Development of ventilatory responsiveness to progressive hypoxia and hypercapnia in low-birth-weight lambs

Moss, T. J., M. G. Davey, G. J. McCrabb, and R. Harding.Development of ventilatory responsiveness to progressive hypoxia and hypercapnia in low-birth-weight lambs. J. Appl.Physiol. 81(4): 1555-1561, 1996.Our aim was todetermine the effects of low birth weight on ventilatory responses toprogressive hypoxia and hypercapnia during early postnatal life. Sevenlow-birth-weight (2.7 ± 0.3 kg) and five normal-birth-weight (4.8 ± 0.2 kg) lambs, all born at term, underwent weekly rebreathingtests during wakefulness while arterialPO₂,PCO₂, and pH were measured. Hypoxicventilatory responsiveness (HOVR; percent increase in ventilation whenarterial PO₂ fell to 60% of resting values) increased in normal lambs from 86.6 ± 7.1% atweek 1 to 227.4 ± 24.9% atweek 6. In low-birth-weight lambs,HOVR was not significantly different at week1 (60.1 ± 18.7%) from that of normal lambs but didnot increase with postnatal age (56.6 ± 19.3% atweek 6). HOVR of all lambs at 6 wkwas significantly correlated with birth weight(r² = 0.8).Hypercapnic ventilatory responsiveness (gradient of ventilation vs.arterial PCO₂) did not change withage and was not significantly different between groups [84.7 ± 7.5 (low-birth-weight lambs) vs. 89.4 ± 6.6 ml ^· min^{1 ·} kg^{1 ·} mmHg¹(normal lambs)]. We conclude that intrauterine conditions that impair fetal growth lead to the failure of HOVR to increase with age.

     

Arousal and ventilatory responses during sleep in children with obstructive sleep apnea

Abnormal centralregulation of upper airway muscles may contribute to thepathophysiology of the childhood obstructive sleep apnea syndrome(OSAS). We hypothesized that this was secondary to global abnormalitiesof ventilatory control during sleep. We therefore compared the responseto chemical stimuli during sleep between prepubertal children with OSASand controls. Patients with OSAS aroused at a higherPCO₂ (58 ± 2 vs. 60 ± 5 Torr,P < 0.05); those with the highestapnea index had the highest arousal threshold(r = 0.52, P < 0.05). The hypercapnic arousal threshold decreased after treatment. For all subjects, hypoxia was apoor stimulus to arousal, whereas hypercapnia and, particularly, hypoxic hypercapnia were potent stimuli to arousal. Hypercapnia resulted in decreased airway obstruction in OSAS. Ventilatory responseswere similar between patients with OSAS and controls; however, thesample size was small. We conclude that children with OSAS haveslightly blunted arousal responses to hypercapnia. However, the overallventilatory and arousal responses are normal in children with OSAS,indicating that a global deficit in respiratory drive is not a majorfactor in the etiology of childhood OSAS. Nevertheless, subtleabnormalities in ventilatory control may exist.

     

Cardiorespiratory responses to systemic administration of a protein kinase C inhibitor in conscious rats

Gozal, David, Gavin R. Graff, José E. Torres, SanjayG. Khicha, Gautam S. Nayak, Narong Simakajornboon, and Evelyne Gozal. Cardiorespiratory responses to systemic administration of aprotein kinase C inhibitor in conscious rats. J. Appl.Physiol. 84(2): 641-648, 1998.Although proteinkinase C (PKC) is an essential component of multiple neurally mediatedevents, its role in respiratory control remains undefined. Theventilatory effects of a systemically active PKC inhibitor (Ro-32-0432;100 mg/kg ip) were assessed by whole body plethysmography duringnormoxia, hypoxia (10% O₂), andhyperoxia (100% O₂) inunrestrained Sprague-Dawley rats. A sustained expiratory time increaseoccurred within 8-10 min of injection in room air[mean 44.8 ± 5.2 (SE) % ], was similarto expiratory time prolongations after Ro-32-0432 administration during100% O₂ (45.5 ± 8.1%; not significant), and was associated with mildminute ventilation (E) decreases.Hypercapnic ventilatory responses (5%CO₂) remained unchanged afterRo-32-0432. During 10% O₂,E increased from 122.6 ± 15.6 to 195.7 ± 10.1 ml/min in vehicle-treated rats(P < 0.001). In contrast, markedattenuation of E hypoxic responsesoccurred after Ro-32-0432 [86.2 ± 6.2 ml/min inroom air to 104.1 ± 7.1 ml/min in 10%O₂; pre- vs. post-Ro32-0432, P < 0.001 (analysis ofvariance)]. Overall, PKC activity was reduced and increases withhypoxia were abolished in the particulate subcellular fraction of brain tissue after Ro-32-0432 treatment, indicating thatthis compound readily crosses the blood-brain barrier. We conclude thatsystemic PKC inhibition elicits significant centrally mediatedexpiratory prolongations and ventilatory reductions as well as bluntedventilatory responses to hypoxia but not to hypercapnia. Wepostulate that PKC plays an important role in signal transduction pathways within brain regions underlying respiratory control.

