Heat acclimation, aerobic fitness, and hydration effects on tolerance during uncompensable heat stress

The purpose ofthe present study was to determine the separate and combined effects ofaerobic fitness, short-term heat acclimation, and hypohydration ontolerance during light exercise while wearing nuclear, biological, andchemical protective clothing in the heat (40°C, 30% relativehumidity). Men who were moderately fit [(MF); <50ml · kg¹ · min¹maximal O₂ consumption;n = 7] and highly fit[(HF); >55ml · kg¹ · min¹maximal O₂ consumption;n = 8] were tested while theywere euhydrated or hypohydrated by ~2.5% of body mass throughexercise and fluid restriction the day preceding the trials. Tests wereconducted before and after 2 wk of daily heat acclimation (1-htreadmill exercise at 40°C, 30% relative humidity, while wearingthe nuclear, biological, and chemical protective clothing). Heatacclimation increased sweat rate and decreased skin temperature andrectal temperature (T_re) in HF subjects but had no effecton tolerance time (TT). MF subjects increased sweat rate but did notalter heart rate, Tre, or TT. In both MF and HF groups, hypohydration significantly increased T_re and heart rate and decreasedthe respiratory exchange ratio and the TT regardless of acclimationstate. Overall, the rate of rise of skin temperature was less, whileT_re, the rate of rise of T_re, and the TTwere greater in HF than in MF subjects. It was concluded thatexercise-heat tolerance in this uncompensable heat-stress environmentis not influenced by short-term heat acclimation but is significantlyimproved by long-term aerobic fitness.

     

Letters to the Editor

The following is the abstract of the article discussed in thesubsequent letter:

Koga, Shunsaku, Tomoyuki Shiojiri, Narihiko Kondo,and Thomas J. Barstow. Effect of increased muscle temperature on oxygen uptake kinetics during exercise. J. Appl. Physiol.83(4): 1333-1338, 1997.To test whether increased muscletemperature (T_m) would improve O₂ uptake(O₂) kinetics, seven menperformed transitions from rest to a moderate work rate [below theestimated lactate threshold (LT_est)] and a heavy workrate (O₂ = 50% of thedifference between LT_est and peakO₂) under conditions of normal T_m (N) and increased T_m (H), produced bywearing hot water-perfused pants before exercise. QuadricepsT_m was significantly higher in H, but rectal temperaturewas similar for the two conditions. There were no significantdifferences in the amplitudes of the fast component ofO₂ or in the time constantsof the on and off transients for moderate and heavy exercise betweenthe two conditions. The increment inO₂ between the 3rd and 6thmin of heavy exercise was slightly but significantly smaller for H thanfor N. These data suggest that elevated T_m before exercise onset, which would have been expected to increase O₂delivery and off-loading to the muscle, had no appreciable effect onthe fast exponential component ofO₂ kinetics (invariant timeconstant). These data further suggest that elevated T_m doesnot contribute to the slow component ofO₂ during heavy exercise.

     

VO2 kinetics in the horse during moderate and heavy exercise

Langsetmo, I., G. E. Weigle, M. R. Fedde, H. H. Erickson, T. J. Barstow, and D. C. Poole.O₂ kinetics in thehorse during moderate and heavy exercise. J. Appl.Physiol. 83(4): 1235-1241, 1997.The horse is asuperb athlete, achieving a maximalO₂ uptake (~160ml · min¹ · kg¹)approaching twice that of the fittest humans. Although equine O₂ uptake(O₂) kinetics arereportedly fast, they have not been precisely characterized, nor hastheir exercise intensity dependence been elucidated. To addressthese issues, adult male horses underwent incremental treadmill testingto determine their lactate threshold (T_lac) and peakO₂(O_{2 peak}),and kinetic features of their O₂ response to"square-wave" work forcings were resolved using exercisetransitions from 3 m/s to abelow-T_lac speed of 7 m/s or anabove-T_lac speed of 12.3 ± 0.7 m/s (i.e., between T_lac and O_{2 peak}) sustainedfor 6 min. O₂ andCO₂ output were measured using anopen-flow system: pulmonary artery temperature was monitored, and mixedvenous blood was sampled for plasma lactate.O₂ kinetics at work levelsbelow T_lac were well fit by atwo-phase exponential model, with a phase2 time constant(₁ = 10.0 ± 0.9 s) thatfollowed a time delay (TD₁ = 18.9 ± 1.9 s). TD₁ was similar tothat found in humans performing leg cycling exercise, but the timeconstant was substantially faster. For speeds aboveT_lac,TD₁ was unchanged (20.3 ± 1.2 s); however, the phase 2 time constantwas significantly slower (₁ = 20.7 ± 3.4 s, P < 0.05) than for exercise belowT_lac. Furthermore, in four of fivehorses, a secondary, delayed increase inO₂ became evident135.7 ± 28.5 s after the exercise transition. This "slowcomponent" accounted for ~12% (5.8 ± 2.7 l/min) of the netincrease in exercise O₂. Weconclude that, at exercise intensities below and aboveT_lac, qualitative features ofO₂ kinetics in the horseare similar to those in humans. However, at speeds belowT_lac the fast component of theresponse is more rapid than that reported for humans, likely reflectingdifferent energetics of O₂utilization within equine muscle fibers.

