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

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.

Right and left vagus nerves regulate breathing by multiplicative interaction

Although it has been recognized for more than a century, we still do not know how the two vagus nerves interact to produce Hering-Breuer reflex. In the current study, we tested the hypothesis that the vagus nerves interact via a multiplicative effect. We examined the Hering-Breuer reflex before and after unilateral (first) and then bilateral (second) vagotomies in the mouse. The lung is mostly innervated homolaterally. Since the right and left lung formed 68.2 and 31.8% of total lung weight, if the interaction is mediated by an additive mechanism, unilateral vagotomy would remove the reflex effects by 68.2 and 31.8%, respectively. Instead, unilateral vagotomy removed 85.4 ± 6.0% (>68.2%) or 52.8 ± 3.7% (>31.8%) of the reflex effects on respiratory rate (n=9, P<0.05); and removed 79.1 ± 4.5% (>68.2%) or 59.3 ± 9.1% (>31.8%) of the effect on expiratory pause induced by lung inflation (n=12, P<0.05). Since the first vagotomy removes more reflex effect than the second vagotomy, we conclude that the two vagus nerves exert their Hering-Breuer reflex effects by a multiplicative effect.

Development of avian intrapulmonary chemoreceptors

Although avian intrapulmonary chemoreceptors (IPC) have been studied extensively in adults, the maturation of IPC CO(2) sensitivity during development is completely unknown. To begin investigating IPC development we asked two fundamental questions: (1) Are IPC capable of sensing CO(2) during early development, and, if so, how early? And, (2) does IPC CO(2) sensitivity during early development exhibit postnatal maturation compared to IPC discharge characteristics in adult ducks? We addressed these questions by recording from single IPC Anas platyrhynchos ducklings beginning approximately 6 h prior to internal pipping through 4 days of postnatal development. We then compared mean IPC discharge characteristics during early development with mean IPC activity from adult ducks greater than 12 weeks old. In total, we recorded 28 individual IPC from 5 ducklings and 12 adult ducks. Results show that IPC were capable of responding to rapid step changes in CO(2) before hatching occurred, during the paranatal developmental period. We also found that mean IPC activity during early development had increased peak discharge frequencies, greater spike frequency adaptation, and less tonic CO(2) sensitivity when compared to adults (P< or =0.05). These results suggest that during early development phasic IPC CO(2) sensitivity is fully developed, yet tonic IPC CO(2) sensitivity exhibits postnatal maturation possibly associated with hatching. These results also suggest that the mechanisms that underlie phasic and tonic IPC action potential discharge, and therefore the degree of partial spike frequency adaptation, may be independent processes with different developmental trajectories.

Subtype Composition and Responses of Respiratory Neurons in the Pre-Bötzinger Region to Pulmonary Afferent Inputs in Dogs

The brain stem pre-Bötzinger complex (pre-BC) plays an important role in respiratory rhythm generation. However, it is not clear what function each subpopulation of neurons in the pre-BC serves. The purpose of the present studies was to identify neuronal subpopulations of the canine pre-BC and to characterize the neuronal responses of subpopulations to experimentally imposed changes in inspiratory (I) and expiratory (E) phase durations. Lung inflations and electrical stimulation of the cervical vagus nerve were used to produce changes in respiratory phase timing via the Hering-Breuer reflex. Multibarrel micropipettes were used to record neuronal activity and for pressure microejection in decerebrate, paralyzed, ventilated dogs. The pre-BC region was functionally identified by eliciting tachypneic phrenic neural responses to localized microejections of dl-homocysteic acid. Antidromic stimulation and spike-triggered averaging techniques were used to identify bulbospinal and cranial motoneurons, respectively. The results indicate that the canine pre-BC region consists of a heterogeneous mixture of propriobulbar I and E neuron subpopulations. The neuronal responses to ipsi-, contra-, and bilateral pulmonary afferent inputs indicated that I and E neurons with decrementing patterns were the only neurons with responses consistently related to phase duration. Late-I neurons were excited, but most other types of I neurons were inhibited or unresponsive. E neurons with augmenting or parabolic discharge patters were inhibited by ipsilateral inputs but excited by contra- and bilateral inputs. Late-E neurons were more frequently encountered and were inhibited by ipsi- and bilateral inputs, but excited by contralateral inputs. The results suggest that only a limited number of neuron subpopulations may be involved in rhythmogenesis, whereas many neuron types may be involved in motor pattern generation.

