Variations in exercise ventilation in hypoxia will affect oxygen uptake

Reports of VO2 response differences between normoxia and hypoxia during incremental exercise do not agree. In this study VO2 and VE were obtained from 15-s averages at identical work rates during continuous incremental cycle exercise in 8 subjects under ambient pressure (633 mmHg ≈1,600 m) and during duplicate tests in acute hypobaric hypoxia (455 mmHg ≈4,350 m), ranging from 49 to 100% of VO2 peak in hypoxia and 42-87% of VO2 peak in normoxia. The average VO2 was 96 mL/min (619 mL) lower at 455 mmHg (n.s. P = 0.15) during ramp exercises. Individual response points were better described by polynomial than linear equations (mL/min/W). The VE was greater in hypoxia, with marked individual variation in the differences which correlated significantly and directly with the VO2 difference between 455 mmHg and 633 mmHg (P = 0.002), likely related to work of breathing (Wb). The greater VE at 455 mmHg resulted from a greater breathing frequency. When a subject's hypoxic ventilatory response is high, the extra work of breathing reduces mechanical efficiency (E). Mean ∆E calculated from individual linear slopes was 27.7 and 30.3% at 633 and 455 mmHg, respectively (n.s.). Gross efficiency (GE) calculated from mean VO2 and work rate and correcting for Wb from a VE-VO2 relationship reported previously, gave corresponding values of 20.6 and 21.8 (P = 0.05). Individual variation in VE among individuals overshadows average trends, as also apparent from other reports comparing hypoxia and normoxia during progressive exercise and must be considered in such studies.

VESTPD as a measure of ventilatory acclimatization to hypobaric hypoxia

This study compared the ventilation response to an incremental ergometer exercise at two altitudes: 633 mmHg (resident altitude = 1,600 m) and following acute decompression to 455 mmHg (≈4,350 m altitude) in eight male cyclists and runners. At 455 mmHg, the V_ESTPD at RER <1.0 was significantly lower and the V_EBTPS was higher because of higher breathing frequency; at VO₂max, both V_ESTPD and V_EBTPS were not significantly different. As percent of VO₂max, the V_EBTPS was nearly identical and V_ESTPD was 30% lower throughout the exercise at 455 mmHg. The lower V_ESTPD at lower pressure differs from two classical studies of acclimatized subjects (Silver Hut and OEII), where V_ESTPD at submaximal workloads was maintained or increased above that at sea level. The lower V_ESTPD at 455 mmHg in unacclimatized subjects at submaximal workloads results from acute respiratory alkalosis due to the initial fall in HbO₂ (≈0.17 pHa units), reduction in PACO₂ (≈5 mmHg) and higher PAO₂ throughout the exercise, which are partially pre-established during acclimatization. Regression equations from these studies predict V_ESTPD from VO₂ and P_B in unacclimatized and acclimatized subjects. The attainment of ventilatory acclimatization to altitude can be estimated from the measured vs. predicted difference in V_ESTPD at low workloads after arrival at altitude.

Plasma volume after heat acclimation: Variations due to season, fitness and methods of measurement

PURPOSE

The reported magnitude of plasma volume increase (Δ%PV) following heat acclimation (HA) varies widely. Variations may result from differences in measurement techniques, season and subjects' fitness. This report compares direct and indirect measurements of Δ%PV after 10 days of HA from studies in winter (WIN, n = 8) and summer (SUM, n = 10) in men, age 21-43 yr, at two fitness levels (VO(2)max: 35 and 51 ml/min/kg). Direct measurements were made before and after HA (cycling at 30% of VO(2)max at 50 °C, for 100 min/day) by carbon monoxide (CO) rebreathing and compared with indirect estimates from changes in hematocrit, hemoglobin and plasma protein concentration.

RESULTS

Overall, Δ%PV by CO was small (2.9%) and greater in SUM than WIN (5.0 vs. 0.3%). Red cell, blood and plasma volumes/kg lean body mass increased in SUM and decreased in WIN, the difference being significant, and Δ%PV by CO was similar for high and low VO(2)max.

CONCLUSION

Overall, indirect estimates of Δ%PV by hemoglobin and hematocrit were similar to CO, but tended to differentiate by fitness and not season. The difference in THb increase in SUM and decrease in WIN was significant. This probably accounts for the differences from the seasonal and fitness results by the direct CO method.

The effect of 10 days of heat acclimation on exercise performance in acute hypobaric hypoxia (4350 m)

To examine the effect (“cross-tolerance”) of heat acclimation (HA) on exercise performance upon exposure to acute hypobaric hypoxia (4350 m). Eight male cyclists residing at 1600 m performed tests of maximal aerobic capacity (VO_2max) at 1600 m and 4350 m, a 16 km time-trial at 4350 m, and a heat tolerance test at 1600 m before and after 10 d HA at 40°C, 20% RH. Resting blood samples were obtained pre-and post- HA to estimate changes in plasma volume (ΔPV). Successful HA was indicated by significantly lower exercise heart rate and rectal temperature on day 10 vs. day 1 of HA and during the heat tolerance tests. Heat acclimation caused a 1.9% ΔPV, however VO_2max was not significantly different at 1600 m or 4350 m. Time-trial cycling performance improved 28 sec after HA (p = 0.07), suggesting a possible benefit for exercise performance at acute altitude and that cross-tolerance between these variables may exist in humans. These findings do not clearly support the use of HA to improve exercise capacity and performance upon acute hypobaric hypoxia, however they do indicate that HA is not detrimental to either exercise capacity or performance.

A stair-climbing test for measuring mechanical efficiency of ambulation in adults with chronic stroke

PURPOSE

Mechanical efficiency can assess motor performance in individuals with physical disabilities. The purpose was to determine the utility of predicting it from heart rate (HR) during a self-paced stair-climbing test in adults with chronic hemiparesis after stroke and to determine the minimal detectable change of net mechanical efficiency (MEnet) measured by this exercise.

METHODS

First, 15 subjects with chronic hemiparesis participated in a validation study (A) and then 28 took part in a repeatability study (B). In study A the MEnet was calculated from external work and oxygen uptake above rest (dVO2), as directly measured and as predicted from body weight and increase in heart rate (dHR). In study B, predicted dVO2 was used to obtain MEnet for duplicate stair-climbing tests (T1, T2) with >30 min rest between.

RESULTS

Measured MEnet was closely related to predicted MEnet (r = 0.97, p < 0.001). In study B predicted MEnet for T2 and T1 were closely related (r = 0.91, ICC = 0.90).

CONCLUSION

With a minimal detectable change of 0.6% (0.053 of average MEnet score of 10.4%), MEnet values from the stair-climbing test seem sufficiently meaningful to estimate ambulatory ability and its changes with interventions or walking aids in adults with hemiparesis.