     

Gas exchange and cardiovascular kinetics with different exercise protocols in heart transplant recipients

Grassi, Bruno, Claudio Marconi, Michael Meyer, Michel Rieu,and Paolo Cerretelli. Gas exchange and cardiovascular kinetics with different exercise protocols in heart transplant recipients. J. Appl. Physiol. 82(6): 1952-1962, 1997.Metabolicand cardiovascular adjustments to various submaximal exercises wereevaluated in 82 heart transplant recipients (HTR) and in 35 controlsubjects (C). HTR were tested 21.5 ± 25.3 (SD) mo (range1.0-137.1 mo) posttransplantation. Three protocols were used:protocol A consisted of 5 min of rectangular 50-W load repeatedtwice, 5 min apart [5 min rest, 5 min 50 W (Ex 1), 5 minrecovery, 5 min 50 W (Ex 2)]; protocol B consistedof 5 min of rectangular load at 25, 50, or 75 W; protocol Cconsisted of 15 min of rectangular load at 25 W. Breath-by-breathpulmonary ventilation (E),O₂ uptake (O₂),and CO₂ output(CO₂) were determined.During protocol A, beat-by-beat cardiacoutput () was estimated by impedance cardiography. The half times (t_1/2) of the on- andoff-kinetics of the variables were calculated. In all protocols,t_1/2 values forO₂ on-,E on-, andCO₂ on-kinetics were higher(i.e., the kinetics were slower) in HTR than in C, independently ofworkload and of the time posttransplantation. Also,t_1/2 on- was higher in HTRthan in C. In protocol A, no significant difference of t_1/2 O₂on- was observed in HTR between Ex 1 (48 ± 9 s) and Ex2 (46 ± 8 s), whereas t_1/2 on- was higher during Ex 1 (55 ± 24 s)than during Ex 2 (47 ± 15 s). In all protocols and for all variables, the t_1/2 off-values were higher in HTRthan in C. In protocol C, no differences of steady-stateE,O₂, andCO₂ were observed in bothgroups between 5, 10, and 15 min of exercise. We conclude that1) in HTR, a "priming" exercise, while effective inspeeding up the adjustment of convective O₂ flow to muscle fibers during a second on-transition, did not affect theO₂ on-kinetics, suggestingthat the slower O₂ on- inHTR was attributable to peripheral (muscular) factors; 2) thedissociation between on- andO₂ on-kinetics in HTRindicates that an inertia of muscle metabolic machinery is the mainfactor dictating theO₂ on-kinetics; and 3) theO₂ off-kinetics was slowerin HTR than in C, indicating a greater alactic O₂ deficitin HTR and, therefore, a sluggish muscleO₂ adjustment.

     