Ventilatory behavior during sleep among A/J and C57BL/6J mouse strains

The pattern of breathing during sleep could be a heritable trait. Our intent was to test this genetic hypothesis in inbred mouse strains known to vary in breathing patterns during wakefulness (Han F, Subramanian S, Dick TE, Dreshaj IA, and Strohl KP. J Appl Physiol 91: 1962-1970, 2001; Han F, Subramanian S, Price ER, Nadeau J, and Strohl KP, J Appl Physiol 92: 1133-1140, 2002) to determine whether such differences persisted into non-rapid eye movement (NREM) and rapid eye movement (REM) sleep. Measures assessed in C57BL/6J (B6; Jackson Laboratory) and two A/J strains (A/J Jackson and A/J Harlan) included ventilatory behavior [respiratory frequency, tidal volume, minute ventilation, mean inspiratory flow, and duty cycle (inspiratory time/total breath time)], and metabolism, as performed by the plethsmography method with animals instrumented to record EEG, electromyogram, and heart rate. In all strains, there were reductions in minute ventilation and CO2 production in NREM compared with wakefulness (P < 0.001) and a further reduction in REM compared with NREM (P < 0.001), but no state-by-stain interactions. Frequency showed strain (P < 0.0001) and state-by-strain interactions (P < 0.0001). The A/J Jackson did not change frequency in REM vs. NREM [141 +/- 15 (SD) vs. 139 +/- 14 breaths/min; P = 0.92], whereas, in the A/J Harlan, it was lower in REM vs. NREM (168 +/- 14 vs. 179 +/- 12 breaths/min; P = 0.0005), and, in the B6, it was higher in REM vs. NREM (209 +/- 12 vs. 188 +/- 13 breaths/min; P < 0.0001). Heart rate exhibited strain (P = 0.003), state (P < 0.0001), and state-by-strain interaction (P = 0.017) and was lower in NREM sleep in the A/J Harlan (P = 0.035) and B6 (P < 0.0001). We conclude that genetic background affects features of breathing during NREM and REM sleep, despite broad changes in state, metabolism, and heart rate.

Altered breathing pattern after prenatal nicotine exposure in the young lamb

Maternal smoking during pregnancy is a risk factor for sudden fetal and infant death as well as obstructive airway disease in childhood. Fetal nicotine exposure affects organ development. The aim of the present study was to investigate effects of fetal nicotine exposure on lung function in young lambs. Nine unanesthetized, awake, prenatally nicotine-exposed lambs (N) (approximate maternal dose: 0.5 mg/kg) and 12 nonexposed control lambs (C) were studied repeatedly for 5 weeks after birth using a pneumotachograph and a computerized method for breath-by-breath determinations. N and C lambs had similar minute ventilation but a markedly different breathing pattern. At both 5 and 21 days, average age, N lambs had significantly lower tidal volumes and higher respiratory rates than C lambs. Inspiratory drive (P(0.1)) and effective impedance were significantly higher in N lambs compared with C lambs only at 5 days. Prenatal nicotine exposure appears to have long-term effects on the postnatal breathing pattern, suggesting altered lung function, e.g., increased airway resistance, decreased lung compliance, or both. The increased inspiratory drive is most likely secondary to increased impedance of the respiratory system. These changes are most marked close to birth but persist during the initial postnatal period.