IMPLICATIONS FOR REHABILITATION

Ambulatory ability can be estimated from mechanical efficiency, obtained from a 5-min stair-climbing test utilizing a 4-step stair, to measure external work, and the change in heart rate above rest to estimate the metabolic cost of the task. A change of > 0.6% in mechanical efficiency by this stair-climbing test indicates a significant change in ambulatory ability of persons with hemiparesis.

Ventilatory response to high inspired carbon dioxide concentrations in anesthetized dogs

Background:

The ventilation ( ) response to inspired CO₂ has been extensively studied, but rarely with concentrations >10%.

Aims:

These experiments were performed to determine whether would increase correspondingly to higher concentrations and according to conventional chemoreceptor time delays.

Materials and Methods:

We exposed anesthetized dogs acutely, with and without vagotomy and electrical stimulation of the right vagus, to 20-100% CO₂-balance O₂ and to 0 and 10% O₂-balance N₂.

Results:

The time delays decreased and response magnitude increased with increasing concentrations (p<0.01), but at higher concentrations the time delays were shorter than expected, i.e., 0.5 s to double at 100% CO₂, with the response to 0% O₂ being ~3 s slower. Right vagotomy significantly reduced baseline breathing frequency (fR), increased tidal volume (VT) and increased the time delay by ~3 s. Bilateral vagotomy further reduced baseline fR and , and reduced the response to CO₂ and increased the time delay by ~12 s. Electro-stimulation of the peripheral right vagus while inspiring CO₂ caused a 13 s asystole and further reduced and delayed the response, especially after bilateral vagotomy, shifting the mode from VT to fR.

Conclusions:

Results indicate that airway or lung receptors responded to the rapid increase in lung H⁺ and that vagal afferents and unimpaired circulation seem necessary for the initial rapid response to high CO₂ concentrations by receptors upstream from the aortic bodies.

Teaching fluid shifts during orthostasis using a classic paper by Foux et al

Hypovolemic and orthostatic challenge can be simulated in humans by the application of lower body negative pressure (LBNP), because this perturbation leads to peripheral blood pooling and, consequently, central hypovolemia. The classic paper by Foux and colleagues clearly shows the effects of orthostasis simulated by LBNP on fluid shifts and homeostatic mechanisms. The carefully carried out experiments reported in this paper show the interplay between different physiological control systems to ensure blood pressure regulation, failure of which could lead to critical decreases in cerebral blood flow and syncope. Here, a teaching seminar for graduate students is described that is designed in the context of this paper and aimed at allowing students to learn how Foux and colleagues have advanced this field by addressing important aspects of blood regulation. This seminar is also designed to put their research into perspective by including important components of LBNP testing and protocols developed in subsequent research in the field. Learning about comprehensive protocols and carefully controlled studies can reduce confounding variables and allow for an optimal analysis and elucidation of the physiological responses that are being investigated. Finally, in collaboration with researchers in mathematical modeling, in the future, we will incorporate the concepts of applicable mathematical models into our curriculum.

Volume regulating hormone responses to repeated head-up tilt and lower body negative pressure

BACKGROUND

We hypothesized the existence of different hormonal response patterns to repeated lower body negative pressure (LBNP) and head-up tilt (HUT) in healthy males. We compared hormonal, cardiovascular and plasma volume changes from rest to stress within- and between-LBNP and HUT applications. Hormones investigated included adrenocorticotropic hormone (ACTH), aldosterone, plasma renin activity (PRA), atrial natriuretic peptide (ANP) and arginine vasopressin (AVP).

MATERIALS AND METHODS

Three sequential 30-min bouts of LBNP at -55mmHg (n=14) or 70° HUT (n=9) were preceded by 30-min supine rest, and a 60-min supine rest followed the 3rd stimulus.

RESULTS

Plasma renin activity increases above baseline, in relation to aldosterone, were larger with LBNP than with HUT. The 3rd HUT application resulted in a greater increase in aldosterone compared to LBNP. Mean arterial blood pressure was elevated significantly during 1st and 3rd HUT application. ACTH responses were highly correlated with those of aldosterone in both LBNP and HUT (r(2) =0·96). AVP responses, in contrast to ANP, to the three consecutive stress situations were not significantly different, both with LBNP and HUT.

CONCLUSIONS

We speculate that the observed differences in blood pressure and hormonal responses to LBNP and HUT are caused by divergent effects of blood pooling in the splanchnic region, despite similar reductions in splanchnic perfusion. Apparently with repeated central hypovolaemia, especially by the 3rd application of stress, plasma aldosterone levels rise (along with ACTH), conceivably increasing its volume-guarding effect.

A forgotten moment in physiology: the Lovelace Woman in Space Program (1960-1962)

In 1959, Brigadier General Donald Flickinger and Dr. W. Randolph Lovelace II suggested that it would be more practical from an engineering standpoint to send women rather than men into space due to their lower body weights and oxygen requirements. When the Air Force decided not to pursue this project, Dr. Lovelace assumed leadership of the Woman in Space Program and began medical and physiological testing of a series of accomplished women aviators at the Lovelace Medical Clinic in Albuquerque, NM, in 1960. The tests that these women underwent were identical to those used to test the original Mercury astronauts, with the addition of gynecological examinations. Thirteen of the nineteen women tested passed these strenuous physiological exams (for comparison, 18 of 32 men tested passed); a subset of these pilots was further tested on a series of psychological exams that were similar to or, in some instances, more demanding than those given to male Mercury candidates. Despite these promising results, further testing was halted, and the Woman in Space Program was disbanded in 1962. Although the Woman in Space Program received a great deal of publicity at the time, the story of these women was somewhat lost until they were reunited at the 1999 launch of the shuttle Columbia, commanded by Colonel Eileen Collins.

Hypoxemia and acute mountain sickness: which comes first?

Hypoxemia is usually associated with acute mountain sickness (AMS), but most studies have varied in time and magnitude of altitude exposure, exercise, diet, environmental conditions, and severity of pulmonary edema. We wished to determine whether hypoxemia occurred early in subjects who developed subsequent AMS while resting at a simulated altitude of 426 mmHg (approximately 16,000 ft or 4880 m). Exposures of 51 men and women were carried out for 8 to 12 h. AMS was determined by Lake Louise (LL) and AMS-C scores near the end of exposure, with spirometry and gas exchange measured the day before (C) and after 1 (A1), 6 (A6), and last (A12) h at simulated altitude and arterial blood at C, A1, and A12. Responses of 16 subjects having the lowest AMS scores (nonAMS: mean LL=1.0, range=0-2.5) were compared with the 16 having the highest scores (+AMS: mean LL=7.4, range=5-11). Total and alveolar ventilation responses to altitude were not different between groups. +AMS had significantly lower PaO2 (4.6 mmHg) and SaO2 (4.8%) at A1 and 3.3 mmHg and 3.1% at A12. Spirometry changes were similar at A1, but at A6 and A12 reduced vital capacity (VC) and increased breathing frequency suggested interstitial pulmonary edema in +AMS. The early hypoxemia in +AMS appears to be the result of diffusion impairment or venous admixture, perhaps due to a unique autonomic response affecting pulmonary perfusion. Early hypoxemia may be useful to predict AMS susceptibility.