Effect of increased muscle temperature on oxygen uptake kinetics during exercise

Koga, Shunsaku, Tomoyuki Shiojiri, Narihiko Kondo,and Thomas J. Barstow. Effect of increased muscle temperature on oxygen uptake kinetics during exercise. J. Appl.Physiol. 83(4): 1333-1338, 1997.To test whetherincreased muscle temperature (T_m) would improveO₂ uptake(O₂) kinetics, seven menperformed transitions from rest to a moderate work rate [belowthe estimated lactate threshold(LT_est)] and a heavy workrate (O₂ = 50% of thedifference between LT_est and peakO₂) under conditions of normal T_m (N) and increasedT_m (H), produced by wearing hotwater-perfused pants before exercise. QuadricepsT_m was significantly higher in H,but rectal temperature was similar for the two conditions. There wereno significant differences in the amplitudes of the fast component ofO₂ or in the time constantsof the on and off transients for moderate and heavy exercise betweenthe two conditions. The increment inO₂ between the 3rd and 6thmin of heavy exercise was slightly but significantly smaller for H thanfor N. These data suggest that elevatedT_m before exercise onset, whichwould have been expected to increaseO₂ delivery and off-loading to themuscle, had no appreciable effect on the fast exponential component ofO₂ kinetics (invariant timeconstant). These data further suggest that elevatedT_m does not contribute to the slowcomponent of O₂ duringheavy exercise.

     

Effects of respiratory muscle work on cardiac output and its distribution during maximal exercise

We have recently demonstrated that changes inthe work of breathing during maximal exercise affect leg blood flow andleg vascular conductance (C. A. Harms, M. A. Babcock, S. R. McClaran, D. F. Pegelow, G. A. Nickele, W. B. Nelson, and J. A. Dempsey. J. Appl. Physiol. 82: 1573-1583,1997). Our present study examined the effects of changesin the work of breathing on cardiac output (CO) during maximalexercise. Eight male cyclists [maximalO₂ consumption(O_{2 max}):62 ± 5 ml · kg¹ · min¹]performed repeated 2.5-min bouts of cycle exercise atO_{2 max}. Inspiratorymuscle work was either 1) at controllevels [inspiratory esophageal pressure (Pes): 27.8 ± 0.6 cmH₂O],2) reduced via a proportional-assistventilator (Pes: 16.3 ± 0.5 cmH₂O), or 3) increased via resistive loads(Pes: 35.6 ± 0.8 cmH₂O).O₂ contents measured in arterialand mixed venous blood were used to calculate CO via the direct Fickmethod. Stroke volume, CO, and pulmonaryO₂ consumption(O₂) were not different(P > 0.05) between control andloaded trials atO_{2 max} but were lower(8, 9, and 7%, respectively) than control withinspiratory muscle unloading atO_{2 max}. Thearterial-mixed venous O₂difference was unchanged with unloading or loading. We combined thesefindings with our recent study to show that the respiratory muscle work normally expended during maximal exercise has two significant effectson the cardiovascular system: 1) upto 14-16% of the CO is directed to the respiratory muscles; and2) local reflex vasoconstriction significantly compromises blood flow to leg locomotor muscles.

     

Muscle capillarization, O2 diffusion distance, and VO2 kinetics in old and young individuals

Chilibeck, P. D., D. H. Paterson, D. A. Cunningham, A. W. Taylor, and E. G. Noble. Muscle capillarization,O₂ diffusion distance, andO₂ kinetics in old andyoung individuals. J. Appl. Physiol.82(1): 63-69, 1997.The relationships between muscle capillarization, estimated O₂diffusion distance from capillary to mitochondria, andO₂ uptake(O₂) kineticswere studied in 11 young (mean age, 25.9 yr) and 9 old (mean age, 66.0 yr) adults. O₂kinetics were determined by calculating the time constants () forthe phase 2 O₂ adjustment to andrecovery from the average of 12 repeats of a 6-min, moderate-intensityplantar flexion exercise. Muscle capillarization was determined fromcross sections of biopsy material taken from lateral gastrocnemius.Young and old groups had similarO₂ kinetics(O₂-on = 44 vs. 48 s;O₂-off = 33 vs. 44 s, for young and old, respectively), muscle capillarization, andestimated O₂ diffusion distances.Muscle capillarization, expressed as capillary density or averagenumber of capillary contacts per fiber/average fiber area, and theestimates of diffusion distance were significantly correlated toO₂-off kinetics in theyoung (r = 0.68 to 0.83;P < 0.05). We conclude that1) capillarization andO₂ kinetics during exerciseof a muscle group accustomed to everyday activity (e.g., walking) arewell maintained in old individuals, and2) in the young, recovery of O₂ after exercise isfaster, with a greater capillary supply over a given muscle fiber areaor shorter O₂ diffusion distances.

