Alteration by hyperoxia of ventilatory dynamics during sinusoidal work

The effects of hyperoxia on ventilatory and gas exchange dynamics were studied utilizing sinusoidal work rate forcings. Five subjects exercised on 14 occasions on a cycle ergometer for 30 min with a sinusoidally varying work load. Tests were performed at seven frequencies of work load during air or 100% O2 inspiration. From the breath-by-breath responses to these tests, dynamic characteristics were analyzed by extracting the mean level, amplitude of oscillation, and phase lag for each six variables with digital computer techniques. Calculation of the time constant (tau) of the ventilatory responses demonstrated that ventilatory kinetics were slower during hyperoxia than during normoxia (P less than 0.025; avg 1.56 and 1.13 min, respectively). Further, for identical work rate fluctuations, end-tidal CO2 tension fluctuations were increased by hyperpoxia. Ventilation during hyperoxia is slower to respond to variations in the level of metabolically produced CO2, presumably because hyperoxia attenuates carotid body output; the arterial CO2 tension is consequently less tightly regulated.     

Hypoxic ventilatory response and arterial desaturation during heavy work

Arterial desaturation in athletes during intense exercise has been reported by several authors, yet the etiology of this phenomenon remains obscure. Inadequate pulmonary ventilation, due to a blunted respiratory drive, has been implicated as a factor. To investigate the relationship between the ventilatory response to hypoxia, exercise ventilation, and arterial desaturation, 12 healthy male subjects [age, 23.8 +/- 3.6 yr; height, 181.6 +/- 5.6 cm; weight, 73.7 +/- 6.2 kg; and maximal O2 uptake (VO2max), 63.0 +/- 2.2 ml.kg-1 min-1] performed a 5-min treadmill test at 100% of VO2max, during which arterial blood samples and ventilatory data were collected every 15 s. Alveolar PO2 (PAO2) was determined using the ideal gas equation. On a separate occasion the ventilatory response to isocapnic hypoxia was measured. Arterial PO2 decreased by an average of 29 Torr during the test, associated with arterial desaturation [arterial O2 saturation (SaO2) 92.0%]. PAO2 was maintained; however, alveolar-arterial gas pressure difference increased progressively to greater than 40 Torr. Minimal hypocapnia was observed, despite marked metabolic acidosis. There was no significant correlation observed between hypoxic drives and ventilation-to-O2 uptake ratio or SaO2 (r = 0.1 and 0.06, respectively, P = NS). These data support the conclusions that hypoxic drives are not related to maximal exercise ventilation or to the development of arterial desaturation during maximal exercise.     

Parameters of ventilatory and gas exchange dynamics during exercise

To determine the precise nonsteady-state characteristics of ventilation (VE), O2 uptake (VO2), and CO2 output (VCO2) during moderate-intensity exercise, six subjects each underwent eight repetitions of 100-W constant-load cycling. The tests were preceded either by rest or unloaded cycling ("0" W). An early component of VE, VO2, and VCO2 responses, which was obscured on any single test by the breath-to-breath fluctuations, became apparent when the several repetitions were averaged. These early responses were abrupt when the work was instituted from rest but were much slower and smaller from the 0-W base line and corresponded to the phase of cardiodynamic gas exchange. Some 20 s after the onset of the work a further monoexponential increase to steady state occurred in all three variables, the time constants of which did not differ between the two types of test. Consequently, the exponential behavior of VE, VO2, and VCO2 in response to moderate exercise is best described by a model that incorporates only the second phase of the response.     