Effects of acute leg ischemia during cycling on oxygen and carbon dioxide stores

This study estimated changes in whole body oxygen stores (O(2)s) and carbon dioxide stores (CO(2)s) during steady state exercise with leg ischemia induced by leg cuff inflation. Six physically fit subjects performed 75 W steady state exercise for 15 min on a cycle ergometer. After 5 min of exercise, cuffs on the upper and lower legs were inflated to 140 mmHg. Cuffs were deflated after 5 min and exercise continued for another 5 min. O(2 )uptake (VO(2)) and CO(2) output (VCO(2)) significantly increased during the first 30 s after inflation, significantly decreased between 60 and 90 s, and then rose linearly until deflation. VO(2) and VCO(2) significantly increased further after cuff deflation, peaking between 30 and 60 s and then returned to near baseline exercise levels. Model-estimated changes in total O(2)s and CO(2)s were compared with time-integrated store changes from VO(2) and VCO(2). During 5 min after cuff deflation, VO(2) and VCO(2) exceeded the model-estimated change in stores by 273 and 697 mL, respectively. These results reflect the O(2) cost repayment of the anaerobic component and lactate buffering to neutralize circulating metabolites caused by the preceding ischemia.

Repeatability of net mechanical efficiency during stair climbing in children with cerebral palsy

PURPOSE

To determine the smallest significant change in mechanical efficiency (MEnet) measured by a stair-climbing test.

METHODS

Duplicate stair-climbing tests (T1 and T2), with more than a 30-minute rest between, were performed by 51 children with diplegic cerebral palsy (CP) at levels II and III of Gross Motor Function Classification System (GMFCS) and 9 children with typical development, aged 5.5 to 13.0 years.

RESULTS

The T2 versus T1 slope values of MEnet for CP and typical development did not significantly differ from 1.00. MEnet was significantly higher for GMFCS level II (7.0%) than level III (1.2%). The mean percentage of difference was 7.8% (T2 > T1) for the children with CP, with a 95% confidence interval of -39% to +54%. The 95% confidence interval for MEnet scores computed from the standard error of the mean (SEM) of the percentage of differences was 4.0 to 4.5 for CP.

CONCLUSIONS

An increase of >13.4% in MEnet score (eg, mean increase from 4.0% to 4.5%) can indicate improved motor status resulting from interventions.

Prediction of mechanical efficiency from heart rate during stair-climbing in children with cerebral palsy

Measuring mechanical efficiency (ME) is potentially useful to assess motor performance in individuals with physical disabilities. The purpose of this study was to determine the accuracy of predicting ME from heart rate (HR) during a self-paced stair-climbing test in children with a range of motor abilities. The participants were 12 normally developed children (ND) and 24 with cerebral palsy (CP), ranging in age from 5 to 15 years (mean: 8 years). Five were at level II, 11 at level III and 8 at level IV according to the gross motor function classification system. ME was calculated as the ratio of external work to O(2) uptake (VO(2) ml/min) measured or predicted from HR. The absolute values of VO(2) and HR during stair-climbing were not significantly correlated. However, the correlation between values above resting (dVO(2) and dHR) was significant (r=0.61). Furthermore, when including body weight as a second variable the prediction of dVO(2) was significantly improved (r=0.85). This resulted in a high correlation (r=0.96) between measured and predicted net ME (ME(net)). Predicted ME(net) for 25 stair-climbing tests repeated after an average of 6 months resulted in an r-value of 0.92 with predicted ME(net) of the first test. This study demonstrates that ME(net) during stair-climbing can be predicted in children with a broad range of motor abilities from dHR and may be a simple tool to help define developmental stages or evaluating intervention efficacy.

Effects of acute hypobaric hypoxia on resting and postprandial superior mesenteric artery blood flow

Reduced blood flow to the gut may contribute to weight loss and gastrointestinal symptoms of acute mountain sickness (AMS) at altitude. A study in humans tested the hypothesis that acute hypobaric hypoxia (ALT) would attenuate the normal postprandial hyperemia in the superior mesenteric artery (SM). Blood pressure, cardiac output (CO), and (SM) were measured with previously validated noninvasive Doppler ultrasonic flowmetry in 9 (3 women) healthy young adults (mean age: 23; range: 18-33 yr) residing at 1700 m. Baseline measurements were made after 2 h at ALT in a chamber at 430 mmHg (asymptotically equal to 4800 m = 15,750 ft) after 10-12-h fasting, and the next day the control (CON) measurements were made at 615 mmHg (1850 m). Postprandial measurements were made 45 to 60 min after ingesting a 1000-cal liquid meal under both conditions. At ALT, 5 of the 9 subjects had AMS by the Lake Louise score criteria of headache > or =1 and total score > or =3. ALT significantly reduced fasting, baseline SM relative to CON by 15%, and increased CO by 16%. The postprandial CO increase was not different between ALT and CON, but (SM) increased 115% at CON, but only 75% at ALT, the attenuation being significant (p < 0.006). Neither the diminution of fasting (SM) at ALT nor the attenuation of the postprandial increase in (SM) correlated significantly with AMS symptom scores. These results suggest that baseline and postprandial gut blood flow are altered during acute altitude exposure because of increased intestinal sympathetic tone, inferred from increased local resistance, and may be related to reduced energy intake if sustained during prolonged exposure.

CO2 rebreathing model in COPD: blood-to-gas equilibration

Rebreathing in a closed system can be used to estimate mixed venous PCO2 (PvCO2) and cardiac output, but these estimates are affected by VA/Q heterogeneity. The purpose of this study was to validate a mathematical model of CO2 exchange during CO2 rebreathing in 29 patients with chronic obstructive pulmonary disease (COPD), with baseline arterial PCO2 (PaCO2) ranging from 28 to 60 mmHg. Rebreathing increased end-tidal PCO2 (PETCO2) by 20 mmHg over 2.2 min. This model employed baseline values for inspired (bag) PCO2, estimated PvCO2, distribution of ventilation and blood flow in one high VA/Q and one low VA/Q compartment, the ventilation increase and conservation of mass equations to simulate time courses of PICO2, PETCO2, PvCO2, and PaCO2. Measured PICO2 and PETCO2 during rebreathing differed by an average (SEM) of 1.4 (0.4) mmHg from simulated values. By end of rebreathing, predicted PvCO2 was lower than measured and predicted PaCO2, indicating gas to blood CO2 flux. Estimates of the ventilatory response to CO2, quantified as the slope (S) of the ventilation increase versus PETCO2, were inversely related to gas-to-blood PCO2 disequilibria due to VA/Q heterogeneity and buffer capacity (BC), but not airflow limitation. S may be corrected for these artifacts to restore S as a more valid noninvasive index of central CO2 responsiveness. We conclude that a rebreathing model incorporating baseline VA/Q heterogeneity and BC can simulate gas and blood PCO2 in patients with COPD, where VA/Q variations are large and variable.