     

Ventilatory response to exercise in diabetic subjects with autonomic neuropathy

Tantucci, C., P. Bottini, M. L. Dottorini, E. Puxeddu, G. Casucci, L. Scionti, and C. A. Sorbini. Ventilatory response toexercise in diabetic subjects with autonomic neuropathy.J. Appl. Physiol. 81(5):1978-1986, 1996.We have used diabetic autonomic neuropathy as amodel of chronic pulmonary denervation to study the ventilatoryresponse to incremental exercise in 20 diabetic subjects, 10 with(Dan+) and 10 without (Dan) autonomic dysfunction, and in 10 normal control subjects. Although both Dan+ and Dan subjectsachieved lower O₂ consumption andCO₂ production(CO₂) thancontrol subjects at peak of exercise, they attained similar values ofeither minute ventilation(E) oradjusted ventilation (E/maximalvoluntary ventilation). The increment of respiratory rate withincreasing adjusted ventilation was much higher in Dan+ than inDan and control subjects (P < 0.05). The slope of the linearE/CO₂relationship was 0.032 ± 0.002, 0.027 ± 0.001 (P < 0.05), and 0.025 ± 0.001 (P < 0.001) ml/min inDan+, Dan, and control subjects, respectively. Bothneuromuscular and ventilatory outputs in relation to increasingCO₂ were progressivelyhigher in Dan+ than in Dan and control subjects. At peak ofexercise, end-tidal PCO₂ was muchlower in Dan+ (35.9 ± 1.6 Torr) than in Dan (42.1 ± 1.7 Torr; P < 0.02) and control (42.1 ± 0.9 Torr; P < 0.005) subjects.We conclude that pulmonary autonomic denervation affects ventilatoryresponse to stressful exercise by excessively increasing respiratoryrate and alveolar ventilation. Reduced neural inhibitory modulationfrom sympathetic pulmonary afferents and/or increasedchemosensitivity may be responsible for the higher inspiratoryoutput.

     

Acceleration of VO2 kinetics in heavy submaximal exercise by hyperoxia and prior high-intensity exercise

MacDonald, Maureen, Preben K. Pedersen, and Richard L. Hughson. Acceleration ofO₂ kinetics in heavysubmaximal exercise by hyperoxia and prior high-intensity exercise.J. Appl. Physiol. 83(4):1318-1325, 1997.We examined the hypothesis thatO₂ uptake (O₂) wouldchange more rapidly at the onset of step work rate transitions inexercise with hyperoxic gas breathing and after prior high-intensityexercise. The kinetics ofO₂ were determined from themean response time (MRT; time to 63% of total change inO₂) andcalculations of O₂ deficit andslow component during normoxic and hyperoxic gas breathing in one groupof seven subjects during exercise below and above ventilatory threshold(VT) and in another group of seven subjects during exercise above VTwith and without prior high-intensity exercise. In exercise transitions below VT, hyperoxic gas breathing did not affect the kinetic response of O₂ at theonset or end of exercise. At work rates above VT, hyperoxic gasbreathing accelerated both the on- and off-transient MRT, reduced theO₂ deficit, and decreased theO₂ slow component fromminute 3 to minute6 of exercise, compared with normoxia. Prior exerciseabove VT accelerated the on-transient MRT and reduced theO₂ slow component fromminute 3 to minute6 of exercise in a second bout of exercise with bothnormoxic and hyperoxic gas breathing. However, the summatedO₂ deficit in the second normoxicand hyperoxic steps was not different from that of the first steps inthe same gas condition. Faster on-transient responses in exerciseabove, but not below, VT with hyperoxia and, to a lesser degree, afterprior high-intensity exercise above VT support the theory of anO₂ transport limitation at theonset of exercise for workloads >VT.

     

