Ventilatory, circulatory, endocrine, and renal effects of almitrine infusion in man: a contribution to high altitude physiology

Diuresis at altitude was thought to be the result of chemoreceptor stimulation leading to a reduction of cardiac volume overload. This hypothesis was tested in ten young, healthy subjects by infusion of almitrine (0.5 mg.kg-1 body mass within 30 min) assuming analogous sites of action, i.e. arterial chemoreceptors and pulmonary vessels, for almitrine as for hypoxic hypoxia. The results show that almitrine increases ventilation, heart rate, systolic blood pressure, central venous pressure and natriuresis, but fails to increase significantly atrial natriuretic peptide plasma concentration and diuresis. It is concluded: (1) that almitrine has similar sites of action as hypoxic hypoxia at about 5000 m, (2) that natriuresis during arterial chemoreceptor stimulation might reduce cardiac volume overload, (3) that the volume excretion hypothesis, in particular the pathways from the cardiac volume overload to the water diuresis, need, for an understanding of the hypoxia-induced diuresis, further direct investigations at altitude.     

Respiratory adjustments of the unanaesthetized chicken, Gallus domesticus, to elevated metabolism elicited by 2,4-dinitrophenol or cold exposure

The effects of pharmacologically elevated metabolism on ventilation, gaseous exchange and blood gases were studied in spontaneously breathing unanaesthetized decerebrate chickens using 2,4-dinitrophenol (DNP) injected intravenously in successive single doses of 2.5-5.0 mg/kg. These responses were compared with the cardiorespiratory adjustments to elevated metabolism evoked by shivering in conscious birds. Oxygen consumption increased with cumulative amounts of DNP, reaching 275 +/- 30% of control values at the maximum tolerated dose of 10-15 mg/kg. Increases in ventilation matched the changes in oxygen consumption via increases in both breathing frequency and tidal volume. Arterial blood gases and pH remained unchanged. Exposure to cold (Ta = 2 +/- 2 degrees C) caused oxygen consumption to increase to 185 +/- 21% of control values. Respiratory and cardiovascular adjustments were similar to those evoked by DNP and were comparable to those produced by low intensity treadmill exercise (cf. Gleeson and Brackenbury, 1984).     

Ontogeny of respiratory control and pulmonary mechanics in newborn rabbits

Maturation of the respiratory pattern and the active and passive mechanical properties of the respiratory system were assessed in 19 tracheotomized rabbits (postnatal age range: 1-26 days) placed in a body plethysmograph. With maturation both minute ventilation and tidal volume significantly increased, whereas respiratory frequency decreased. When normalized for body weight (kg) both the passive (Rrs X kg) and active (R'rs X kg) resistances of the respiratory system significantly increased with age, whereas the corresponding passive (Crs X kg-1) and active (C'rs X kg-1) compliances significantly decreased. At any given age R'rs X kg only slightly exceeded Rrs X kg, whereas C'rs X kg-1 was significantly lower than Crs X kg-1. Moreover, the maturational increases in Rrs X kg and R'rs X kg exceeded the corresponding decreases in Crs X kg-1 and C'rs X kg-1, resulting in significant age-related increases in both the passive (tau rs) and active (tau'rs) time constants of the respiratory system. Due to the age-related increases in tau'rs, producing a delayed volume response to any given inspiratory driving pressure, the relative volume loss obtained at any time during inspiration was greater in the maturing rabbit. On the other hand, because of concomitant compensatory changes in respiratory pattern, evidenced by increases in inspiratory duration with age, the end-inspiratory tidal volume loss in the maturing animal was maintained generally less than 10% at all postnatal ages. Thus maturational changes in respiratory pattern appear coupled to changes in the active mechanical properties of the respiratory system. The latter coupling serves to optimize the transduction of inspiratory pressure into volume change in a manner consistent with establishing the minimum inspiratory work of breathing during postnatal development.     