Effect of a marathon run on serum lipoproteins, creatine kinase, and lactate dehydrogenase in recreational runners

The objective of this study was to determine the effect of a marathon run on serum lipid and lipoprotein concentrations and serum muscle enzyme activities and follow their recovery after the run. These blood concentrations were measured before, immediately after, and serially after a marathon run in 15 male recreational runners. The triglyceride level was significantly elevated postrace, then fell 30% below baseline 1 day after the run, and returned to baseline after 1 week. Total cholesterol responded less dramatically but with a similar pattern. High-density lipoprotein cholesterol remained significantly elevated and low-density lipoprotein cholesterol was transiently reduced for 3 days after the run. The total cholesterol/high-density cholesterol ratio was significantly lowered for 3 days. Serum lactate dehydrogenase activity significantly doubled postrace and then declined but remained elevated for 2 weeks. Serum creatine kinase activity peaked 24 hr after the run, with a 15-fold rise, and returned to baseline after 1 week. The rise of these enzymes reflects mechanically damaged muscle cells leaking contents into the interstitial fluid. It is concluded that a prolonged strenuous exercise bout in recreational runners, such as a marathon, produces beneficial changes in lipid blood profiles that are significant for only 3 days. However, muscle damage is also evident for 1 week or more from the dramatic and long-lasting effect on enzyme levels. Laboratory values for these runners were outside normal ranges for some days after the race.

Validation of a two-compartment model of ventilation/perfusion distribution

Ventilation (V (A)) to perfusion (Q ) heterogeneity (V (A)/Q ) analyses by a two-compartment lung model (2C), utilizing routine gas exchange measurements and a computer solution to account for O(2) and CO(2) measurements, were compared with multiple inert gas elimination technique (MIGET) analyses and a multi-compartment (MC) model. The 2C and MC estimates of V (A)/Q mismatch were obtained in 10 healthy subjects, 43 patients having chronic obstructive pulmonary disease (COPD) and in 14 dog experiments where hemodynamics and acid-base status were manipulated with gas mixtures, fluid loading and tilt-table stressors. MIGET comparisons with 2C were made on 6 patients and 32 measurements in healthy subjects before and after exercise at normoxia and altitude hypoxia. Statistically significant correlations for logarithmic standard deviations of V (A)/Q distributions (SD(V (A)/Q )) were obtained for all 2C comparisons, with similar values between 2C and both other methods in the 1.1-1.5 range, compatible with mild to moderate COPD. 2C tended to overestimate MC and MIGET values at low and underestimate them at high SD(V (A)/Q ) values. SD(V (A)/Q ) weighted by Q agreed better with MC and MIGET estimates in the normal range, whereas SD(V (A)/Q ) weighted by V (A) was closer to MC at higher values because the V (A)-weighted SD(V (A)/Q ) is related to blood-to-gas PCO(2) differences that are elevated in disease, thereby allowing better discrimination. The 2C model accurately described functional V (A)/Q characteristics in 26 normal and bronchoconstricted dogs during non-steady state rebreathing and could be used to quantify the effect of reduced O(2) diffusing capacity in diseased lungs. These comparisons indicate that 2C adequately describes V (A)/Q mismatch and can be useful in clinical or experimental situations where other techniques are not feasible.

Role of Hypobaria in Fluid Balance Response to Hypoxia

To estimate the separate and combined effects of reduced P(B) and O2 levels on body fluid balance and regulating hormones, measurements were made during reduced PB (altitude, ALT; P(B) = 432 mm Hg, F(I(O2)) = 0.207), reduced inspired O2 concentration (normobaric hypoxia, HYX; P(B) = 614 mm Hg, F(I(O2)) = 0.142), and lowered ambient pressure without hypoxia (normoxic hypobaria HYB; P(B) = 434 mm Hg, F(I(O2)) = 0.296). Nine fit and healthy young men were exposed to these conditions for 10 h in a decompression chamber. Lake Louise AMS scores, urine collections, and blood samples were obtained every 3 h, with recovery measurements 2 h after exposure. AMS was significantly greater during ALT than HYX, as previously reported (J. Appl. Physiol. 81:1908-1910. 1996), because the combination of reduced P(B) and P(O2) over the 10 h favored fluid retention by reducing urine volume, while plasma volume (PV) remained higher than during HYX. At ALT the plasma Na+ fell significantly at 6 h, probably from dilution of extracellular fluid, and antidiuretic hormone (ADH) was highest (p = 0.006 versus HYB). The PV, urine flow, free water clearance, and plasma renin activity (PRA) rose significantly during recovery from ALT as AMS symptoms subsided, suggesting increased intravascular fluid and reduced adrenergic tone. During HYB, the plasma aldosterone (ALDO) and K+ levels were significantly elevated, and PRA was highest and ADH lowest, without fluid retention. During HYX, fluid balance was similar to HYB, but PV and ALDO were significantly lower, and ALDO increased significantly in recovery from HYX. The fluid retention at ALT in AMS-susceptible subjects appears related to a synergistic interaction involving reduced P(B) and ADH and ALDO.

Early fluid retention and severe acute mountain sickness

Field studies of acute mountain sickness (AMS) usually include variations in exercise, diet, and environmental conditions over days and development of clinically apparent edemas. The purpose of this study was to clarify fluid status in persons developing AMS vs. those remaining without symptoms during simulated altitude with controlled fluid intake, diet, temperature, and without exercise. Ninety-nine exposures of 51 men and women to reduced barometric pressure (426 mmHg = 16,000 ft. = 4,880 m) were carried out for 8–12 h. AMS was evaluated by Lake Louise (LL) and AMS-C scores near the end of exposure. Serial measurements included fluid balance, electrolyte excretions, and plasma concentrations, regulating hormones, and free water clearance. Comparison between 16 subjects with the lowest AMS scores near the end of exposure (“non-AMS”: mean LL = 1.0, range = 0–2.5) and 16 others with the highest AMS scores (“AMS”: mean LL = 7.4, range = 5–11) demonstrated significant fluid retention in AMS beginning within the first 3 h, resulting from reduced urine flow. Plasma Na+ decreased significantly after 6 h, indicating dilution throughout the total body water. Excretion of Na+ and K+ trended downward with time in both groups, being lower in AMS after 6 h, and the urine Na+-to-K+ ratio was significantly higher for AMS after 6 h. Renal compensation for respiratory alkalosis, plasma renin activity, aldosterone, and atrial natriuretic peptide were not different between groups, with the latter tending to rise and aldosterone falling with time of exposure. Antidiuretic hormone fell in non-AMS and rose in AMS within 90 min of exposure and continued to rise in AMS, closely associated with severity of symptoms and fluid retention.