Effects of vagal denervation on cardiorespiratory and behavioral responses in the newborn lamb

Recently, Wong et al. (Wong KA, Bano A, Rigaux A, Wang B, Bharadwaj B, Schurch S, Green F, Remmers JE, and Hasan SU, J Appl Physiol 85: 849-859, 1998) demonstrated that fetal lambs that have undergone vagal denervation prenatally do not establish adequate alveolar ventilation shortly after birth. In their study, however, vagal denervation was performed prenatally and the deleterious effects of vagal denervation on breathing patterns and gas exchange could have resulted from the prenatal actions of the neurotomy. To quantify the relative roles of pre- vs. postnatal vagal denervation on control of breathing, we studied 14 newborn lambs; 6 were sham operated, and 8 were vagally denervated below the origin of the recurrent laryngeal nerve. Postoperatively, all denervated animals became hypoxemic and seven of eight succumbed to respiratory failure. In vagally denervated lambs, expiratory time increased, whereas respiratory rate, minute ventilation, and lung compliance decreased compared with the sham-operated animals. In the early postoperative period, the frequency of augmented breaths was lower but gradually increased over time in the denervated vs. sham-operated group. The dynamic functional residual capacity was significantly higher than the passive functional residual capacity among the sham-operated group compared with the denervated group. No significant differences were observed in the prevalence of various sleep states and in the amount of total phospholipids or large- and small-aggregate surfactants between the two groups. We provide new evidence indicating that intrauterine actions of denervation are not required to explain the effects of vagal denervation on postnatal survival. Our data suggest that vagal input is critical in the maintenance of normal breathing patterns, end-expiratory lung volume, and gas exchange during the early neonatal period.

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.

Inspiration-promoting vagal reflex under NMDA receptor blockade in anaesthetized rabbits

1. This study describes a novel vagal respiratory reflex in anaesthetized rabbits. In contrast to the well-known inspiratory (I) off-switching by vagal afferent excitation, this vagal reflex initiates and maintains the central I activity of phrenic nerve discharges in rabbits pre-treated with antagonists of N-methyl-D-aspartate-type excitatory amino acid receptors (NMDA-Rs). 2. Under NMDA-R blockade with either dizocilpine (0.025-0.3 mg kg-1), D-2-amino-5-phosphonopentanoic acid (AP5, 0.5-1 mg, i.c.v.) or ketamine (10 mg kg-1), vagal stimulation at low frequencies (5-40 Hz) during the I phase prevented or markedly delayed the spontaneous I termination. In contrast, stimulation of the same vagal afferent at the same intensity but at a higher frequency (100-160 Hz) during the I phase immediately terminated the I phase. 3. In non-vagotomized rabbits, maintaining the tidal volume at end-expiratory levels during the I phase prevented spontaneous I termination and maintained apneusis after NMDA-R blockade with dizocilpine. 4. Brief stimulation of vagal afferents at low frequency (5-40 Hz) during the expiratory (E) phase constantly initiated phrenic I discharge after NMDA-R block. 5. We conclude that low-frequency discharge of vagal pulmonary stretch receptor afferents, as when lung volume is near functional residual capacity, promotes central I activity under NMDA-R blockade.

Pulmonary vagal reflexes and breathing pattern are not altered in elastase-induced emphysema in rats

The role of nonmyelinated and myelinated vagal afferents in pulmonary reflexes and breathing pattern was examined in elastase-treated emphysemic rats. Fourteen to 17 days after intratracheal instillation of 1 IU/gm of porcine pancreatic elastase or 0.5 mL of saline, elastase-treated rats had a decreased alveolar surface area to volume of parenchyma (Sv) (42.44 +/- 1.7 vs. 31.51 +/- 1.1 mm2/mm3), increased quasistatic compliance (QSC) (1.05 +/- 0.06 vs. 1.25 +/- 0.09 mL/cm H2O), functional residual capacity (FRC) (4.31 +/- 0.10 vs. 5.88 +/- 0.37 mL), residual volume (RV) (3.02 +/- 0.14 vs. 4.27 +/- 0.31 mL), and total lung capacity (TLC) (14.04 +/- 0.28 vs. 15.58 +/- 0.54 mL). There were no changes in the strength of the pulmonary chemoreflex, the strength of the Hering-Breuer inflation reflex, or breathing pattern before or after vagal perineural capsaicin treatment (VPCT) or vagotomy. There were, however, significant negative correlations between Sv and TLC, FRC and RV, and a near significant (p < .09) negative correlation between Sv and QSC, but no significant correlations between Sv and indices of either the pulmonary chemoreflex or Hering-Breuer inflation reflex. The results indicate that pulmonary vagal nonmyelinated and myelinated reflex activity and breathing pattern are not affected by elastase-induced emphysema in rats.