     

Skeletal muscle chemoreflex and pHi in exercise ventilatory control

Oelberg, David A., Allison B. Evans, Mirko I. Hrovat, PaulP. Pappagianopoulos, Samuel Patz, and David M. Systrom. Skeletal muscle chemoreflex and pH_i inexercise ventilatory control. J. Appl.Physiol. 84(2): 676-682, 1998.To determinewhether skeletal muscle hydrogen ion mediates ventilatory drive inhumans during exercise, 12 healthy subjects performed three bouts ofisotonic submaximal quadriceps exercise on each of 2 days in a 1.5-Tmagnet for ³¹P-magnetic resonancespectroscopy(³¹P-MRS). Bilaterallower extremity positive pressure cuffs were inflated to 45 Torr duringexercise (BLPP_ex) or recovery(BLPP_rec) in a randomized orderto accentuate a muscle chemoreflex. Simultaneous measurements were madeof breath-by-breath expired gases and minute ventilation, arterializedvenous blood, and by ³¹P-MRS ofthe vastus medialis, acquired from the average of 12 radio-frequencypulses at a repetition time of 2.5 s. WithBLPP_ex, end-exercise minuteventilation was higher (53.3 ± 3.8 vs. 37.3 ± 2.2 l/min;P < 0.0001), arterializedPCO₂ lower (33 ± 1 vs. 36 ± 1 Torr; P = 0.0009), and quadricepsintracellular pH (pH_i) more acid (6.44 ± 0.07 vs. 6.62 ± 0.07; P = 0.004), compared withBLPP_rec. Bloodlactate was modestly increased withBLPP_ex but without a change inarterialized pH. For each subject, pH_i was linearly relatedto minute ventilation during exercise but not to arterialized pH. Thesedata suggest that skeletal muscle hydrogen ion contributes to theexercise ventilatory response.

     

Effects of changes in pH and CO2 on pulmonary arterial wall tension are not endothelium dependent

We examined thechanges in isolated pulmonary artery (PA) wall tension on switchingfrom control conditions (pH 7.38 ± 0.01, PCO₂ 32.9 ± 0.4 Torr) toisohydric hypercapnia (pH change 0.00 ± 0.01, PCO₂ change 24.9 ± 1.1 Torr) ornormocapnic acidosis (pH change 0.28 ± 0.01, PCO₂ change 0.3 ± 0.04 Torr) and the role of the endothelium in these responses. In rat PA, submaximally contracted with phenylephrine, isohydric hypercapnia did not cause a significant change in mean (± SE) tension [3.0 ± 1.8% maximal phenylephrine-induced tension(P_o)]. Endothelial removal did not alter this response. In aorticpreparations, isohydric hypercapnia caused significant(P < 0.01) relaxation (27.4 ± 3.2% P_o), which waslargely endothelium dependent. Normocapnic acidosis caused relaxationof PA (20.2 ± 2.6% P_o), which was less(P < 0.01) than that observed in aorticpreparations (35.7 ± 3.4%P_o). Endothelial removal leftthe pulmonary response unchanged while increasing(P < 0.01) the aortic relaxation(53.1 ± 4.4% P_o).These data show that isohydric hypercapnia does not alter PA tone.Reduction of PA tone in normocapnic acidosis is endothelium independentand substantially less than that of systemic vessels.