Chemoreflex modulation of ventilatory dynamics during exercise in humans

The precision of arterial blood gas homeostasis following a change of work rate depends on the response kinetics of ventilation. The carotid bodies (CB's) have been proposed as modulators of these kinetics. The present investigation was undertaken to determine whether the effect is specific to CB activation or whether other factors that augment the exercise hyperpnea would produce a similar response. We therefore established the effects of increased CB and central (C) chemoreflex activation on the inspired ventilatory (VI) dynamics for moderate-intensity cycling. Work tests were separately performed with air, 12% O2 to increase CB activity, 100% O2 to "abolish" CB activity, and CO2 in O2 to increase C activity. The time constant of the VI response was substantially shortened by hypoxia (40 s) compared with air breathing (58 s) and increased by 100% O2 (92 s) and, even more so, by CO2 in O2 (101 s). We conclude that increased carotid (but not central) chemoreflex responsiveness speeds the kinetics of the exercise hyperpnea by a process that is not merely the consequence of increased ventilatory drive.     

Ventilatory dynamics in children and adults during sinusoidal exercise

The ventilatory response to sinusoidally varying exercise was studied in five adults and seven prepubertal children to determine whether the faster kinetics of ventilation observed in children during abrupt changes in exercise intensity remained more rapid when exercise intensity varied continuously. Each subject exercised on a cycle ergometer first against a constant load and then against a load fluctuating over six different periods ranging from 0.75 to 10 min. The pedal rate was kept constant for all loads. The inspiratory minute ventilation was determined breath-by-breath. Amplitude (A) and phase angle (phi) of the fundamental component and the first harmonics of the ventilatory response were calculated by Fourier analysis for an integer number of waves for each period. From the relationship between A, phi and frequency, dynamic parameters of a first order model with and without delay were compared between adults and children. Firstly we found that the ventilatory time constant was significantly faster in children: 49.7 (SD 9.1) s vs 74.6 (SD 11.1) s (P less than 0.01). Secondly, the change in A and phi with the frequency was not however characteristic of a first order system without delay in most of the subjects (phi greater than 90 degrees for the shorter periods). Thirdly, even when the ventilatory control system was described as a first order model with a positive delay, time constants remained significantly shorter in children: 45.6 (SD 5.7) s vs 67.4 (SD 13) s (P less than 0.01). The ability to increase ventilation faster in children appeared to be a characteristic of the ventilatory control system during exercise independent of the type of drive used.     

Human ventilatory response to acute hyperoxia during and after 8h of both isocapnic and poikilocapnic hypoxia

Tansley, J. G., C. Clar, M. E. F. Pedersen, and P. A. Robbins. Human ventilatory response to acute hyperoxia during andafter 8 h of both isocapnic and poikilocapnic hypoxia.J. Appl. Physiol. 82(2): 513-519, 1997.During 8 h of either isocapnic or poikilocapnic hypoxia,there may be a rise in ventilation(E) thatcannot be rapidly reversed with a return to higherPO₂ (L. S. G. E. Howard and P. A. Robbins. J. Appl. Physiol. 78:1098-1107, 1995). To investigate this further, threeprotocols were compared: 1) 8-hisocapnic hypoxia [end-tidalPCO₂(PET_CO2 ) held atprestudy value, end-tidal PO₂(PET_O2) = 55 Torr],followed by 8-h isocapnic euoxia(PET_O2 = 100 Torr);2) 8-h poikilocapnic hypoxia followed by 8-h poikilocapnic euoxia; and3) 16-h air-breathing control.Before and at intervals throughout each protocol, theE response to eucapnichyperoxia (PET_CO2 held1-2 Torr above prestudy value,PET_O2 = 300 Torr) wasdetermined. There was a significant rise in hyperoxic E over 8 hduring both forms of hypoxia (P < 0.05, analysis of variance) that persisted during the subsequent 8-heuoxic period (P < 0.05, analysis ofvariance). These results support the notion that an 8-h period ofhypoxia increases subsequenthyperoxic E, even if acid-base changes have been minimized through maintenance ofisocapnia during the hypoxic period.