Alpha 2 adrenergic control of ventilation in the rat]

In anaesthetized rats, ventilatory stimulation induced by phentolamine, an alpha sympatholytic agent, emphasizes the role of some adrenergic mechanisms in the control of the respiratory centres activity. Phentolamine (5 and 10 mg.kg-1, iv) stimulates ventilation after a 4 s latency, tidal volume and respiratory rate being both increased. A same response can also be provoked 10 min later, by a second identical iv administration, systemic blood pressure remaining then stable at its previous low level. Hyperventilation is also observed when phentolamine is injected in totally denervated rats, without any remaining baro- or chemosensitivity. Stimulation is thus due to a central activity in relation with the release of inhibitory influences. Phentolamine also causes hyperventilation after prazosin pretreatment indicating that the alpha 1 adrenergic blockade is not involved in the post-phentolamine stimulation. This is an alpha 2 adrenergic transmission dependent mechanism. Variation of the systemic blood pressure is not the main mechanism involved in the hyperventilation induced by phentolamine. Meanwhile, baroreceptor activity modulates the central response to the drug, as shown by the negative influence of the post-vasopressin arterial hypertension. Hyperoxia is also a modulating factor acting by two ways: an inhibition of the peripheral chemoreceptors activity is added to an arterial hypertension. On the other side, activation of these chemoreceptors by almitrine bismesilate increases the respiratory responses to phentolamine. As already shown by one of us (Lagneuax, 1986), phentolamine pretreated rats are more responsive to hypoxia and to almitrine. Moreover, these phentolamine pretreated rats are protected against cardiovascular collapses and against apnea, frequently observed during hypoxia without CO2 compensation.     

Effects of almitrine on genioglossal and diaphragmatic electromyograms

We previously demonstrated dose-dependent increases in both hypoglossal and phrenic electroneurograms after almitrine in anesthetized, paralyzed, and vagotomized cats. We have now investigated the effect of this peripheral chemoreceptor stimulant on diaphragmatic and genioglossal (GG, an upper airway-maintaining muscle) electromyograms in five unanesthetized, chronically instrumented, spontaneously breathing adult cats during slow-wave sleep. In 12 studies almitrine doses of 1.0-6.0 mg/kg increased inspired minute ventilation (VI), frequency (f), and tidal volume (VT) and decreased expiratory time (TE). However, almitrine doses as high as 6.0 mg/kg failed to augment phasic inspiratory GG activity. To determine why almitrine induced phasic inspiratory upper airway activity in anesthetized, vagotomized cats but not in sleeping cats, additional studies were performed. In four dose-response studies in three pentobarbital-anesthetized cats, almitrine, 1.0-6.0 mg/kg, did not produce phasic inspiratory GG activity. Almitrine did induce phasic inspiratory GG activity in two of three studies in three vagotomized, tracheostomized, alpha-chloralose-urethan-anesthetized cats. These results suggest that almitrine would not be useful in obstructive sleep apnea, yet because almitrine markedly increased VI, f, and VT and decreased TE in unanesthetized sleeping cats the drug may be effective in patients who lack normal central neural respiratory drive, such as the preterm infant.     