     

Cerebral vasomotor reactivity at high altitude in humans

The purpose of this study was twofold:1) to determine whether at highaltitude cerebral blood flow (CBF) as assessed during CO₂ inhalation and duringhyperventilation in subjects with acute mountain sickness (AMS) wasdifferent from that in subjects without AMS and2) to compare the CBF as assessedunder similar conditions in Sherpas at high altitude and in subjects atsea level. Resting control values of blood flow velocity in themiddle cerebral artery (V_MCA), pulseoxygen saturation (Sa_O2), andtranscutaneous PCO₂ were measured at4,243 m in 43 subjects without AMS, 17 subjects with AMS, 20 Sherpas,and 13 subjects at sea level. Responses ofCO₂ inhalation andhyperventilation onV_MCA,Sa_O2, and transcutaneous PCO₂ were measured, and the cerebralvasomotor reactivity (VMR = V_MCA/PCO₂)was calculated as the fractional change ofV_MCA per Torrchange of PCO₂, yielding ahypercapnic VMR and a hypocapnic VMR. AMS subjects showeda significantly higher resting controlV_MCA than didno-AMS subjects (74 ± 22 and 56 ± 14 cm/s, respectively;P < 0.001), andSa_O2 was significantly lower (80 ± 8 and 88 ± 3%, respectively; P < 0.001). Resting control V_MCA values inthe sea-level group (60 ± 15 cm/s), in the no-AMS group, and inSherpas (59 ± 13 cm/s) were not different. Hypercapnic VMR valuesin AMS subjects were 4.0 ± 4.4, in no-AMS subjects were 5.5 ± 4.3, in Sherpas were 5.6 ± 4.1, and in sea-level subjects were 5.6 ± 2.5 (not significant). Hypocapnic VMR values were significantly higher in AMS subjects (5.9 ± 1.5) compared with no-AMS subjects (4.8 ± 1.4; P < 0.005) but werenot significantly different between Sherpas (3.8 ± 1.1) and thesea-level group (2.8 ± 0.7). We conclude that AMS subjects havegreater cerebral hemodynamic responses to hyperventilation, higherV_MCAresting control values, and lower Sa_O2 compared with no-AMSsubjects. Sherpas showed a cerebral hemodynamic patternsimilar to that of normal subjects at sea level.     

Skeletal muscle ECF pH error signal for exercise ventilatory control

Evans, Allison B., Larry W. Tsai, David A. Oelberg, HomayounKazemi, and David M. Systrom. Skeletal muscle ECF pH error signalfor exercise ventilatory control. J. Appl.Physiol. 84(1): 90-96, 1998.An autonomic reflexlinking exercising skeletal muscle metabolism to central ventilatorycontrol is thought to be mediated by neural afferents having freeendings that terminate in the interstitial fluid of muscle. Todetermine whether changes in muscle extracellular fluid pH(pH_e) can provide an errorsignal for exercise ventilatory control,pH_e was measured duringelectrically induced contraction by³¹P-magnetic resonancespectroscopy and the chemical shift of a phosphorylated, pH-sensitivemarker that distributes to the extracellular fluid (phenylphosphonicacid). Seven lightly anesthetized rats underwentunilateral continuous 5-Hz sciatic nerve stimulation in an 8.45-Tnuclear magnetic resonance magnet, which resulted in a mixed lacticacidosis and respiratory alkalosis, with no net change in arterial pH.Skeletal muscle intracellular pH fell from 7.30 ± 0.03 units atrest to 6.72 ± 0.05 units at 2.4 min of stimulation and then roseto 7.05 ± 0.01 units (P < 0.05), despite ongoing stimulation and muscle contraction.Despite arterial hypocapnia, pH_eshowed an immediate drop from its resting baseline of 7.40 ± 0.01 to 7.16 ± 0.04 units (P < 0.05)and remained acidic throughout the stimulation protocol. During the on-and off-transients for 5-Hz stimulation, changes in the pH gradientbetween intracellular and extracellular compartments suggestedtime-dependent recruitment of sarcolemmal ion-transport mechanisms.pH_e of exercising skeletal musclemeets temporal and qualitative criteria necessary for a ventilatorymetaboreflex mediator in a setting where arterial pH doesnot.