Effects of ischemic training on leg exercise endurance

This study tested whether ischemic exercise training (Tr(IS+EX)) would increase endurance of ischemic (Ex(IS)) and ramp exercise (Ex(RA)) knee-extension tests more than exercise training (Tr(EX)) alone. Ten healthy subjects performed pre- and posttraining tests with each leg. For Ex(RA), after subjects warmed up, a weight was added each minute until they were exhausted. Ex(IS) was similar, but after warm-up, we inflated a thigh cuff to 150 mmHg instead of adding weights. One leg was chosen for Tr(IS+EX) (cuff inflated to 150 mmHg during exercise) and the other for Tr(EX), both with a small weight on each leg, four to six times per daily session for 3 to 5 min each, 5 days per week for 6 weeks. Ex(IS) duration increased 120% more (p = 0.002) in the Tr(IS+EX) leg than in the contralateral Tr(EX) leg, whereas Ex(RA) duration increased only 16% (nonsignificant). Tr(IS+EX )and Tr(EX) significantly attenuated the ventilation increase (ergoreflex) during Ex(IS). TheO(2) debt for Ex(IS )was significantly lower and systolic blood pressure recovery was faster after Tr(IS+EX) than after Tr(EX). Heart rate recovery after Ex(RA )andEx(IS )was faster after Tr(IS+EX). Apparently, Tr(IS+EX) with low-intensity resistance increases exercise endurance and attenuates the ergoreflex and therefore may be a useful tool to increase regional muscle endurance to improve systemic exercise capacity in patients.

Effects of habitual smoking on cardiorespiratory responses to sub-maximal exercise

The effects of habitual cigarette smoking on cardiorespiratory responses to sub-maximal and maximal work were evaluated in nine adult nonsmokers and nine smokers with a mean age of 33 yr. A maximal treadmill test was followed by three tests at 45, 60 and 75% of each subject's VO(2)max. Compared to nonsmokers, the habitual smokers had a non-significantly lower VO(2)max in L/min and per lean body mass (9 and 6%, respectively), but had higher %fat (p<0.01), resulting in a significantly lower VO(2)max per kg body wt (13%, p<0.03). Maximal exercise ventilation (V(E)) was 16% lower in smokers. During sub-maximal work at equivalent exercise stress levels in the two groups, the V(E)/VO(2) ratio was higher in smokers by an average of 11% because VO(2) was lower and the respiratory exchange ratio values were significantly elevated in smokers at 75% of VO(2)max. Blood lactate concentrations in smokers were higher as workloads increased and O(2) pulse (VO(2)/HR) was significantly lower throughout, indicating reduced O(2) extraction, probably due to carbon monoxide. The resting HR was significantly higher in smokers and the HR recovery following all three submaximal exercises was significantly slower in smokers. These results show that detrimental cardiorespiratory effects of chronic cigarette smoking in apparently healthy individuals are evident at moderate exercise levels as reduced gas exchange efficiency in lungs and muscles.

Body Temperature, Autonomic Responses, and Acute Mountain Sickness

A few studies have reported increased body temperature (T(o)) associated with acute mountain sickness (AMS), but these usually include exercise, varying environmental conditions over days, and pulmonary edema. We wished to determine whether T(o) would increase with AMS during early exposure to simulated altitude at rest. Ninety-four exposures of 51 men and women to reduced P(B) (423 mmHg = 16,000 ft = 4850 m) were carried out for 8 to 12 h. AMS was evaluated by LL and AMS-C scores near end of exposure, and T(o) was measured by oral digital thermometer before altitude and after 1 (A1), 6 (A6), and last (A12) h at simulated altitude. Other measurements included ventilation, O(2) consumption and autonomic indicators of plasma catecholamines, HR, and HR variability. Average T(o) increased by 0.5 degrees F from A1 to A12 in all subjects (p < 0.001). Comparison between 16 subjects with lowest AMS scores (mean LL = 1.0, range = 0 to 2.5) and 16 other subjects with highest AMS scores (mean LL = 7.4, range = 5 to 11) demonstrated a transient decline in T(o) from A1 to A6 in AMS, in contrast to a rise in non-AMS (p = 0.001). Catecholamines, HR, and HR variability (increased low F/high F ratio) indicated significant elevation of sympathetic activity in AMS, where T(o) fell, but no change in metabolic rate. The apparently greater heat loss during early AMS suggests increased hypoxic vasodilation in spite of enhanced sympathetic drive. Greater hypoxic vasodilation and elevated HR in AMS in the absence of other changes suggest that augmentation of beta-adrenergic tone may be involved in early AMS pathophysiology.

Plasma volume by Evans blue: effects of eating and comparison with other methods at altitude

HYPOTHESIS

Measurements of plasma volume (PV) and its changes (delta%PV) by Evans blue (EB) dye are presumed to be valid only in fasting subjects. In addition, delta%PVEB with acute altitude exposure has not been compared with other methods employing the concentration or dilution of naturally occurring blood (hematocrit (Hct), hemoglobin (Hb)) and plasma (density, proteins) components, but should be similar if capillary permeability and the sampled vein/whole body Hct ratio remain unchanged.

METHODS

PVEB was determined in six subjects while fasting or eating on different days, with injection and sampling in the same arm, 4-h extrapolation to time zero and correcting readings with the 620-740 A method. For 93 experiments at altitude, delta%PVEB was obtained similarly from a 3-h extrapolation near the end of a 12-h chamber exposure to 426 mm Hg (-4,880 m =16,000 ft) and at the same time on the preceding control day.

RESULTS

Mean PVEB with and without eating was not significantly different (SE of absolute difference = +/- 2.8%). The EB decay curves had significantly more scatter with eating than fasting. The fasting vs. non-fasting values for the single 20-min post-injection point also gave a close comparison (r = +0.97). At altitude the loss in PV measured with EB was significantly greater (delta%PVEB = -6.3%) than losses estimated from Hct-Hb (-2.9%), plasma protein (-3.7%), and plasma density (-3.9%). The expected larger PV loss in subjects tolerant to altitude sickness compared with intolerant ones was most clearly shown by delta%PVEB (8.8%).

CONCLUSIONS

Obtaining more samples can offset reproducibility lost by eating. The delta%PVEB were largest and nearest to values previously reported at altitude, perhaps because the single baseline and altitude samples utilized by the other methods are more sensitive to subtle, transient fluctuations in body water and vasomotor tone associated with apprehension, vomiting, fluid intake, and regional vasodilation and constriction.