Effects of almitrine on hypoglossal and phrenic electroneurograms

Almitrine increases breathing by stimulating peripheral chemoreceptors. Previous studies suggest clinical usefulness in the adult with chronic obstructive pulmonary disease, but little data are available to decide whether almitrine would be helpful in diseases involving pharyngeal airway obstruction, such as apnea of prematurity or obstructive sleep apnea. We investigated the effect of intravenous almitrine on hypoglossal (HG), an upper airway nerve, and phrenic (PHR) neural activity in eight alpha-chloralose-urethan anesthetized, paralyzed, vagotomized, and artificially ventilated cats. Recordings were made of raw and integrated HG and PHR electroneurograms (ENGs), alveolar PCO2, arterial PO2, arterial blood pressure, and rectal temperature. A dose-response study of cumulative almitrine doses ranging from 0.1 to 4.0 mg/kg was performed in three cats. The interactive effects of almitrine and hypoxic stimulation were investigated in four cats. The interactive effects of almitrine and hypercapnic stimulation were investigated in five cats. The interactive effects of almitrine and ventilatory timing were investigated in six cats. We found that 1) almitrine doses as low as 0.1 mg/kg iv increased both HG and PHR ENG activity, with a maximum effect at approximately 1.0 mg/kg; 2) almitrine markedly increased HG and PHR ENG activity at all arterial PO2 values from 35-175 Torr; 3) almitrine increased HG and PHR ENG activity at all arterial PCO2 values from 30-70 Torr; and 4) almitrine increased the ratio of tidal volume to inspiratory time and decreased the inspiratory muscle duty cycle at normoxia and eucapnia.     

Sinoaortic contribution to ventilatory control in exercising dogs

The role of the sinoaortic reflexes in the regulation of ventilation during exercise was evaluated in seven awake dogs prepared with chronic tracheostomies and arterial catheters. Each dog ran on a treadmill at several work loads before and after sinoaortic denervation and served as its own control. Minute ventilation in the sinoaortic denervated state was significantly reduced from intact values by 10-40% at the mild and moderate levels of exercise [O2 uptake (VO2) = 30-50 ml . kg-1 . min-1] mainly as a result of a lowering respiratory frequency. At higher work loads (VO2 = 70-80 ml . kg-1 . min-1) minute ventilation was similar in the intact and denervated states, but the pattern of ventilation was altered with a higher frequency and a lower tidal volume in the denervated state. The rise in ventilation toward a stable plateau was slower at all work loads in the denervated than in the intact state. After sinoaortic denervation, arterial PCO2(PaCO2) levels were significantly elevated above intact PaCO2 levels during both the preexercise period and the steady state at all exercise levels. These results suggest that the sinoaortic reflexes contribute to both the control of ventilation and the pattern of breathing during mild and heavy levels of exercise in the conscious dog.     

Separation of factors responsible for change in breathing pattern induced by instrumentation

Employment of mouthpiece and noseclips (MP + NC) has repeatedly been shown to increase tidal volume (VT), but its effect on respiratory frequency (f) and its subsets is controversial. The mechanisms accounting for this alteration in breathing pattern are poorly understood and may include stimulation of oral or nasal sensory receptors or alteration in the route of breathing. In this study we demonstrated that use of a MP + NC, compared with nonobtrusive measurement with a calibrated respiratory inductive plethysmograph, alters the majority of the volume and time indexes of breathing pattern, with increases in minute ventilation (P less than 0.01), VT (P less than 0.001), inspiratory time (TI, P less than 0.05), expiratory time (TE, P less than 0.05), mean inspiratory flow (P less than 0.05), and mean expiratory flow (P less than 0.05) and a decrease in f(P less than 0.05). Separating the potential mechanisms we found that when the respiratory route was not altered, independent oral stimulation (using an occluded MP) or nasal stimulation (by applying paper clips to the alae nasi) did not change the breathing pattern. In contrast, obligatory oral breathing without additional stimulation of the oral or nasal sensory receptors caused increases in VT (P less than 0.05), TI (P less than 0.05), and TE (P less than 0.01) and a fall in f(P less than 0.05). Heating and humidifying the inspired air did not prevent the alteration in breathing pattern with a MP. Thus change in the respiratory route is the major determinant of the alteration in breathing pattern with a MP + NC.(ABSTRACT TRUNCATED AT 250 WORDS)     

Stimulation of vagal C-fibers alters timing and distribution of respiratory motor output in cats