     

Differential inspiratory timing is genetically linked to mouse chromosome 3

Genetic control ofdifferential inspiratory timing(TI) at baseline has beenpreviously demonstrated among inbred mouse strains. The inheritancepattern for TI between C3H/HeJ(C3; 188 ± 3 ms) and C57BL/6J (B6; 111 ± 2 ms) progenitors wasconsistent with a two-gene model. By using the strain distributionpattern for recombinant inbred strains derived from C3 and B6progenitors, 100% concordance was established betweenTI phenotypes and DNA markers onmouse chromosome 3. This genotype-phenotype hypothesis was tested bytyping 52 B6C3F₂(F₂) progeny by using simplesequence repeat DNA markers (n = 21)polymorphic between C3 and B6 strains on mouse chromosome 3. Linkageanalysis compared marker genotypes to baseline ventilatory phenotypesby computing log-likelihood values. A putative quantitative trait locuslocated in proximity to D3Mit119 wassignificantly associated with baselineTI phenotypes. At the peak(log-likelihood = 3.3), the putative quantitative trait locusdetermined 25% of the phenotypic variance inTI among F₂ progeny. In conclusion, thisgenetic model of ventilatory characteristics demonstrated an importantlinkage between differential baseline TI and a candidate genomicregion on mouse chromosome 3.

     

Ventilatory response to exercise in subjects breathing CO2 or HeO2

Babb, T. G. Ventilatory response to exercise insubjects breathing CO₂ orHeO₂.J. Appl. Physiol. 82(3): 746-754, 1997.To investigate the effects of mechanical ventilatory limitationon the ventilatory response to exercise, eight older subjects with normal lung function were studied. Each subject performed graded cycleergometry to exhaustion once while breathing room air; once whilebreathing 3% CO₂-21%O₂-balanceN₂; and once while breathing HeO₂ (79% He and 21%O₂). Minute ventilation(E) and respiratory mechanics weremeasured continuously during each 1-min increment in work rate (10 or20 W). Data were analyzed at rest, at ventilatory threshold (VTh),and at maximal exercise. When the subjects were breathing 3%CO₂, there was an increase(P < 0.001) inE at rest and at VTh but not duringmaximal exercise. When the subjects were breathingHeO₂,E was increased(P < 0.05) only during maximalexercise (24 ± 11%). The ventilatory response to exercise belowVTh was greater only when the subjects were breathing 3% CO₂(P < 0.05). Above VTh, theventilatory response when the subjects were breathingHeO₂ was greater than whenbreathing 3% CO₂(P < 0.01). Flow limitation, aspercent of tidal volume, during maximal exercise was greater(P < 0.01) when the subjects werebreathing CO₂ (22 ± 12%) thanwhen breathing room air (12 ± 9%) or when breathingHeO₂ (10 ± 7%)(n = 7). End-expiratory lung volumeduring maximal exercise was lower when the subjects were breathingHeO₂ than when breathing room airor when breathing CO₂(P < 0.01). These data indicate thatolder subjects have little reserve for accommodating an increase inventilatory demand and suggest that mechanical ventilatory constraintsinfluence both the magnitude of Eduring maximal exercise and the regulation ofE and respiratory mechanics duringheavy-to-maximal exercise.

     

Inhibition of nitric oxide synthase slows heart rate recovery from cholinergic activation