Neuronal control of airways smooth muscle

Sensory afferent nerves relay impulses from the airways to the central nervous system so that appropriate changes in bronchomotor tone and breathing patterns may occur. The dominant efferent control of airways smooth muscle is exerted via bronchoconstrictor parasympathetic cholinergic nerves. In some species this is opposed by bronchodilator sympathetic noradrenergic nerves. In addition, there exist both excitatory bronchoconstrictor and inhibitory bronchodilator non-adrenergic, non-cholinergic pathways. This review examines the role of the different branches of the autonomic nervous system in the control of airways smooth muscle tone with particular reference to modulation of these branches and the interactions which may exist between them.

Preservation of integrative function in a perfused guinea pig brain

The mammalian brain has been one of the most difficult organs to maintain using artificial perfusion. Normal biochemistry, histology, and electrophysiology of the brain have been demonstrated for limited periods in vitro, but it has been more difficult to maintain complex, integrative neuronal activity such as the electroencephalogram (EEG) or programmed motor output. Normal motor output, other than reflex activity, has not previously been demonstrated in a perfused brain preparation. This paper reports the first preservation of normal function in a complete motor network, including intact afferent and efferent pathways, during perfusion of the mammalian brain. The brain, rostral spinal cord and peripheral nervous system of the guinea pig were perfused in situ using an artificial blood containing the oxygen carrier, perfluorotributylamine (FC-43). This preparation was maintained normothermic, whereas many other perfused brain preparations have been maintained hypothermic to prolong viability. Survival was enhanced by the addition of HEPES buffer to the perfusion medium, probably by increasing carbon dioxide transport. The duration of normal EEG was extended to 8 h. Spontaneous respiratory motor output with normal waveform and temporal pattern was recorded from the phrenic nerve for an average of 6 h. The respiratory motor output responded appropriately to blood pCO2, temperature, blood flow, drug concentrations, and electrical stimulation of vagal afferent fibers. This preparation represents a significant advance in the ability to preserve neural function during perfusion, and should offer advantages for studying cellular electrophysiology of intact, functioning neural networks, as well as neurochemistry and neuropharmacology.

Sensory interaction with central 'generators' during respiration in the dogfish

The activity in sensory and motor nerves of the gills was recorded from selected branches of the vagus nerve in decerebrate dogfish, Scyliorhinus canicula. Vagal motoneuronal activity was observed at the start of the rapid pharyngeal contraction and was followed by sensory nerve activity which preceded the slow expansion phase. Rhythmical vagal motoneuronal activity was still present after all movements had been prevented by curare paralysis although the frequency of the rhythm was higher than in the ventilating fish. Electrical stimulation of vagal sensory fibres had 3 effects on the ventilatory movements. (1) It evoked a reflex contraction of several gill muscles after a latency of about 11 ms. (2) It could reset the respiratory cycle because a stimulus given during expansion delayed the onset of the subsequent contraction. (3) The stimulus could entrain the rhythm if it was given continuously at a frequency close to that of ventilation. The vagal motor rhythm was disrupted by trigeminal nerve stimulation in the paralyzed fish but not if the motor rhythm was being entrained by vagal nerve stimulation. Vagal sensory activity may be important, therefore, in maintaining the stability of the generating circuits.

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.

