loads on breathing pattern of anesthetized and conscious men

In anesthetized subjects rib cage strapping (RCS) did not change tidal volume (VT) and increased ventilation (V), whereas abdomen strapping (AS) markedly decreased VT and V. Both kinds of strapping decreased expiratory duration (TE), but did not change inspiratory duration (TI) and breathing rate. RCS and AS decreased lung volume by about 200 ml and increased the elastance of the repiratory system by 12 cm H2O/1 and 9 CM H20/l, repectively. The changes produced are mainly due to mechanical factors, although reflexes also seem to be operating in some cases. In conscious subjects RCS decreased VT, TI, TE and did not change V, whereas AS did not change these parameters. The different changes in conscious and anesthetized subjects show the effects of cortical influences, which also partly explain the differen effects elicited in conscious subjects by RCS and AS. The effects produced by RCS are mainly due to the sensation of hindrance to rib cage expansion, rather than to that of rib cage squeezing, as shown by experiments of RCS without reduction of rib cage volume.

Vagal control of diaphragm timing in cat while breathing at elevated lung volumes

This paper proposes and tests an hypothesis to account for the roles of the volume and rate components of vagal feedback in determining the steady-state pattern of breathing during continuous positive pressure breathing (PPB) and expiratory threshold loading (ETL) in Dial anesthetized cats. During PPB the duration of diaphragm activity (Tdi) is shortened; the duration of its expiratory pause (Tep) is lengthened with little or no change in cycle duration (Tt); with onset of inspiration, flow (dV/dt) is increased; as inspiration proceeds, flow decelerates (d2V/dt2). During ETL Tdi, Tep and Tt are all prolonged; dV/dt is decreased at onset of inspiration, with either no change or an acceleration in flow as inspiration proceeds. PPB and ETL cause similar increases in resting lung volume and Tep, and high negative correlations between Tdi and flow. These relationship suggest that the 'volume component' of vagal feedback is one important factor controlling Tep whereas the 'rate component' contributes to the restraint of Tdi.

Role of pulmonary stretch receptors during breathing in rabbits, cats and dogs

In order to mimic and then modify the input to the respiratory centre from pulmonary stretch receptors, the central ends of the cut cervical vagus nerves were electrically stimulated with a frequency determined by transpulmonary pressure through a voltage to frequency converter. At appropriate end-expiratory stimulation frequency and gain of the voltage to frequency converter, such stimulation restored the pre-vagotomised patterns of breathing in rabbits, cats and dogs. Mimicking the changes in activity from pulmonary stretch receptors that would be produced by such manoeuvres as hypercapnia, inflations and deflations, reproduced the responses in inspiratory duration that occurred with natural stimuli in the same animals with intact. There were some differences between the responses of expiratory durations to the natural and mimicked interventions; these may be related to the presence of increased expiratory muscle activity in the former. The results demonstrate that transpulmonary pressure-controlled stimulation of the afferent vagus nerves is a satisfactory method of mimicking and controlling the pulmonary stretch receptor feedback mechanism in studies on the control of breathing.

Interaction between vagal and chemoreceptors afferents in ventilatory response to transient hypercapnia (anaesthetized rabbit)

In rabbits anaesthetized with ethyl-carbamate, stimulation of chemoreceptors afferents was allowed by transient hypercapnia, before and after vagal blockade by DC current. In these relatively fast breathing animals, the transient hypercapnia produced light changes of inspiratory tidal volume (VI), inspiratory (TI) and expiratory durations (TE). Despite the identity of transient hypercapnia, it ensued that: (1) the higher the spontaneous VI and the lower the respiratory frequency (fR), the greater their respective changes (deltaVI and deltafR) during the ventilatory response; (2) after vagal blockade, greater changes in VI, TI, TE and mean inspiratory flow rate (VI/TI) occurred than in control state, while the relation between deltafR and fR was more significant than in control state. Respective roles played by vagal and chemoreceptors afferents in the ventilatory response to transient hypercapnia are discussed.