The role ofnitric oxide (NO) in the cholinergic regulation of heart rate(HR) recovery from an aspect of simulated exercise wasinvestigated in atria isolated from guinea pig to test the hypothesisthat NO may be involved in the cholinergic antagonism of the positivechronotropic response to adrenergic stimulation. Inhibition of NOsynthesis withN^G-monomethyl-L-arginine(L-NMMA, 100 µM) significantlyslowed the time course of the reduction in HR without affecting themagnitude of the response elicited by bath-applied ACh (100 nM) orvagal nerve stimulation (2 Hz). The half-times(t_1/2) of responses were 3.99 ± 0.41 s in control vs. 7.49 ± 0.68 s inL-NMMA(P < 0.05). This was dependent onprior adrenergic stimulation (norepinephrine, 1 µM). The effect ofL-NMMA was reversed byL-arginine (1 mM; t_1/2 4.62 ± 0.39 s). The calcium-channelantagonist nifedipine (0.2 µM) also slowed the kinetics of thereduction in HR caused by vagal nerve stimulation. However, thet_1/2 for the reduction in HR with antagonists (2 mM Cs⁺ and 1 µM ZD-7288) of thehyperpolarization-activated current were significantlyfaster compared with control. There was no additional effect ofL-NMMA orL-NMMA+L-arginineon vagal stimulation in groups treated with nifedipine,Cs⁺, or ZD-7288. Weconclude that NO contributes to the cholinergic antagonism of thepositive cardiac chronotropic effects of adrenergic stimulation byaccelerating the HR response to vagal stimulation. This may involve aninterplay between two pacemaking currents (L-type calcium channelcurrent and hyperpolarization-activated current). Whether NO modulatesthe vagal control of HR recovery from actual exercise remains to bedetermined.

     

Ventilatory stability to transient CO2 disturbances in hyperoxia and normoxia in awake humans

Lai, Jie, and Eugene N. Bruce. Ventilatory stability totransient CO₂ disturbances inhyperoxia and normoxia in awake humans. J. Appl.Physiol. 83(2): 466-476, 1997.Modarreszadeh andBruce (J. Appl. Physiol. 76:2765-2775, 1994) proposed that continuous random disturbances inarterial PCO₂ are more likely toelicit ventilatory oscillation patterns that mimic periodic breathingin normoxia than in hyperoxia. To test this hypothesis experimentally,in nine awake humans we applied pseudorandom binary inspiredCO₂ fraction stimulation innormoxia and hyperoxia to derive the closed-loop and open-loopventilatory responses to a briefCO₂ disturbance in terms ofimpulse responses and transfer functions. The closed-loop impulseresponse has a significantly higher peak value [0.143 ± 0.071 vs. 0.079 ± 0.034 (SD)l · min¹ · 0.01 lCO₂¹,P = 0.014] and a significantlyshorter 50% response duration (42.7 ± 13.3 vs. 72.3 ± 27.6 s,P = 0.020) in normoxia than in hyperoxia. Therefore, the ventilatory responses to transientCO₂ disturbances are less damped(but generally not oscillatory) in normoxia than in hyperoxia. For theclosed-loop transfer function, the gain in normoxia increasedsignificantly (P < 0.0005), while phase delay decreased significantly (P < 0.0005). The gain increased by 108.5, 186.0, and 240.6%, whilephase delay decreased by 26.0, 18.1, and 17.3%, at 0.01, 0.03, and0.05 Hz, respectively. Changes in the same direction were found for theopen-loop system. Generally, an oscillatory ventilatory response to asmall transient CO₂ disturbance isunlikely during wakefulness. However, changes in parameters that leadto additional increases in chemoreflex loop gain are more likely toinitiate oscillations in normoxia than in hyperoxia.

     

Effect of chest wall vibration on breathlessness in normal subjects

This study evaluated the effect of chest wall vibration (115 Hz) on breathlessness. Breathlessness was induced in normal subjects by a combination of hypercapnia and an inspiratory resistive load; both minute ventilation and end-tidal CO2 were kept constant. Cross-modality matching was used to rate breathlessness. Ratings during intercostal vibration were expressed as a percentage of ratings during the control condition (either deltoid vibration or no vibration). To evaluate their potential contribution to any changes in breathlessness, we assessed several aspects of ventilation, including chest wall configuration, functional residual capacity (FRC), and the ventilatory response to steady-state hypercapnia. Intercostal vibration reduced breathlessness ratings by 6.5 +/- 5.7% compared with deltoid vibration (P less than 0.05) and by 7.0 +/- 8.3% compared with no vibration (P less than 0.05). The reduction in breathlessness was accompanied by either no change or negligible change in minute ventilation, tidal volume, frequency, duty cycle, compartmental ventilation, FRC, and the steady-state hypercapnic response. We conclude that chest wall vibration reduces breathlessness and speculate that it may do so through stimulation of receptors in the chest wall.     