Ventilation is greater in women than men, but the increase during acute altitude hypoxia is the same

We wished to determine whether the previously reported lower arterial or alveolar P(CO2) in women than men, and in luteal (LUT) compared with follicular (FOL) menstrual cycle phase would persist during normal oral contraceptive use and during early altitude exposure. Ventilation and blood gases were measured at baseline (636 mmHg approximately 5400 ft, 1650 m) and during simulated altitude at 426 mmHg ( approximately 16000 ft, 4880 m), after 1 h (A1) and during the 12th h (A12), in 18 men (once) and in 19 women twice, during LUT and FOL and in 20 women twice while on placebo (PLA) or highest progestin dose (PIL) oral contraceptives. At baseline, Pa(CO2) was significantly higher in men than all women by 3.3 mmHg. When progesterone-progestin (PRO) was elevated in women, Pa(CO2) was significantly lower than in FOL and PLA, but the latter were still significantly lower than men. At altitude the P(CO2) differences between men and women and PRO levels persisted, with PA(CO2) falling by 3.6 and 7.3 mmHg at A1 and A12 in all, indicating an equivalent increase in alveolar ventilation. The mean arterial-end tidal P(CO2) difference was never >2 mmHg in the groups, indicating no VA/Q mismatch related to gender, PRO levels or altitude. All women had higher breathing frequency than men, resulting in greater deadspace ventilation. At altitude, the mean Pa(O2) was approximately 44 mmHg (Sa(O2) approximately 79%) for all, indicating equivalent oxygenation, but alveolar-arterial P(O2) differences were greater in women than men and higher when PRO was elevated. These results show that, relative to men, women have a compensated respiratory alkalosis, accentuated with elevated PRO. However, the ventilation response to acute altitude is the same in women and men.

Exercise exacerbates acute mountain sickness at simulated high altitude

We hypothesized that exercise would cause greater severity and incidence of acute mountain sickness (AMS) in the early hours of exposure to altitude. After passive ascent to simulated high altitude in a decompression chamber [barometric pressure = 429 Torr, approximately 4,800 m (J. B. West, J. Appl. Physiol. 81: 1850-1854, 1996)], seven men exercised (Ex) at 50% of their altitude-specific maximal workload four times for 30 min in the first 6 h of a 10-h exposure. On another day they completed the same protocol but were sedentary (Sed). Measurements included an AMS symptom score, resting minute ventilation (VE), pulmonary function, arterial oxygen saturation (Sa(O(2))), fluid input, and urine volume. Symptoms of AMS were worse in Ex than Sed, with peak AMS scores of 4.4 +/- 1.0 and 1.3 +/- 0.4 in Ex and Sed, respectively (P < 0.01); but resting VE and Sa(O(2)) were not different between trials. However, Sa(O(2)) during the exercise bouts in Ex was at 76.3 +/- 1.7%, lower than during either Sed or at rest in Ex (81.4 +/- 1.8 and 82.2 +/- 2.6%, respectively, P < 0.01). Fluid intake-urine volume shifted to slightly positive values in Ex at 3-6 h (P = 0.06). The mechanism(s) responsible for the rise in severity and incidence of AMS in Ex may be sought in the observed exercise-induced exaggeration of arterial hypoxemia, in the minor fluid shift, or in a combination of these factors.

Effects of gas density on experimentally obstructed ventilation during acute hypoxia

When patients with obstructive lung disease breathe helium-oxygen mixtures, their arterial PCO2, is lowered towards normal, indicating more effective ventilation. However, there is a lack of detailed respiratory data from clinical cases, so that the mechanisms remain unclear. To study relevant variables during hypoxemia and obstruction in the absence of disease, we undertook experiments with healthy subjects breathing normoxic and hypoxic gas mixtures of differing densities (air, 13.7% O2 in N2 and 13.7% O2 in helium) through an experimental obstruction (resistive airway loading). This increased airway resistance was twice that reported from the ambient-pleural pressure differences in patients with moderately severe emphysema. Without imposed resistance the total ventilation (VE) increased 27% on both hypoxic mixtures. With normoxia, the obstruction increased tidal volume but decreased frequency so that VE and alveolar ventilation (VA) were essentially unchanged. With hypoxia, breathing pattern changed similarly, but now VE decreased while VA was maintained. Helium returned the breathing patterns toward normal. Obstruction lowered the rapid increase in VE from two or three breaths of N2, but the decrease from two or three breaths of O2 was unchanged. We detected an increase in metabolic rate with obstructed breathing that was reduced by the helium mixtures. The remarkable finding was that despite the obstruction being markedly uncomfortable because of the high resistance, we did not find any substantial disturbance in gas exchange, compared to hypoxia with no obstruction. Thus, the main mechanisms responsible for improved blood gases in patients breathing helium mixtures were outside the scope of our experiment and likely related to disease factors.

Effect of head-down tilt on brain water distribution

Vascular and tissue fluid dynamics in the microgravity of space environments is commonly simulated by head-down tilt (HDT). Previous reports have indicated that intracranial pressure and extracranial vascular pressures increase during acute HDT and may cause cerebral edema. Tissue water changes within the cranium are detectable by T2 magnetic resonance imaging. We obtained T2 images of sagittal slices from five subjects while they were supine and during -13 degrees HDT using a 1.5-Tesla whole-body magnet. The analysis of difference images demonstrated that HDT leads to a 21% reduction of T2 in the subarachnoid cerebrospinal fluid (CSF) compartment and a 11% reduction in the eyes, which implies a reduction of water content; no increase in T2 was observed in other brain regions that have been associated with cerebral edema. These findings suggest that water leaves the CSF and ocular compartments by exudation as a result of increased transmural pressure causing water to leave the cranium via the spinal CSF compartment or the venous circulation.

The effects of low levels of CO2 on ventilation during rest and exercise

BACKGROUND

Measurements of pulmonary gas exchange are especially sensitive to low levels of CO2 in the environment; this is an important consideration in measurements in enclosed spaces.

METHODS

In order to determine the responses to these low levels, subjects were exposed in five studies to partial pressures of inspired CO2 (PICO2) of 5.7 and 7.5 mmHg for 30 min during basal conditions at rest and to 5.4, 9.4 and 15 mmHg during a progressive exercise to VO2max on a cycle ergometer.

RESULTS

In the two resting studies, total pulmonary ventilation and alveolar ventilation were increased by 19% at 7.5 mmHg (1.1% sea level equivalent) and 10% at 5.4 mmHg (0.8% equivalent), with clear evidence of CO2 retention in both studies. During exercise at 15 mmHg the VO2max was reduced significantly by 13%, compared with air at about the same maximal ventilation, but VO2max was not reduced at 9.4 mmHg. A 6% decrease in VO2max at a PICO2 of 5.4 mmHg may have resulted from these subjects being less fit. The maximal CO2 output and respiratory exchange ratio in the three exercise studies was always lower with CO2 than corresponding air measurements, indicating CO2 storage. Evaluation of submaximal measurements provided an equation for predicting ventilation as a function of PICO2 and VO2/VO2max and demonstrated that ventilation during submaximal exercise is increased significantly by the lowest CO2 level. BP and heart rate responses during submaximal and maximal work were not predictably altered by CO2 at these levels.

CONCLUSION

These studies demonstrate that minimal CO2 levels have significant influences on pulmonary ventilation during rest and exercise and must be considered in acute studies in confined spaces such as space cabins. The inspired CO2 should be stated when ventilation measurements are reported under these conditions.