Tachypnoeic response to amyl nitrite inhalation in the rabbit

Intratracheal inhalation of amyl nitrite, a non-specific smooth muscle relaxant, in the pentobarbitone/urethane anaesthetized rabbit caused reductions in tidal volume and both inspiratory and expiratory times, without a preceding apnoea, that were independent of the associated hypotension and of reflex influences from the carotid sinus region but dependent on supra-abdominal vagal integrity. In artificially ventilated, paralyzed rabbits amyl nitrite caused a pronounced sensitization of pulmonary stretch receptors (PSRs) during the inflation phase, typically with a reduction in the level of activity during the deflation phase. The time course of the change in the pattern of PSR activity paralleled that of the tachypnoeic response. The sensitization of a small sample of rapidly adapting 'irritant' receptors was of a significantly shorter duration. A unitary analysis of non-myelinated vagal afferents was not attempted. The sensitization of these vagal afferents cannot be attributed to the smooth muscle relaxant properties of amyl nitrite since other relaxants (sodium nitrite, sodium nitroprusside, phentolamine) did not possess this capacity, and such properties would be expected to diminish their activities.

The effect of the phase relationship between the arterial blood gas oscillations and central neural respiratory activity on phrenic motoneurone output in cats

The aim of the present experiments in artificially ventilated, anesthetized cats was to investigate in which circumstances the timing of the arterial blood gas oscillations within the respiratory cycle can be of importance in determining phrenic motoneurone output. The phase relationship phi was defined as the relative position of the peak of the phrenic bursts within the current continuously measured PaO2 oscillations. It was judged breath by breath whether there was a relationship between phi and neural tidal volume, and neural inspiratory and expiratory duration. Within cats, PETCO2 was kept constant at about 1.5-2% above apneic threshold. It was found that phi indeed partly determined these ventilatory parameters provided the oscillations were large enough. This was evident in normoxia; in moderate hypoxia the influence of phi was demonstrable more easily, i.e. at smaller oscillation amplitudes. In both conditions the effect of phi on neural tidal volume was most pronounced. Neural tidal volume was maximal when peak inspiration coincided with the expiratory trough of the PaO2 oscillations. A 1:1 phase lock between phrenic activity and the ventilatory only occurred when the pump frequency was close to the cats own breathing frequency. Bilateral carotid sinus nerve section abolished the effects of phi.

Effect of graded cooling of intermediate areas on respiratory response to vagal input

The present study was undertaken to determine if the phrenic responses to vagally mediated inputs are also affected by focal cooling of the intermediate areas (IA) of the ventral medulla. Anesthetized, paralyzed cats whose vagi and carotid sinus nerves had been cut were studied. The IA were cooled focally with a thermostatically controlled thermode. When the IA were 40 degrees C, low intensity vagal stimulation caused inhibition of phrenic activity. The stimulus was also applied when IA were cooled to 30 and 20 degrees C. The magnitude of the inhibition was unaffected by the cooling. In another series of experiments, high intensity vagal stimulation was used. This led to an hyperpnea when IA were 40 degrees C. The magnitude of the response was much smaller when the test stimulus was given at lower IA temperatures. The effect of cooling IA on the phrenic response to mechanical stimulation of pulmonary stretch receptors and airway irritant receptors were also studied in cats with intact vagi. We found that the response to irritant receptor, but not to stretch receptor, stimulation was abolished by the cooling. We conclude that the intermediate areas are involved in the integration of afferent input from airway irritant receptors that reaches the respiratory controller via high threshold vagal afferents, but not involved in processing signals from pulmonary stretch receptors.

Effects of bronchoconstriction on breathing during normoxia and hypoxia in anesthetized cats