Hypercapnic blood pressure response is greater during the luteal phase of the menstrual cycle

Edwards, N., I. Wilcox, O. J. Polo, and C. E. Sullivan.Hypercapnic blood pressure response is greater during the luteal phase of the menstrual cycle. J. Appl.Physiol. 81(5): 2142-2146, 1996.We investigatedthe cardiovascular responses to acute hypercapnia during the menstrualcycle. Eleven female subjects with regular menstrual cycles performedhypercapnic rebreathing tests during the follicular and luteal phasesof their menstrual cycles. Ventilatory and cardiovascular variableswere recorded breath by breath. Serum progesterone and estradiol weremeasured on each occasion. Serum progesterone was higher during theluteal [50.4 ± 9.6 (SE) nmol/l] than during thefollicular phase (2.1 ± 0.7 nmol/l;P < 0.001), but serum estradiol didnot differ (follicular phase, 324 ± 101 pmol/l; luteal phase, 162 ± 71 pmol/l; P = 0.61). Thesystolic blood pressure responses during hypercapnia were 2.0 ± 0.3 and 4.0 ± 0.5 mmHg/Torr (1 Torr = 1 mmHg rise inend-tidal PCO₂) during the follicularand luteal phases, respectively, of the menstrual cycle(P < 0.01). The diastolic bloodpressure responses were 1.1 ± 0.2 and 2.1 ± 0.3 mmHg/Torrduring the follicular and luteal phases, respectively(P < 0.002). Heart rate responses did not differ during the luteal (1.7 ± 0.3 beats ^· min^{1 ·} Torr¹)and follicular phases (1.4 ± 0.3 beats ^· min^{1 ·} Torr¹;P = 0.59). These data demonstrate agreater pressor response during the luteal phase of the menstrual cyclethat may be related to higher serum progesterone concentrations.

     

Effect of chronic resistive loading on hypoxic ventilatory responsiveness

Greenberg, Harly E., Rammohan S. Rao, Anthony L. Sica, andSteven M. Scharf. Effect of chronic resistive loading on hypoxicventilatory responsiveness. J. Appl.Physiol. 82(2): 500-507, 1997.Depression ofventilation mediated by endogenous opioids has been observed acutelyafter resistive airway loading. We evaluated the effects of chronicallyincreased airway resistance on hypoxic ventilatory responsivenessshortly after load imposition and 6 wk later. A circumferentialtracheal band was placed in 200-g rats, tripling tracheal resistance.Sham surgery was performed in controls. Ventilation and the ventilatoryresponse to hypoxia were measured by using barometric plethysmographyat 2 days and 6 wk postsurgery in unanesthetized rats during exposureto room air and to 12% O₂-5%CO₂-balanceN₂. Trials were performed with andwithout naloxone (1 mg/kg ip). Room air arterial blood gases demonstrated hypercapnia with normoxia in obstructed rats at 2 days and6 wk postsurgery. During hypoxia, a 30-Torr fall inPO₂ occurred with no change inPCO₂. Hypoxic ventilatory responsiveness was suppressed in obstructed rats at 2 days postloading. Naloxone partially reversed this suppression. However, hypoxic responsiveness at 6 wk was not different from control levels. Naloxonehad a small effect on ventilatory pattern at this time with no overalleffect on hypoxic responsiveness. This was in contrast to previouslydemonstrated long-term suppression ofCO₂ sensitivity in this model,which was partially reversible by naloxone only during the immediateperiod after load imposition. Endogenous opioids apparently modulateventilatory control acutely after load imposition. Their effect waneswith time despite persistence of depressedCO₂ sensitivity.

     