Effects of training duration on substrate turnover and oxidation during exercise

Phillips, S. M., H. J. Green, M. A. Tarnopolsky, G. J. F. Heigenhauser, R. E. Hill, and S. M. Grant. Effects of training duration on substrate turnover and oxidation during exercise. J. Appl. Physiol. 81(5):2182-2191, 1996.Adaptations in fat and carbohydrate metabolismafter a prolonged endurance training program were examined using stableisotope tracers of glucose([6,6-²H₂]glucose),glycerol([²H₅]glycerol),and palmitate([²H₂]palmitate).Active, but untrained, males exercised on a cycle for 2 h/day[60% pretraining peak O₂consumption (O_{2 peak}) = 44.3 ± 2.4 ml ^· kg^{1 ·} min¹]for a total of 31 days. Three cycle tests (90 min at 60% pretraining O_{2 peak}) wereadministered before training (PRE) and after 5 (5D) and 31 (31D) daysof training. Exercise increased the rate of glucose production(R_a) and utilization(R_d) as well as the rate oflipolysis (glycerol R_a) and freefatty acid turnover (FFA R_a/R_d).At 5D, training induced a 10% (P < 0.05) increase in total fat oxidation because of an increase inintramuscular triglyceride oxidation (+63%,P < 0.05) and a decreased glycogenoxidation (16%, P < 0.05).At 31D, total fat oxidation during exercise increased a further 58%(P < 0.01). The pattern of fatutilization during exercise at 31D showed a reduced reliance on plasmaFFA oxidation (FFA R_d) and agreater dependence on oxidation of intramuscular triglyceride, whichincreased more than twofold (P < 0.001). In addition, glucose R_aand R_d were reduced at all timepoints during exercise at 31D compared with PRE and 5D. We concludethat long-term training induces a progressive increase in fatutilization mediated by a greater oxidation of fats from intramuscularsources and a reduction in glucose oxidation. Initial changes arepresent as early as 5D and occur before increases in muscle maximalmitochondrial enzyme activity [S. M. Phillips, H. J. Green, M. A. Tarnopolsky, G. J. F. Heigenhauser, and S. M. Grant.Am. J. Physiol. 270 (Endocrinol. Metab. 33):E265-E272, 1996].

     

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.

     

Estimating exercise stroke volume from asymptotic oxygen pulse in humans

Whipp, Brian J., Michael B. Higgenbotham, and Frederick C. Cobb. Estimating exercise stroke volume from asymptotic oxygenpulse in humans. J. Appl. Physiol.81(6): 2674-2679, 1996.Noninvasive techniques have been devisedto estimate cardiac output () during exercise toobviate vascular cannulation. However, although these techniques arenoninvasive, they are commonly not nonintrusive to subjects'spontaneous ventilation and gas-exchange responses. We hypothesizedthat the exercise stroke volume (SV) and, hence, might be accurately estimated simply from the response pattern of twostandardly determined variables:O₂ uptake(O₂) and heart rate (HR).Central to the theory is the demonstration that the product of and mixed venousO₂ content is virtually constant (k) during steady-state exercise. Thus from the Fickequation, O₂ =  ^· Ca_CO2  k, whereCa_CO2 is the arterialCO₂ content, theO₂ pulse(O₂-P) equalsSV ^· Ca_CO2  (k/HR). Because the arterial O₂ content(Ca_O2) is usually relatively constant innormal subjects during exercise,O₂-P should change hyperbolicallywith HR, asymptoting atSV ^· Ca_O2. Inaddition, because the asymptoticO₂-P equals the slope (S) of thelinear O₂-HR relationship,exercise SV may be predicted as S/Ca_O2.We tested this prediction in 23 normal subjects who underwent a 3-minincremental cycle-ergometer test with direct determination ofCa_O2 and mixed venous O₂content from indwelling catheters. The predicted SV closely reflected the measured value (r = 0.80). Wetherefore conclude that, in normal subjects, exercise SV may beestimated simply as five times S of the linearO₂-HRrelationship (where 5 is approximately 1/Ca_O2).

     

Influence of muscle fiber type and pedal frequency on oxygen uptake kinetics of heavy exercise