     

Influence of body CO2 stores on ventilatory dynamics during exercise

Pulmonary CO2 flow (the product of cardiac output and mixed venous CO2 content) is purported to be an important determinant of ventilatory dynamics in moderate exercise. Depletion of body CO2 stores prior to exercise should thus slow these dynamics. We investigated, therefore, the effects of reducing the CO2 stores by controlled volitional hyperventilation on cardiorespiratory and gas exchange response dynamics to 100 W cycling in six healthy adults. The control responses of ventilation (VE), CO2 output (VCO2), O2 uptake (VO2), and heart rate were comprised of an abrupt increase at exercise onset, followed by a slower rise to the new steady state (t1/2 = 48, 43, 31, and 33 s, respectively). Following volitional hyperventilation (9 min, PETCO2 = 25 Torr), the steady-state exercise responses were unchanged. However, VE and VCO2 dynamics were slowed considerably (t1/2 = 76, 71 s) as PETCO2 rose to achieve the control exercise value. VO2 dynamics were slowed only slightly (t1/2 = 39 s), and heart rate dynamics were unaffected. We conclude that pulmonary CO2 flow provides a significant stimulus to the dynamics of the exercise hyperpnea in man.     

Peripheral chemoreflex function in hyperoxia following ventilatory acclimatization to altitude.

After a period of ventilatory acclimatization to high altitude (VAH), a degree of hyperventilation persists after relief of the hypoxic stimulus. This is likely, in part, to reflect the altered acid-base status, but it may also arise, in part, from the development during VAH of a component of carotid body (CB) activity that cannot be entirely suppressed by hyperoxia. To test this hypothesis, eight volunteers undergoing a simulated ascent of Mount Everest in a hypobaric chamber were acutely exposed to 30 min of hyperoxia at various stages of acclimatization. For the second 10 min of this exposure, the subjects were given an infusion of the CB inhibitor, dopamine (3 microg. kg(-1). min(-1)). Although there was both a significant rise in ventilation (P < 0.001) and a fall in end-tidal PCO(2) (P < 0.001) with VAH, there was no progressive effect of dopamine infusion on these variables with VAH. These results do not support a role for CB in generating the persistent hyperventilation that remains in hyperoxia after VAH.     

Effect of sinusoidal forcing of ventilatory volume on avian breathing frequency

Awake chickens were unidirectionally ventilated at 3.6 l . min-1 with 3.2-4.8% CO2 in air. The air sacs on each side were made confluent and implanted with exit tubes connected to the following three devices: 1) a system of constant-flow generators which remove air at exactly the same rate that it entered the trachea, allowing no port for spontaneous volume changes; 2) a sinusoidal pump to force volume changes in the chicken; and 3) a pressure transducer to record air sac pressure, which reflected the sum of two pressure components, the passive pressure changes created by the pump and the active pressure changes due to breathing efforts. Over a range of pump frequencies, the amplitude of measured air sac pressure changes varied inversely with frequency. Above and below this range, pressure showed a beat pattern, indicating a difference in the frequencies of the two pressure components. Within the range lacking a beat pattern, breathing movements and the pump stroke had the same frequency. This range was greater at increased stroke volume. Breathing efforts worked with the pump at the high end of the range and against the pump at the low end. These findings show further evidence of the presence of a response to volume forcing and fit a previously described volume threshold model.     

Adaptation of respiratory muscle perfusion during exercise to chronically elevated ventilatory work.

Pneumonectomy (PNX) leads to chronic asymmetric ventilatory loading of respiratory muscles (RM). We measured RM energy requirements during exercise from RM blood flow (Q) using a fluorescent microsphere technique in dogs that had undergone right PNX as adults (adult R-PNX) or as puppies (puppy R-PNX), compared with dogs subjected to right thoracotomy without PNX as puppies (Sham) and to left PNX as adults (adult L-PNX). Ventilatory work (W) was measured during exercise. RM weight was determined post mortem. After adult and puppy R-PNX, the right hemidiaphragm becomes grossly distorted, but W and right costal muscle mass increased only after adult R-PNX. After adult L-PNX, the diaphragm was undistorted; W and left hemidiaphragm RM Q were elevated, but muscle mass did not increase. Mass of parasternal muscle did not increase after adult R-PNX, despite increased Q. Thus muscle mass increased only in response to the combination of chronic stretch and dynamic loading. There was a dorsal-to-ventral gradient of increasing Q within the diaphragm, but the distribution was unaffected by anatomic distortion, hypertrophy, or workload, suggesting a fixed pattern of neural activation. The diaphragm and parasternals were the primary muscles compensating for the asymmetric loading from PNX.     