Effect of rib cage or abdomen compression at iso-lung volume on breathing pattern

In anesthetized rabbits a small compression of the rib cage (RC) caused a marked increase of breathing frequency (f), a marked reduction of expiratory duration (Te), a reduction of inspiratory duration (Ti) and tidal volume (VT), while an equal decrease of lung volume produced by abdominal compression(AC) caused a smaller increase of f and no change of Ti, and a slight increase of VT. Similar results occurred when normal end-expiratory volume was maintained during compression. The phenomena disappeared after bilateral vagotomy, whereas persisted after cordotomy in T1. Similar results occurred in dogs (with the exception that VT decreased during AC), whereas in cats only RC increased f by shortening Te. RC caused a marked increase of discharge in 11 out of 19 irritant receptor fibers, whereas AC caused an increase only in 2. In most of the pulmonary stretch receptor fibers the change of activity produced by compression paralleled the lung volume change. The effects of vagal cooling on Ti, Te and the VT-Ti relationship with and without compression suggest irritant receptors as responsible for the different ventilatory pattern during RC and AC.

The effect of limb movements on the regulation of depth and rate of breathing

In anesthetized dogs and rabbits passive or active limb movements (1) shifted to the left the relationship between tidal volume (Vt) and inspiratory time (Ti), (2) lowered the relationship between expiratory time (Te) and Ti and decreased its slope, and (3) increased the output to the inspiratory muscles (Vt/Ti). These effects increased with increasing the frequency of movements. Similar effects were obtained after vagotomy. When the stimulus was started during expiration. Te was shorted in spite of the previous unaffected Ti, Arterial PCO2 during exercise was similar (active movements) or below (passive movements) control value. Since other chemical and physical humoral factors do not seem involved, the whole increase of ventilation should be produced by neurogenic stimuli. The time course of Te, Ti and VT/Ti at the onset and at the offset of limb movements indicates an abrupt and a slow component in the neurogenic drive. A single contraction of the limb during expiration of inspiration affected the timing and the VT/Ti of 3-8 breaths.

Airway occlusion pressures in awake and anesthetized goats

The pressures generated by the inspiratory muscles as they contract isometrically during airway occlusion seem to be a measure of respiratory neuron efferent activity. The ventilatory and occlusion pressure responses to increasing levels of CO2 were studied in goats, awake and anesthetized, with and without inspiratory flow resistance. Hypercapnia was produced by rebreathing. Randomly, during rebreathing, inspiratory airflow was prevented on single breaths. Ventilation and pressures developed during the first 100, 200, 300 and 400 milliseconds of an inspiratory effort against a complete occlusion increased linearly with CO2 in both awake and anesthetized animals. Anesthesia reduced both the ventilatory and occlusion pressure responses to CO2. Inspiratory resistance increased occlusion pressure responses in awake goats but not in the same animals when anesthetized. Inspiratory airflow resistance seems to augment respiratory efferent activity as reflected in the pressure responses only in conscious goats. Thus the response to an inspiratory resistance seems to depend on the state of consciousness.

Role of peripheral and central chemosensitive afferents in the control of depth and frequency of breathing

In anaesthetized cats the response to hypercapnia was studied during normoxia, hypoxia (increased peripheral chemosensitive afferents, IPA) and after carotid sinus denervation (decreased peripheral chemosensitive afferents, DPA) in terms of: (a) central output to the inspiratory muscles, (b) bulbopontine respiratory activity and (c) threshold-inhibition curve for termination of inspiration (Vr/Ti relationship). IPA increased, whereas DPA decreased the central output, as estimated from the rate of change of the subatmospheric pressure developed in the trachea during occlusion of the airways. IPA and DPA did not modify the bulbo-pontine rhythm, as estimated from the timing of occluded breaths (phasic vagal afferents nil), nor the Vt/Ti relationship, both of which have been shown to vary as a function of PACO2. It is concluded that peripheral chemosensitive afferents influence only the output of the respiratory centres, whereas central chemosensitive afferents influence also the bulbo-pontine respiratory rhythm and the threshold inhibition curve for termination of inspiration.