Barstow, Thomas J., Andrew M. Jones, Paul H. Nguyen, andRichard Casaburi. Influence of muscle fiber type and pedal frequency on oxygen uptake kinetics of heavy exercise.J. Appl. Physiol. 81(4):1642-1650, 1996.We tested the hypothesis that the amplitude ofthe additional slow component ofO₂ uptake(O₂) during heavy exerciseis correlated with the percentage of type II (fast-twitch) fibers inthe contracting muscles. Ten subjects performed transitions to a workrate calculated to require aO₂ equal to 50% betweenthe estimated lactate (Lac) threshold and maximalO₂ (50%).Nine subjects consented to a muscle biopsy of the vastus lateralis. Toenhance the influence of differences in fiber type among subjects,transitions were made while subjects were pedaling at 45, 60, 75, and90 rpm in different trials. Baseline O₂ was designed to besimilar at the different pedal rates by adjusting baseline work ratewhile the absolute increase in work rate above the baseline was thesame. The O₂ response after the onset of exercise was described by a three-exponential model. Therelative magnitude of the slow component at the end of 8-min exercisewas significantly negatively correlated with %type I fibers at everypedal rate (r = 0.64 to 0.83, P < 0.05-0.01). Furthermore,the gain of the fast component forO₂ (asml ^· min^{1 ·} W¹)was positively correlated with the %type I fibers across pedal rates(r = 0.69-0.83). Increase inpedal rate was associated with decreased relative stress of theexercise but did not affect the relationships between%fiber type and O₂parameters. The relative contribution of the slow component was alsosignificantly negatively correlated with maximalO₂(r = 0.65), whereas the gainfor the fast component was positively associated(r = 0.68-0.71 across rpm). Theamplitude of the slow component was significantly correlated with netend-exercise Lac at all four pedal rates(r = 0.64-0.84), but Lac was notcorrelated with %type I (P > 0.05).We conclude that fiber type distribution significantly affects both thefast and slow components ofO₂ during heavy exerciseand that fiber type and fitness may have both codependent andindependent influences on the metabolic and gas-exchange responses toheavy exercise.

     

Cardiac output estimated noninvasively from oxygen uptake during exercise

Stringer, William W., James E. Hansen, and K. Wasserman.Cardiac output estimated noninvasively from oxygen uptake duringexercise. J. Appl. Physiol. 82(3):908-912, 1997.Because gas-exchange measurements duringcardiopulmonary exercise testing allow noninvasive measurement ofoxygen uptake (O₂), whichis equal to cardiac output (CO) × arteriovenous oxygencontent difference [C(a-vD_O2)],CO and stroke volume could theoretically be estimated if theC(a-vD_O2)increased in a predictable fashion as a function of %maximumO₂(O_{2 max}) duringexercise. To investigate the behavior ofC(a-vD_O2)during progressively increasing ramp pattern cycle ergometry exercise,5 healthy subjects performed 10 studies to exhaustion while arterialand mixed venous blood were sampled. Samples were analyzed forblood gases (pH, PCO₂,PO₂) and oxyhemoglobin and hemoglobinconcentration with a CO-oximeter. TheC(a-vD_O2)(ml/100 ml) could be estimated with a linear regression [C(a-vD_O2) = 5.72 + 0.105 × %O_{2 max};r = 0.94]. The CO estimated fromthe C(a-vD_O2)by using the above linear regression was well correlated withthe CO determined by the direct Fick method(r = 0.96). The coefficient ofvariation of the estimated CO was small (7-9%) between the lacticacidosis threshold and peakO₂. The behaviorof C(a-vD_O2),as related to peakO₂, was similar regardless of cardiac function compared with similar measurements fromstudies in the literature performed in normal and congestive heartfailure patients. In summary, CO and stroke volume can be estimatedduring progressive work rate exercise testing from measured O₂ (in normal subjects andpatients with congestive heart failure), and the resultant linearregression equation provides a good estimate ofC(a-vD_O2).

     

Dehydration markedly impairs cardiovascular function in hyperthermic endurance athletes during exercise

González-Alonso, José, RicardoMora-Rodríguez, Paul R. Below, and Edward F. Coyle.Dehydration markedly impairs cardiovascular function inhyperthermic endurance athletes during exercise. J. Appl. Physiol. 82(4): 1229-1236, 1997.Weidentified the cardiovascular stress encountered by superimposingdehydration on hyperthermia during exercise in the heat and themechanisms contributing to the dehydration-mediated stroke volume (SV)reduction. Fifteen endurance-trained cyclists [maximalO₂ consumption(O_{2 max}) = 4.5 l/min] exercised in the heat for 100-120 min and either became dehydrated by 4% body weight or remained euhydrated by drinkingfluids. Measurements were made after they continued exercise at 71%O_{2 max} for 30 minwhile 1) euhydrated with anesophageal temperature (T_es) of38.1-38.3°C (control); 2)euhydrated and hyperthermic (39.3°C);3) dehydrated and hyperthermic withskin temperature (T_sk) of34°C; 4) dehydrated withT_es of 38.1°C and T_sk of 21°C; and5) condition4 followed by restored blood volume. Compared withcontrol, hyperthermia (1°C T_esincrease) and dehydration (4% body weight loss) each separatelylowered SV 7-8% (11 ± 3 ml/beat;P < 0.05) and increased heart ratesufficiently to prevent significant declines in cardiac output.However, when dehydration was superimposed on hyperthermia, thereductions in SV were significantly (P < 0.05) greater (26 ± 3 ml/beat), and cardiac output declined 13% (2.8 ± 0.3 l/min). Furthermore, mean arterialpressure declined 5 ± 2%, and systemic vascular resistanceincreased 10 ± 3% (both P < 0.05). When hyperthermia wasprevented, all of the decline in SV with dehydration was due to reducedblood volume (~200 ml). These results demonstrate that thesuperimposition of dehydration on hyperthermia during exercise in theheat causes an inability to maintain cardiac output and blood pressurethat makes the dehydrated athlete less able to cope with hyperthermia.