Ventilation during simulated altitude, normobaric hypoxia and normoxic hypobaria

To investigate the possible effect of hypobaria on ventilation (VE) at high altitude, we exposed nine men to three conditions for 10 h in a chamber on separate occasions at least 1 week apart. These three conditions were: altitude (PB = 432, FIO2 = 0.207), normobaric hypoxia (PB = 614, FIO2 = 0.142) and normoxic hypobaria (PB = 434, FIO2 = 0.296). In addition, post-test measurements were made 2 h after returning to ambient conditions at normobaric normoxia (PB = 636, FIO2 = 0.204). In the first hour of exposure VE was increased similarly by altitude and normobaric hypoxia. The was 38% above post-test values and end-tidal CO2 (PET(CO2) was lower by 4 mmHg. After 3, 6 and 9 h, the average VE in normobaric hypoxia was 26% higher than at altitude (p < 0.01), resulting primarily from a decline in VE at altitude. The difference between altitude and normobaric hypoxia was greatest at 3 h (+ 39%). In spite of the higher VE during normobaric hypoxia, the PET(CO2) was higher than at altitude. Changes in VE and PET(CO2) in normoxic hypobaria were minimal relative to normobaric normoxia post-test measurements. One possible explanation for the lower VE at altitude is that CO2 elimination is relatively less at altitude because of a reduction in inspired gas density compared to normobaric hypoxia; this may reduce the work of breathing or alveolar deadspace. The greater VE during the first hour at altitude, relative to subsequent measurements, may be related to the appearance of microbubbles in the pulmonary circulation acting to transiently worsen matching. Results indicate that hypobaria per se effects ventilation under altitude conditions.

Acute ventilatory response to simulated altitude, normobaric hypoxia, and hypobaria

BACKGROUND

Some reports claim that ventilation (VE) is greater in human subjects in normobaric hypoxia than at altitude following an equivalent drop in inspired PO2 (PIO2). It has been suggested that reduced barometric pressure (PB) may decrease chemoreceptor sensitivity and account for these results. In this pilot study we tested the hypothesis that VE and hypoxic chemoresponsiveness would not be different after 30 min of normobaric hypoxia and altitude.

METHODS

We exposed three male and three female subjects to four conditions in an environmental chamber, varying the order. The four conditions were: air (PB = 640, FIO2 = 0.204), hypobaria (434, 0.298), hypoxia (640, 0.141) and altitude (434, 0.203). We measured VE, end-tidal O2 and CO2 and arterial O2 saturation (SpO2) after 30 min in each environment, and while breathing 100% O2 for 1 min immediately thereafter.

RESULTS

The mean increase in VE relative to air was 14%, 20% and 26% for hypobaria, hypoxia and altitude, respectively, with corresponding reductions in PETCO2 in the three conditions. The reduction in VE with 100% O2 was inversely proportional to the rise in SpO2 in all cases, indicating that chemoresponsiveness was unchanged by PB. When hypobaria preceded altitude, the VE at altitude increased less, relative to air, than when altitude was given first (not significant).

CONCLUSIONS

The VE and chemosensitivity are about the same after 30 min of altitude and equivalent hypoxia. However, when the drop in PIO2 is not synchronous with the drop in PB, like at altitude, the VE values may be altered. Air density, hypoxic pulmonary vasoconstriction and circulating microbubbles may interact to account for the observed findings.

Acute mountain sickness: increased severity during simulated altitude compared with normobaric hypoxia

Acute mountain sickness (AMS) strikes those in the mountains who go too high too fast. Although AMS has been long assumed to be due solely to the hypoxia of high altitude, recent evidence suggests that hypobaria may also make a significant contribution to the pathophysiology of AMS. We studied nine healthy men exposed to simulated altitude, normobaric hypoxia, and normoxic hypobaria in an environmental chamber for 9 h on separate occasions. To simulate altitude, the barometric pressure was lowered to 432 +/- 2 (SE) mmHg (simulated terrestrial altitude 4,564 m). Normobaric hypoxia resulted from adding nitrogen to the chamber (maintained near normobaric conditions) to match the inspired PO2 of the altitude exposure. By lowering the barometric pressure and adding oxygen, we achieved normoxic hypobaria with the same inspired PO2 as in our laboratory at normal pressure. AMS symptom scores (average scores from 6 and 9 h of exposure) were higher during simulated altitude (3.7 +/- 0.8) compared with either normobaric hypoxia (2.0 +/- 0.8; P < 0.01) or normoxic hypobaria (0.4 +/- 0.2; P < 0.01). In conclusion, simulated altitude induces AMS to a greater extent than does either normobaric hypoxia or normoxic hypobaria, although normobaric hypoxia induced some AMS.

Acute effects of head-down tilt and hypoxia on modulators of fluid homeostasis

In an effort to understand the interaction between acute postural fluid shifts and hypoxia on hormonal regulation of fluid homeostasis, the authors measured the responses to head-down tilt with and without acute exposure to normobaric hypoxia. Plasma atrial natriuretic peptide (ANP), cyclic guanosine monophosphate (cGMP), cyclic adenosine monophosphate (cAMP), plasma aldosterone (ALD), and plasma renin activity (PRA) were measured in six healthy male volunteers who were exposed to a head-down tilt protocol during normoxia and hypoxia. The tilt protocol consisted of a 17 degrees head-up phase (30 minutes), a 28 degrees head-down phase (1 hour), and a 17 degrees head-up recovery period (2 hours, with the last hour normoxic in both experiments). Altitude equivalent to 14,828 ft was simulated by having the subjects breathe an inspired gas mixture with 13.9% oxygen. The results indicate that the postural fluid redistribution associated with a 60-minute head-down tilt induces the release of ANP and cGMP during both hypoxia and normoxia. Hypoxia increased cGMP, cAMP, ALD, and PRA throughout the protocol and significantly potentiated the increase in cGMP during head-down tilt. Hypoxia had no overall effect on the release of ANP, but appeared to attenuate the increase with head-down tilt. This study describes the acute effects of hypoxia on the endocrine response during fluid redistribution and suggests that the magnitude, but not the direction, of these changes with posture is affected by hypoxia.