Pulmonary vascular congestion or pulmonary embolism in humans produces shallow tachypnea, and indirect experimental evidence suggests that this characteristic breathing pattern may result from activation of vagal unmyelinated afferents from the lung. We have investigated, in decerebrate cats, reflex changes in breathing pattern and in the activation of the diaphragm, posterior cricoarytenoid, and thyroarytenoid muscles caused by activating C-fiber afferents in the vagus nerve. The right vagus nerve was sectioned distal to the origin of the recurrent laryngeal nerve, eliminating vagal afferent traffic although preserving motor innervation of the larynx on that side. The left cervical vagus was stimulated electrically, and efferent activation of the laryngeal muscles was avoided by cutting the left recurrent laryngeal nerve. Transmission to the brain of vagal afferent traffic resulting from this stimulation was controlled by graded cold block of the nerve cranial to the site of application of the stimulus. Activation of C-fibers, when A-fibers were blocked, significantly decreased respiratory period and amplitude of diaphragm inspiratory burst. In addition, this selective activation of vagal C-fibers augmented postinspiratory activity of the diaphragm and recruited phasic expiratory bursts in the thyroarytenoid. We conclude that, in unanesthetized decerebrate cats, afferent traffic of vagal C-fibers initiates a pontomedullary reflex that increases respiratory frequency, decreases tidal volume, and augments braking of expiratory airflow.     

Ventilatory effects of impaired glial function in a brain stem chemoreceptor region in the conscious rat.

Glia are thought to regulate ion homeostasis, including extracellular pH; however, their role in modulating central CO2 chemosensitivity is unclear. Using a push-pull cannula in chronically instrumented and conscious rats, we administered a glial toxin, fluorocitrate (FC; 1 mM) into the retrotrapezoid nucleus (RTN), a putative chemosensitive site, during normocapnia and hypercapnia. FC exposure significantly increased expired minute ventilation (VE) to a value 38% above the control level during normocapnia. During hypercapnia, FC also significantly increased both breathing frequency and expired VE. During FC administration, maximal ventilation was achieved at approximately 4% CO2, compared with 8-10% CO2 during control hypercapnic trials. RTN perfusion of control solutions had little effect on any ventilatory measures (VE, tidal volume, or breathing frequency) during normocapnic or hypercapnic conditions. We conclude that unilateral impairment of glial function in the RTN of the conscious rat results in stimulation of respiratory output.     

Separate and combined effects of temperature and hypoxia on breathing pattern in the domestic fowl

Summary Minute ventilation (V _E), tidal volume (V _T), respiratory frequency (f) and clavicular air sac gas composition were measured in conscious domestic fowl breathing air and hypoxic gas mixtures at neutral (18±1°C) and raised (33±1°C) air temperatures. Increases inV _E caused by inhalation of 10%, 8% or 6.5% O₂ in N₂, respectively, were independent of temperature although at each level the absoluteV _E was ca. 21·min⁻¹ greater in the panting birds. Changes in respiratory pattern during hypoxia were markedly dependent on temperature. At 18°C almost all of the increasedV _E resulted from increasedf. At 33°C hypoxia led to a strong suppression off and increase inV _T. It is concluded that hyperthermia and hypoxia are additive and non-interactive in their effects on ventilatory drive, in agreement with previously reported effects of hypercapnia and physical exercise on breathing in panting fowl.     

Almitrine bismesylate and the central and peripheral ventilatory response to CO2

Effects of almitrine bismesylate on the peripheral and central chemoreflex to a CO2 challenge during normoxia were studied in nine alpha-chloralose-urethan anesthetized cats. With the dynamic end-tidal CO2 forcing technique the ventilatory response after a square-wave change in end-tidal PCO2 (PETCO2) was partitioned into a central and a peripheral part using a two-compartment model. With almitrine administered intravenously (0.6 mg/kg followed by a maintenance dose of 0.4 mg.kg-1 X h-1) the CO2 sensitivity of the peripheral chemoreflex increased on the average from 0.315 to 0.564 l.min-1 X kPa-1 (P less than 0.001, 6 cats, 73 runs), whereas the CO2 sensitivity of the central chemoreflex remained the same (P = 0.87). The extrapolated PETCO2 at zero ventilation (apneic threshold) of the (total) steady-state response curve decreased on the average from 3.50 to 2.36 kPa (P less than 0.001). With the artificial brain stem perfusion technique it was confirmed that almitrine did not affect ventilation by administering it to the blood perfusing the brain stem. We conclude that almitrine bismesylate during normoxia enhances the CO2 sensitivity of the peripheral chemoreflex loop and decreases the apneic threshold due to an action located outside the brain stem.     