     

Human ventilatory response to 8h of euoxic hypercapnia

Tansley, John G., Michala E. F. Pedersen, Christine Clar,and Peter A. Robbins. Human ventilatory response to 8 h of euoxic hypercapnia. J. Appl.Physiol. 84(2): 431-434, 1998.Ventilation (E) risesthroughout 40 min of constant elevated end-tidalPCO₂ without reaching steady state(S. Khamnei and P. A. Robbins. Respir. Physiol. 81: 117-134, 1990). The present studyinvestigates 8 h of euoxic hypercapnia to determine whetherE reachessteady state within this time. Two protocols were employed:1) 8-h euoxic hypercapnia (end-tidalPCO₂ = 6.5 Torr above prestudy value,end-tidal PO₂ = 100 Torr) followed by 8-h poikilocapnic euoxia; and2) control, where the inspired gaswas air. Ewas measured over a 5-min period before the experiment and then hourly over a 16-h period. In the hypercapnia protocol,E had notreached a steady state by the first hour(P < 0.001, analysis of variance), but there were no further significant differences inEover hours 2-8 (analysis ofvariance). Efell promptly on return to eucapnic conditions. We conclude that,whereas there is a component of theE responseto hypercapnia that is slow, there is no progressive rise inE throughoutthe 8-h period.

     

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.

     

Ventilatory and metabolic responses to ambient hypoxia or hypercapnia in rats exposed to CO hypoxia

Gautier, Henry, Cristina Murariu, and Monique Bonora.Ventilatory and metabolic responses to ambient hypoxia orhypercapnia in rats exposed to CO hypoxia. J. Appl. Physiol.83(1): 253-261, 1997.We have investigated at ambienttemperatures (T_am) of 25 and5°C the effects of ambient hypoxia(Hx_am; fractional inspired O₂ = 0.14) and hypercapnia(fractional inspiredCO₂ = 0.04) on ventilation (),O₂ uptake(O₂), andcolonic temperature (T_c) in 12 conscious rats before and after carotid body denervation (CBD). Therats were concomitantly exposed to CO hypoxia (Hx_CO; fractional inspired CO = 0.03-0.05%), which decreases arterial O₂ saturation by ~25-40%.The results demonstrate the following. 1) AtT_am of 5°C, in both intact andCBD rats,/O₂ islarger when Hx_am orCO₂ is associated withHx_CO than with normoxia. At T_am of 25°C, this is also thecase except for CO₂ in CBD rats. 2) AtT_am of 5°C, the changes inO₂ andT_c seem to result from additiveeffects of the separate changes induced byHx_am,CO₂, andHx_CO. It is concluded that, inconscious rats, central hypoxia does not depress respiratory activity.On the contrary, particularly whenO₂ is augmented during acold stress, both/O₂during Hx_CO and the ventilatoryresponses to Hx_am andCO₂ are increased. The mechanismsinvolved in this relative hyperventilation are likely to involvediencephalic integrative structures.