Effect of ingested sodium bicarbonate on muscle force, fatigue, and recovery

Verbitsky, O., J. Mizrahi, M. Levin, and E. Isakov.Effect of ingested sodium bicarbonate on muscle force, fatigue, and recovery. J. Appl. Physiol. 83(2):333-337, 1997.The influence of acute ingestion ofNaHCO₃ on fatigue and recovery ofthe quadriceps femoris muscle after exercise was studied in six healthymale subjects. A bicycle ergometer was used for exercising under three loading conditions: test A, loadcorresponding to maximal oxygen consumption; testB, load in test A + 17%; test C, load intest B but performed 1 h after acuteingestion of NaHCO₃.Functional electrical stimulation (FES) was applied to provokeisometric contraction of the quadriceps femoris. The resulting kneetorque was monitored during fatigue (2-min chronic FES) and recovery (10-s FES every 10 min, for 40 min). Quadriceps torques were higher inthe presence of NaHCO₃(P < 0.05): withNaHCO₃ the peak, residual, andrecovery (after 40 min) normalized torques were, respectively, 0.68 ± 0.05 (SD), 0.58 ± 0.05, and 0.73 ± 0.05; withoutNaHCO₃ the values were 0.45 ± 0.04, 0.30 ± 0.06, and 0.63 ± 0.06. The increasedtorques obtained after acute ingestion ofNaHCO₃ indicate the possibleexistence of improved nonoxidative glycolysis in isometric contraction,resulting in reduced fatigue and enhanced recovery.

     

Task failure with lack of diaphragm fatigue during inspiratory resistive loading in human subjects

McKenzie, D. K., G. M. Allen, J. E. Butler, and S. C. Gandevia. Task failure with lack of diaphragm fatigue during inspiratory resistive loading in human subjects. J. Appl. Physiol. 82(6): 2011-2019, 1997.Taskfailure during inspiratory resistive loading is thought to beaccompanied by substantial peripheral fatigue of the inspiratorymuscles. Six healthy subjects performed eight resistive breathingtrials with loads of 35, 50, 75 and 90% of maximal inspiratorypressure (MIP) with and without supplemental oxygen. MIP measuredbefore, after, and at every minute during the trial increased slightlyduring the trials, even when corrected for lung volume (e.g., for 24 trials breathing air, 12.5% increase, P < 0.05). In some trials, taskfailure occurred before 20 min (end point of trial), and in thesetrials there was an increase in end-tidalPCO₂(P < 0.01), despite the absence of peripheral muscle fatigue. In four subjects (6 trials with task failure), there was no decline in twitch amplitude with bilateral phrenic stimulation or in voluntary activation of the diaphragm, eventhough end-tidal PCO₂ rose by 1.6 ± 0.9%. These results suggest that hypoventilation,CO₂ retention, and ultimate taskfailure during resistive breathing are not simply dependent on impairedforce-generating capacity of the diaphragm or impaired voluntaryactivation of the diaphragm.

     

Changes in respiratory control during and after 48h of isocapnic and poikilocapnic hypoxia in humans

Ventilatory acclimatization tohypoxia is associated with an increase in ventilation under conditionsof acute hyperoxia(E_hyperoxia) and an increase in acute hypoxic ventilatory response (AHVR). Thisstudy compares 48-h exposures to isocapnic hypoxia( protocol I) with 48-hexposures to poikilocapnic hypoxia ( protocolP) in 10 subjects to assess the importance ofhypocapnic alkalosis in generating the changes observed in ventilatoryacclimatization to hypoxia. During both hypoxic exposures,end-tidal PO₂ was maintained at60 Torr, with end-tidal PCO₂ held at the subject's prehypoxic level( protocol I) or uncontrolled( protocol P).E_hyperoxiaand AHVR were assessed regularly throughout the exposures.E_hyperoxia(P < 0.001, ANOVA) and AHVR(P < 0.001) increased during thehypoxic exposures, with no significant differences betweenprotocols I andP. The increase inE_hyperoxiawas associated with an increase in slope of theventilation-end-tidal PCO₂ response(P < 0.001) with no significantchange in intercept. These results suggest that changes in respiratorycontrol early in ventilatory acclimatization to hypoxiaresult from the effects of hypoxia per se and not the alkalosisnormally accompanying hypoxia.