Hyperpnoea and CO2 sensitivity of the respiratory centres during exercise

The aim of this study was to specify whether exercise hyperpnoea was related to the CO2 sensitivity of the respiratory centres measured during steady-state exercise of mild intensity. Thus, ventilation (VE), breathing pattern [tidal volume (VT), respiratory frequency (f), inspiratory time (TI), total time of the respiratory cycle (TTOT), VT/TI, TI/TTOT] and CO2 sensitivity of the respiratory centres determined by the rebreathing method were measured at rest (SCO2re) and during steady-state exercise (SCO2ex) of mild intensity [CO2 output (VCO2) = 20 ml.kg-1.min-1] in 11 sedentary male subjects (aged 20-34 years). The results showed that SCO2re and SCO2ex were not significantly different. During exercise, there was no correlation between VE and SCO2ex and, for the same VCO2, all subjects had very close VE values normalized for body mass (bm), regardless of their SCO2ex (VEbm0.75 = 1.44 l.min-1.kg-1 SD 0.10). A highly significant positive correlation between SCO2ex and VT (normalised for bm) (r = 0.80, P less than 0.01), TI (r = 0.77, P less than 0.01) and TTOT (r = 0.77, P less than 0.01) existed, as well as a highly significant negative correlation between SCO2ex and (normalised for bm-0.25) (r = -0.73, P less than 0.01). We conclude that the hyperpnoea during steady-state exercise of mild intensity is not related to the SCO2ex. The relationship between breathing pattern and SCO2ex suggests that the breathing pattern could influence the determination of the SCO2ex. This finding needs further investigation.     

Effects of industrial respirators on breathing pattern at different work levels

The effects of a filtering device and an air-line apparatus on breathing pattern were studied in healthy men with different physical characteristics and work capacity. The subjects comprised nine construction workers aged 35-44, and nine firemen aged 21-35. The construction workers' mean maximal oxygen consumption (VO2max) was 34.5 ml min-1 kg-1, the firemen's 66.9 ml min-1 kg-1. Breathing pattern was analyzed for its components, inspiratory time, expiratory time, breathing frequency, tidal volume, and pulmonary ventilation at rest, during two submaximal treadmill walks when the subjects' absolute work load was equal, and during recovery. Neither the filtering device nor the air-line apparatus had a significant effect on breathing pattern when compared with the control values measured twice with a low-resistance breathing valve. A significantly longer expiratory time, lower breathing frequency, and smaller pulmonary ventilation were found for the firemen with the breathing valve and the industrial respirators. The breathing pattern of the construction workers and the firemen differed, but the alterations were not induced by the use of the filtering device or the air-line apparatus when studied at aerobic work levels up to 60% VO2max.     

Development of the ventilatory response to hypoxia in Swiss CD-1 mice.