     

Association of chest wall motion and tidal volume responses during CO2 rebreathing

Yan, Sheng, Pawel Sliwinski, and Peter T. Macklem.Association of chest wall motion and tidal volume responses during CO₂ rebreathing.J. Appl. Physiol. 81(4):1528-1534, 1996.The purpose of this study is to investigate theeffect of chest wall configuration at end expiration on tidal volume(VT) response duringCO₂ rebreathing. In a group of 11 healthy male subjects, the changes in end-expiratory andend-inspiratory volume of the rib cage (Vrc,E andVrc,I, respectively) and abdomen (Vab,E and Vab,I, respectively) measured by linearizedmagnetometers were expressed as a function of end-tidalPCO₂(PET_CO2). The changes inend-expiratory and end-inspiratory volumes of the chest wall(Vcw,E and Vcw,I,respectively) were calculated as the sum of the respectiverib cage and abdominal volumes. The magnetometer coils were placed atthe level of the nipples and 1-2 cm above the umbilicus andcalibrated during quiet breathing against theVT measured from apneumotachograph. TheVrc,E/PET_CO2 slope was quite variable among subjects. It was significantly positive (P < 0.05) in fivesubjects, significantly negative in four subjects(P < 0.05), and not different fromzero in the remaining two subjects. TheVab,E/PET_CO2slope was significantly negative in all subjects(P < 0.05) with a much smallerintersubject variation, probably suggesting a relatively more uniformrecruitment of abdominal expiratory muscles and a variable recruitmentof rib cage muscles during CO₂rebreathing in different subjects. As a group, the meanVrc,E/PET_CO2,Vab,E/PET_CO2, andVcw,E/PET_CO2slopes were 0.010 ± 0.034, 0.030 ± 0.007, and0.020 ± 0.032 l / Torr, respectively;only theVab,E/PET_CO2 slope was significantly different from zero. More interestingly, theindividualVT/PET_CO2slope was negatively associated with theVrc,E/PET_CO2(r = 0.68,P = 0.021) and Vcw,E/PET_CO2slopes (r = 0.63,P = 0.037) but was not associated withtheVab,E/PET_CO2slope (r = 0.40, P = 0.223). There was no correlation oftheVrc,E/PET_CO2 andVcw,E/PET_CO2slopes with age, body size, forced expiratory volume in 1 s, orexpiratory time. The groupVab,I/PET_CO2 slope (0.004 ± 0.014 l / Torr) was not significantlydifferent from zero despite theVT nearly being tripled at theend of CO₂ rebreathing. Inconclusion, the individual VTresponse to CO₂, althoughindependent of Vab,E, is a function ofVrc,E to the extent that as theVrc,E/PET_CO2slope increases (more positive) among subjects, theVT response toCO₂ decreases. These results maybe explained on the basis of the respiratory muscle actions andinteractions on the rib cage.

     

Smaller lungs in women affect exercise hyperpnea

We subjected 29 healthy young women (age: 27 ± 1 yr) with a wide range of fitness levels [maximal oxygenuptake (O_{2 max}): 57 ± 6 ml · kg¹ · min¹;35-70ml · kg¹ · min¹]to a progressive treadmill running test. Our subjects had significantly smaller lung volumes and lower maximal expiratory flow rates, irrespective of fitness level, compared with predicted values for age-and height-matched men. The higher maximal workload in highly fit(O_{2 max} > 57 ml · kg¹ · min¹,n = 14) vs. less-fit(O_{2 max} < 56 ml · kg¹ · min¹,n = 15) women caused a higher maximalventilation (E) with increased tidal volume (VT)and breathing frequency (f_b) atcomparable maximal VT/vitalcapacity (VC). More expiratory flow limitation (EFL; 22 ± 4% ofVT) was also observed duringheavy exercise in highly fit vs. less-fit women, causing higherend-expiratory and end-inspiratory lung volumes and greater usage oftheir maximum available ventilatory reserves.HeO₂ (79% He-21%O₂) vs. room air exercise trialswere compared (with screens added to equalize external apparatusresistance). HeO₂ increasedmaximal expiratory flow rates (20-38%) throughout the range ofVC, which significantly reduced EFL during heavy exercise. When EFL wasreduced with HeO₂, VT,f_b, andE (+16 ± 2 l/min) weresignificantly increased during maximal exercise. However, in theabsence of EFL (during room air exercise),HeO₂ had no effect onE. We conclude that smaller lungvolumes and maximal flow rates for women in general, and especiallyhighly fit women, caused increased prevalence of EFL during heavyexercise, a relative hyperinflation, an increased reliance onf_b, and a greater encroachment onthe ventilatory "reserve." Consequently,VT andE are mechanically constrained duringmaximal exercise in many fit women because the demand for highexpiratory flow rates encroaches on the airways' maximum flow-volumeenvelope.