     

Effects of N2O narcosis on breathing and effort sensations during exercise and inspiratory resistive loading

Fothergill, D. M., and N. A. Carlson. Effects ofN₂O narcosis on breathing andeffort sensations during exercise and inspiratory resistive loading.J. Appl. Physiol. 81(4):1562-1571, 1996.The influence of nitrous oxide(N₂O) narcosis on the responses toexercise and inspiratory resistive loading was studied in thirteen maleUS Navy divers. Each diver performed an incremental bicycle exercisetest at 1 ATA to volitional exhaustion while breathing a 23%N₂O gas mixture and a nonnarcoticgas of the same PO₂, density, andviscosity. The same gas mixtures were used during four subsequent30-min steady-state submaximal exercise trials in which the subjectsbreathed the mixtures both with and without an inspiratory resistance(5.5 vs. 1.1 cmH₂O ^· s ^· l¹at 1 l/s). Throughout each test, subjective ratings of respiratory effort (RE), leg exertion, and narcosis were obtained with acategory-ratio scale. The level of narcosis was rated between slightand moderate for the N₂O mixturebut showed great individual variation. Perceived leg exertion and thetime to exhaustion were not significantly different with the twobreathing mixtures. Heart rate was unaffected by the gas mixture andinspiratory resistance at rest and during steady-state exercise but wassignificantly lower with the N₂O mixture during incremental exercise (P < 0.05). Despite significant increases in inspiratory occlusionpressure (13%; P < 0.05),esophageal pressure (12%; P < 0.001), expired minute ventilation (4%;P < 0.01), and the work rate ofbreathing (15%; P < 0.001) when the subjects breathed the N₂O mixture,RE during both steady-state and incremental exercise was 25% lowerwith the narcotic gas than with the nonnarcotic mixture(P < 0.05). We conclude that the narcotic-mediated changes in ventilation, heart rate, and RE induced by23% N₂O are not of sufficientmagnitude to influence exercise tolerance at surface pressure.Furthermore, the load-compensating respiratory reflexes responsible formaintaining ventilation during resistive breathing are not depressed byN₂O narcosis.

     

The Hering-Breuer reflex in anesthetized infants: end-inspiratory vs. end-expiratory occlusion technique

Bothend-inspiratory (EIO) and end-expiratory (EEO) occlusions have beenused to measure the strength of the Hering-Breuer inflation reflex(HBIR) in infants. The purpose of this study was to compare bothtechniques in anesthetized infants. In each infant, HBIR activity wascalculated as the relative prolongation of expiratory and inspiratorytime during EIO and EEO, respectively. Respiratory drive was assessedfrom the change in airway pressure during inspiratory effort againstthe occlusion, both at a fixed time interval of 100 ms(P_0.1) and a fixed proportion(10%) of the occluded inspiratory time(P_10%). Twenty-two infants [age 14.3 ± 6.4 (SD) mo] were studied. No HBIR activitywas present during EIO [11.8 ± 15.9 (SD) %]. Bycontrast, there was significant, albeit weak, reflex activity duringEEO [HBIR: 27.2 ± 17.4%]. A strong HBIR (up to 310%)was elicited in six of seven infants in whom EIO was repeated afterlung inflation. P_0.1 was similar during both types of occlusions, whereas mean ± SDP_10% was lower during EEO thanduring EIO: 0.198 ± 0.09 vs. 0.367 ± 0.15 kPa, respectively(P < 0.01). These data suggest adifference in the central integration of stretch receptor activity ininfants during anesthesia compared with during sleep.

     

Alae nasi activation decreases nasal resistance during hyperoxic hypercapnia

It has beenproposed that decreases in nasal resistance (Rn) during hypercapnia areentirely due to vasoconstriction in the nasal cavity. We hypothesizedthat alae nasi (AN) muscle activity dilates the nasal vestibule andcontributes to the decrease in Rn during hypercapnia. Nine normalsubjects were studied during hyperoxic hypercapnia (HH). Rn andvestibular resistance (Rvest) for one nasal passage were measuredsimultaneously with the AN electromyogram before and after nasaldecongestion. HH decreased Rvest from 1.6 ± 0.6 to 0.8 ± 0.9 cmH₂O · l¹ · s(predecongestant) and from 1.3 ± 0.8 to 0.6 ± 0.7 cmH₂O · l¹ · s(postdecongestant; both P < 0.01).Nasal decongestant decreased Rn but not Rvest. Significant inverselinear relationships between Rvest and AN electromyogram weredemonstrated for all subjects. We conclude that in normal subjectsduring HH 1) decreases in Rvest arepredominantly due to increases in AN activity; and2) decreases in Rn are due to acombination of mucosal vasoconstriction and ANactivation.