Potentiation of hypoxic ventilatory response by hyperoxia in the conscious rat: putative role of nitric oxide

In humans, the hypoxic ventilatory response(HVR) is augmented when preceded by a short hyperoxic exposure (Y. Honda, H. Tani, A. Masuda, T. Kobayashi, T. Nishino, H. Kimura, S. Masuyama, and T. Kuriyama. J. Appl.Physiol. 81: 1627-1632, 1996). To examine whetherneuronal nitric oxide synthase (nNOS) is involved in such hyperoxia-induced HVR potentiation, 17 male Sprague-Dawley adult ratsunderwent hypoxic challenges (10%O₂-5%CO₂-balanceN₂) preceded either by 10 min ofroom air (O₂) or of 100%O₂(+O₂). At least 48 h later,similar challenges were performed after the animals received theselective nNOS inhibitor 7-nitroindazole (25 mg/kg ip). InO₂ runs, minute ventilation(E)increased from 121.3 ± 20.5 (SD) ml/min in room air to 191.7 ± 23.8 ml/min in hypoxia (P < 0.01). After +O₂,E increasedfrom 114.1 ± 19.8 ml/min in room air to 218.4 ± 47.0 ml/min inhypoxia (+O₂ vs.O₂:P < 0.005, ANOVA). After7-nitroindazole administration, HVR was not affected in theO₂ treatment group withE increasingfrom 113.7 ± 17.8 ml/min in room air to 185.8 ± 35.0 ml/min inhypoxia (P < 0.01).However, HVR potentiation in+O₂-exposed animals was abolished(111.8 ± 18.0 ml/min in room air to 184.1 ± 35.6 ml/min inhypoxia; +O₂ vs.O₂:P not significant). We conclude that in the conscious rat nNOS activation mediates essential components ofthe HVR potentiation elicited by a previous short hyperoxic exposure.

     

Aminophylline effects on ventilatory response to hypoxia and hyperoxia in normal adults

In 10 normal young adults, ventilation was evaluated with and without pretreatment with aminophylline, an adenosine blocker, while they breathed pure O2 1) after breathing room air and 2) after 25 min of isocapnic hypoxia (arterial O2 saturation 80%). With and without aminophylline, 5 min of hyperoxia significantly increased inspiratory minute ventilation (VI) from the normoxic base line. In control experiments, with hypoxia, VI initially increased and then declined to levels that were slightly above the normoxic base line. Pretreatment with aminophylline significantly attenuated the hypoxic ventilatory decline. During transitions to pure O2 (cessation of carotid bodies' output), VI and breathing patterns were analyzed breath by breath with a moving-average technique, searching for nadirs before and after hyperoxia. On placebo days, at the end of hypoxia, hyperoxia produced nadirs that were significantly lower than those observed with room-air breathing and also significantly lower than when hyperoxia followed normoxia, averaging, respectively, 6.41 +/- 0.52, 8.07 +/- 0.32, and 8.04 +/- 0.39 (SE) l/min. This hypoxic depression was due to significant decrease in tidal volume and prolongation of expiratory time. Aminophylline partly prevented these alterations in breathing pattern; significant posthypoxic ventilatory depression was not observed. We conclude that aminophylline attenuated hypoxic central depression of ventilation, although it does not affect hyperoxic steady-state hyperventilation. Adenosine may play a modulatory role in hypoxic but not in hyperoxic ventilation.