We examined developmental changes in breathing pattern and the ventilatory response to hypoxia (7.4% O(2)) in unanesthetized Swiss CD-1 mice ranging in age from postnatal day 0 to 42 (P(0)-P(42)) using head-out plethysmography. The breathing pattern of P(0) mice was unstable. Apneas were frequent at P(0) (occupying 29 +/- 6% of total time) but rare by P(3) (5 +/- 2% of total time). Tidal volume increased in proportion to body mass ( approximately 10-13 ml/kg), but increases in respiratory frequency (f) (55 +/- 7, 130 +/- 13, and 207 +/- 20 cycles/min for P(0), P(3), and P(42), respectively) were responsible for developmental increases in minute ventilation (690 +/- 90, 1,530 +/- 250, and 2,170 +/- 430 ml. min(-1). kg(-1) for P(0), P(3), and P(42), respectively). Between P(0) and P(3), increases in f were mediated by reductions in apnea and inspiratory and expiratory times; beyond P(3), increases were due to reductions in expiratory time. Mice of all ages showed a biphasic hypoxic ventilatory response, which differed in two respects from the response typical of most mammals. First, the initial hyperpnea, which was greatest in mature animals, decreased developmentally from a maximum, relative to control, of 2.58 +/- 0.29 in P(0) mice to 1. 32 +/- 0.09 in P(42) mice. Second, whereas ventilation typically falls to or below control in most neonatal mammals, ventilation remained elevated relative to control throughout the hypoxic exposure in P(0) (1.73 +/- 0.31), P(3) (1.64 +/- 0.29), and P(9) (1. 34 +/- 0.17) mice but not in P(19) or P(42) mice.     

AMPA glutamate receptors and respiratory control in the developing rat: anatomic and pharmacological aspects

The developmental role of alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA) glutamate receptors in respiratory regulation remains undefined. To study this issue, minute ventilation (V(E)) was measured in 5-, 10-, and 15-day-old intact freely behaving rat pups using whole body plethysmography during room air (RA), hypercapnic (5% CO(2)), and hypoxic (10% O(2)) conditions, both before and after administration of the non-N-methyl-D-aspartate (NMDA) receptor antagonist 1,2,3, 4-tetrahydro-6-nitro-2,3-dioxobenzo[f]quinoxaline-7-sulfonamide disodium (NBQX; 10 mg/kg ip). In all age groups, V(E) during RA was unaffected by NBQX, despite reductions in breathing frequency (f) induced by increases in both inspiratory and expiratory duration. During hypoxia and hypercapnia, V(E) increases were similar in both NBQX and control conditions in all age groups. However, tidal volume was greater and f lower after NBQX. To determine if AMPA receptor-positive neurons are recruited during hypoxia, immunostaining for AMPA receptor (GluR2/3) and c-fos colabeling was performed in caudal brain stem sections after exposing rat pups at postnatal ages 2, 5, 10, and 20 days, and adult rats to room air or 10% O(2) for 3 h. GluR2/3 expression increased with postnatal age in the nucleus of the solitary tract (NTS) and hypoglossal nucleus, whereas a biphasic pattern emerged for the nucleus ambiguus (NA). c-fos expression was enhanced by hypoxia at all postnatal ages in the NTS and NA and also demonstrated a clear maturational pattern. However, colocalization of GluR2/3 and c-fos was not affected by hypoxia. We conclude that AMPA glutamate receptor expression in the caudal brain stem is developmentally regulated. Furthermore, the role of non-NMDA receptors in respiratory control of conscious neonatal rats appears to be limited to modest, albeit significant, regulation of breathing pattern.     

Archosaurian respiration and the pelvic girdle aspiration breathing of crocodyliforms

Birds and crocodylians, the only living archosaurs, are generally believed to employ pelvic girdle movements as a component of their respiratory mechanism. This in turn provides a phylogenetic basis for inferring that extinct archosaurs, including dinosaurs, also used pelvic girdle breathing. I examined lung ventilation through cineradiography (high-speed X-ray filming) and observed that alligators indeed rotate the pubis to increase tidal volume, but did not observe pelvic girdle movement contributing to lung ventilation in guinea fowl, emus or tinamous, despite extensive soft-tissue motion. Re-examination of fossil archosaurs reveals that pubic rotation evolved in basal crocodyliforms and that pelvic girdle breathing is not a general archosaurian mechanism. The appearance of pelvic aspiration in crocodyliforms is a striking example of the ability of amniotes to increase gas exchange or circumvent constraints on respiration through the evolution of novel accessory breathing mechanisms.     