The effect of an increase in bronchomotor tone on control of breathing during both normoxia and hypoxia, and the role of vagal afferents in regulating these responses were studied in 15 anesthetized cats. Minute ventilation (VE) was measured with a pneumotachograph connected in series with a tracheal cannula. Total diaphragmatic EMG activity per minute (means p X f, peak EMG moving average X respiratory frequency) was measured to assess the central inspiratory drive. Bronchoconstriction was generated by inhalation of methacholine aerosol (10-30 breaths, 0.5% solution) which increased total lung resistance to approximately 400% of the control value. Transient hypoxia was induced by allowing the cats to rebreathe a hypoxic gas mixture (4.5% O2 balanced N2) for approximately 1 min. During normoxia, bronchoconstriction increased VE from a baseline of 100 to 129 +/- 7% (mean +/- SEM; P less than 0.05) and increased (means p X f) from 100 to 174 +/- 16% (P less than 0.01). During hypoxia, the response of (means p X f) to bronchoconstriction (404 +/- 40%) was still greater than without bronchoconstriction (306 +/- 35%; P less than 0.01), but the responses of VE were not significantly different between these two conditions (P greater than 0.05). After sectioning both vagus nerves the bronchoconstriction-induced increase in central inspiratory drive was either reduced (during normoxia) or abolished (during hypoxia). These results suggest that stimulation of vagal bronchopulmonary afferents are involved in regulating the ventilatory responses to bronchoconstriction. Other non-vagal factors, such as intrinsic properties and reflex responses of the respiratory muscles, may also contribute, in part, to the observed responses.

Respiratory responses to stimulation of branchial vagus nerve ganglia of a teleost fish

The effects of electrical stimulation of epibranchial vagus ganglia upon respiration of the carp were investigated. Single shocks evoked fast twitch responses in a number of respiratory muscles with latencies around 18 msec to the beginning and 30-35 msec to the peak of activity. Shocks given during abduction decreased the respiratory cycle duration by shortening abduction and accelerating adduction. Stimuli given throughout most of adduction also shortened the respiratory cycle, accelerating the adduction only. These responses are similar to vagally mediated lung receptor reflexes of mammals. Stimulation with short trains of pulses produced a rapid expansion-contraction movement. This movement resembles in all respects (shape, time in the respiratory cycle, muscle coordination) the intermediate expansion of a normal coughing movement. Continual stimulation at frequencies close to the normal respiratory rate had a synchronising influence upon respiration, speeding up or slowing down its rate. HRP applied to the third vagal ganglion showed that there is a small projection of this ganglion to the nucleus intermedius facialis, although the majority of sensory fibres terminate in the vagal lobe. The nucleus intermedius facialis is already known to connect directly with the respiratory motor centres and thus might provide a pathway for the fast twitch response. A projection was also found to the nucleus ambiguus; in mammals this nucleus plays an important role in the regulation of respiratory movements.

Bilateral reflex effects on phrenic nerve activity in response to single-shock vagal stimulation

The bilateral reflex actions of vagus nerve afferent signals on phrenic efferent activity have been tested by unilateral graded single shock electrical stimulation. An early excitation (latency 3-5 msec) was more prominent in the phrenic nerve contralateral to the stimulated vagus. Spinal cord hemisection at C3 eliminated both contralateral and ipsilateral responses: thus, both were mediated via descending tracts in the contralateral cord. A bilaterally symmetrical early inhibition (latency 8-12 msec) followed the early excitation. The electrical thresholds for evoking the early responses and the temperature for blocking these responses during graded vagal cooling were closely similar to the threshold and blocking temperature for pulmonary stretch receptor afferents. Higher stimulus strengths evoked a strong, bilaterally similar, late excitation (latency 12-20 msec) followed by a late inhibition. At very high stimulus strengths a third excitation (latency 25-30 msec) could appear. Sometimes these responses were followed by lowered phrenic activity for the remainder of inspiration. Single shock stimulation of the intact vagus nerve or of the peripheral end of the cut recurrent laryngeal nerve provoked, by the contraction of laryngeal muscles, a strong, short latency (12 msec) inhibition of phrenic activity mediated by superior laryngeal nerve afferents. The implications of these results with respect to the reflex pathways of the different responses and their possible integration in the central respiratory control mechanisms are discussed.

A reinvestigation of the Geman-Miller respiratory oscillator model

The model of Geman-Miller of the respiratory oscillator is reinvestigated for its interpretation of the parameters: W and T. It was found that the interpretation of Geman-Miller, that the parameters T and W represent the chemosensitive feedback, is incorrect. The extension to the model made by Engeman and Swanson is not necessary to produce afterdischarge. It is demonstrated that the afterdischarge can be predicted in the original Geman-Miller model from the Jacobian Matrix.

Properties of inspiratory termination by superior laryngeal and vagal stimulation

Electrical stimulation of two respiratory afferent nerves, the vagus and the internal branch of the superior laryngeal, was used to terminate inspiration. The short latency responses of phrenic motoneurones to these stimuli were studied to determine if inspiratory termination was preceded by a characteristic phrenic motoneurone discharge pattern, reflecting changes in brainstem inspiratory neurone discharge and inspiratory terminating mechanisms. Stimulus trains of sufficient intensity delivered to the superior laryngeal nerve terminated inspiration within 50 ms and were preceded by a stereotyped pattern of phrenic motoneurone discharge. This consisted of a short latency (disynaptic), predominantly contralateral excitation in response to the first shock of the train, followed by a marked and long lasting inhibition. In contrast, vagal stimulation typically terminated inspiration hundreds of milliseconds after the onset of the stimulus train and was not preceded by a stereotyped pattern of phrenic motoneurone responses to single shocks. Transient short latency responses were obtained but were extremely small, requiring considerable excitation followed by a moderate bilateral depression of activity. Inspiration could be terminated with or without the presence of these short latency responses. These results indicate that superior laryngeal and vagal (presumably pulmonary stretch receptor) afferents have different projections to brainstem inspiratory neurones and may exert their effects on inspiratory duration through different, but as yet undefined, neural mechanisms.

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.

II. Effect of CO2 on afferent vagal endings in the canine lung

We have attempted to identify the afferent endings responsible for the pulmonary-CO2 ventilatory reflex. We recorded afferent vagal impulses arising from the left lung in anesthetized dogs with separately ventilated lungs. When the left pulmonary artery was occluded, left lung PCO2 fell to 3 mm Hg and slowly-adapting pulmonary stretch receptor activity increased 46%. Firing declined to its original intensity when left lung PCO2 was raised in steps by administration of CO2, firing decreasing most between 2 and 19 mm Hg, and least between 30 and 50 mm Hg. Irritant receptor activity also increased (from 2.8 to 7.4 impulses/sec) after pulmonary arterial occlusion, the effect being reversed by administration of CO2. These procedures caused trivial changes in pulmonary and bronchial C-fiber activity. Effects on both slowly-adapting stretch receptors and irritant receptors appeared to result from a direct action of CO2 on the endings themselves, rather than from mechanical changes in the lung. Changes in slowly-adapting stretch receptor activity provide an adequate explanation for the pulmonary-CO2 ventilatory reflex, the relationship between impulse frequency and lung PCO2 suggesting that these afferents may have a role in limiting CO2 loss under conditions causing hypocapnia, but be less effective in stimulating breathing during hypercapnia.

The alteration of CO2 respiratory sensitivity in chickens by thoracic visceral denervation

We measured respiratory movements in nine groups of six cockerels, 20-24 weeks of age. We opened the thorax and all air sacs, and unidirectionally ventilated each lung separately. The right lung received constant P(CO2), while the P(CO2) was altered to the left lung. There were only small differences in response to P(CO2) alterations whether both pulmonary circulations were intact, the left pulmonary circulation was blocked, or the left lung was denervated and the right pulmonary circulation blocked, suggesting (1) that the extrapulonary and pulmonary P(CO2) -sensitive afferents (in one lung) have equivalent influence, and (2) the influences of the two afferent systems are not additive. Respiratory sensitivity after bilateral vagotomy is small despite pulmonary innervation by CO2 -sensitive spinal afferents, perhaps one reason for abnormal respiration after vagotomy. The respiratory influences of pulmonary vagal and spinal CO2-sensitive afferents are also non-additive, suggesting that non-additive interactions among afferents controlling respiration may be common in the chicken. Rates of response to altered intrapulmonary P(CO2) are determined by central mechanisms and not the time for CO2 distribution or receptor response.