Effects of expiratory loading on respiration in humans

We examined the effects of expiratory resistive loads of 10 and 18 cmH2O.l-1.s in healthy subjects on ventilation and occlusion pressure responses to CO2, respiratory muscle electromyogram, pattern of breathing, and thoracoabdominal movements. In addition, we compared ventilation and occlusion pressure responses to CO2 breathing elicited by breathing through an inspiratory resistive load of 10 cmH2O.l-1.s to those produced by an expiratory load of similar magnitude. Both inspiratory and expiratory loads decreased ventilatory responses to CO2 and increased the tidal volume achieved at any given level of ventilation. Depression of ventilatory responses to Co2 was greater with the larger than with the smaller expiratory load, but the decrease was in proportion to the difference in the severity of the loads. Occlusion pressure responses were increased significantly by the inspiratory resistive load but not by the smaller expiratory load. However, occlusion pressure responses to CO2 were significantly larger with the greater expiratory load than control. Increase in occlusion pressure observed could not be explained by changes in functional residual capacity or chemical drive. The larger expiratory load also produced significant increases in electrical activity measured during both inspiration and expiration. These results suggest that sufficiently severe impediments to breathing, even when they are exclusively expiratory, can enhance inspiratory muscle activity in conscious humans.     

Self-controlled artificial respiration

We compared respiratory parameters during natural and self-controlled mechanical breathing to investigate mechanisms of respiratory control in alert humans. The self-control of mechanical breathing is realised manually: duration and velocity of air flow are controlled by left and right hands, resp. In this case, the respiratory afferent information is used to control activity of hand muscles but not of breathing muscles. The findings show that lung ventilation during self-controlled mechanical breathing increases by 7.5 l/min. at resting, by 6.3 l/min. during an exercise, as compared with the natural breathing. The increase in the lung ventilation occurs on account of an increase in the tidal volume but the frequency of the self-controlled mechanical breathing tends to be lesser at resting and was statistically significantly lower in exercise that at natural breathing. The exercise increases the lung ventilation by 13.0 l/min. at natural breathing and by 11.8 l/min. during self-controlled mechanical breathing. The findings suggest that the increased lung ventilation during self-controlled mechanical breathing is connected with creation of a new movement skill, and the modified pattern of self-controlled mechanical breathing is caused by a process of cortical transformation of respiratory afferents signals to efferent signals towards the hand muscles.     

Control of respiratory pattern in conscious dog: effects of heat and CO2

We measured tidal volume (VT) and inspiratory (TI) and expiratory (TE) durations in five conscious tracheostomized dogs breathing air or 5% CO2 in air either at normal (20 degrees C) or elevated (30 degrees C) ambient temperatures. Respiratory frequency ranged between 16 and 333/min due to changes in both TI and TE. During panting TI exceeded TE. During air inhalation instantaneous ventilation (V) spontaneously ranged from 100 to 1,600 ml . kg-1 . min-1. Hypercapnia, heat stress, or both, increased this range of V by increasing maximum V, primarily due to increases in mean inspiratory flow. Under these conditions, changes in TI accounted for more of the spontaneous changes in breath duration. During inhalation of air and 5% CO2, a positive correlation between VT and TI was obtained for TI between 0.13 and 1.05 s; above 1.05 s VT decreased. Heat stress increased VT at a given TI. We suggest that either the decay rate or position of the inspiratory off-switch threshold curve (Clark and von Euler, J. Physiol. London 222: 267, 1972) varies in conscious dogs. Shifts in either the reset (onset) value or decay rate of the curve yield a positive correlation between VT and TI. This modification to the Clark-von Euler model implies that the primary effect of anesthesia on respiratory control is fixation of the inspiratory off-switch threshold curve.