Relationship between whole blood base excess and CO2 content in vivo

Empirical relationships are demonstrated for whole blood base excess (BE) and CO2 content (CCO2), both calculated from in vivo measurements of PCO2, pH, hemoglobin concentration and O2 saturation. Comparisons are provided by measurements from three separate studies: (1) supine exercise (arterial and mixed venous samples); (2) chronic obstructive disease patients (arterial samples) breathing air and 100% O2; and (3) maximal seated exercise on a bicycle ergometer with and without added inspired CO2 (arterial samples before, during and after). Two standardized values of CCO2 (vol.%) are derived which closely relate to BE (mmol/l). The CCO2 at a PCO2 of 40 mmHG [CCO2(40)] for all samples (n = 220) demonstrated a curvilinear relationship: CCO2 (40) = 45.37 + 1.48(BE) + 0.0156(BE)2, r = + 0.996, SEE = 0.88 vol.%. The CCO2 at a pH of 7.4 [CCO2(7.4)] gave a linear relationship: CCO2(7.4) = 45.09 + 2.58(BE), r = + 0.998, SEE = 1.19 vol.%. Empirical computations for the Haldane factor from studies 1 and 2 gave values of 0.285 in terms of CCO2 (vol.%/vol.%) and 0.266 for BE (mmol/l/mmol reduced Hb). The BE values can serve as useful estimates of lactate concentrations during exercise and the excellent relationships between standardized CCO2 and BE demonstrate their equivalency and either can be utilized, depending on whether quantification of the CO2 dissociation curve or acid-base status is desired.

Effects of prolonged head-down bed rest on physiological responses to moderate hypoxia

To determine the effects of hypoxia on physiological responses to simulated zero-gravity, cardiopulmonary and fluid balance measurements were made in 6 subjects (acclimatized to 5,400 ft) before and during 5 degrees head-down bed rest (HDBR) over 8 d at 10,678 ft and a second time at this altitude as controls (CON). The VO2max increased by 9% after CON, but fell 3% after HDBR (p < 0.05). This reduction in work capacity during HDBR could be accounted for by inactivity. The heart rate response to a head-up tilt was greatly enhanced following HDBR, while mean blood pressure was lower. No significant negative impact of HDBR was noted on the ability to acclimatize to hypoxia in terms of pulmonary mechanics, gas exchange, circulatory or mental function measurements. No evidence of pulmonary interstitial edema or congestion was noted during HDBR at the lower PIO2 and blood rheology properties were not negatively altered. Symptoms of altitude illness were more prevalent, but not marked, during HDBR and arterial blood gases and oxygenation were not seriously effected by simulated microgravity. Declines in base excess with altitude were similar in both conditions. The study demonstrated a minimal effect of HDBR on the ability to adjust to this level of hypoxia.

Body fluid alterations during head-down bed rest in men at moderate altitude

To determine the effects of hypoxia on fluid balance responses to simulated zero-gravity, measurements were made in six subjects (acclimatized to 5,400 ft; 1,646 m) before and during -5 degrees continuous head-down bed rest (HDBR) over 8 d at 10,678 ft. The same subjects were studied again at this altitude without HDBR as a control (CON) using a cross-over design. During this time, they maintained normal upright day-time activities, sleeping in the horizontal position at night. Fluid balance changes during HDBR in hypoxia were more pronounced than similar measurements previously reported from HDBR studies at sea level. Plasma volume loss (-19% on day 6) was slightly greater and the diuresis and natriuresis were doubled in magnitude as compared to previous studies in normoxia and sustained for 4 d during hypoxia. These changes were associated with an immediate, but transient rise in plasma atrial natriuretic peptide (ANP) to day 4 of 140% in HDBR and 41% in CON (p < 0.005), followed by a decline towards baseline. Differences were less striking between HDBR and CON for plasma antidiuretic hormone and aldosterone, which were transiently reduced by HDBR. Plasma catecholamines showed a similar pattern to ANP (+122%) in both HDBR and CON, suggesting that elevated ANP and catecholamines together accounted for the enhanced fluid shifts with HDBR during hypoxia.

Alveolar ventilation to perfusion heterogeneity and diffusion impairment in a mathematical model of gas exchange

This study describes a two-compartment model of pulmonary gas exchange in which alveolar ventilation to perfusion (VA/Q) heterogeneity and impairment of pulmonary diffusing capacity (D) are simultaneously taken into account. The mathematical model uses as input data measurements usually obtained in the lung function laboratory. It consists of two compartments and an anatomical shunt. Each compartment receives fractions of alveolar ventilation and blood flow. Mass balance equations and integration of Fick's law of diffusion are used to compute alveolar and blood O2 and CO2 values compatible with input O2 uptake and CO2 elimination. Two applications are presented. The first is a method to partition O2 and CO2 alveolar-arterial gradients into VA/Q and D components. The technique is evaluated in data of patients with chronic obstructive pulmonary disease (COPD). The second is a theoretical analysis of the effects of blood flow variation in alveolar and blood O2 partial pressures. The results show the importance of simultaneous consideration of D to estimate VA/Q heterogeneity in patients with diffusion impairment. This factor plays an increasing role in gas alveolar-arterial gradients as severity of COPD increases. Association of VA/Q heterogeneity and D may produce an increase of O2 arterial pressure with decreasing QT which would not be observed if only D were considered. We conclude that the presented computer model is a useful tool for description and interpretation of data from COPD patients and for performing theoretical analysis of variables involved in the gas exchange process.

Effects of acid-base status on acute hypoxic pulmonary vasoconstriction and gas exchange

To investigate the relationship between hypoxic pulmonary vasoconstriction and respiratory and metabolic acidosis and respiratory alkalosis, the pulmonary gas exchange and pulmonary hemodynamic responses were measured in anesthetized, paralyzed, and mechanically ventilated dogs in two sets of experiments (series A, n = 6; series B, n = 10). The animals were treated with acute hypoxia, CO2 inhalation, hyperventilation, and dinitrophenol in various combinations. Multiple regression analysis indicated that mean pulmonary arterial pressure (Ppa) was significantly correlated with end-tidal PO2, mixed venous PO2, and the mean pulmonary capillary pH (average of arterial and mixed venous pH) as independent variables [series A: r = +0.999, standard error of estimate (SEE) = 0.4 mmHg; series B: r = +0.98, SEE = 1.4 mmHg]. Similar analyses of mean values published by other authors from an acute study on humans with exercise at sea level and simulated altitudes of 10,000 and 15,000 ft also indicated a good relationship (n = 14, r = +0.98, SEE = 2.1 mmHg). The mean data (n = 19) obtained in Operation Everest II at various exercise loads and simulated altitudes gave a correlation of r = +0.87, SEE = 6.1 mmHg. These empirical analyses suggest that variations in the rise of Ppa with hypoxia can be accounted for in vivo by the superimposed acid-base status. Furthermore, ventilation-perfusion inhomogeneity, as estimated in the dogs from end-tidal and arterial O2 and CO2 differences and assuming no true shunt or diffusion impairment, was highly correlated with Ppa and mean pulmonary capillary pH (r = +0.999 in series A, r = +0.77 in series B). The human data from the above studies also showed significant correlations between Ppa and directly measured ventilation-perfusion (standard deviation of perfusion obtained from inert gas measurements). These observations indicate that the beneficial effects of hyperventilation during hypoxia may be related to the marked alkalosis that serves to reduce Ppa and improve pulmonary gas exchange efficiency.

Cardiopulmonary responses to acute hypoxia, head-down tilt and fluid loading in anesthetized dogs

The separate and combined acute effects of hypoxia (HY-11% O2), head-down tilt (HD-30 degrees) and fluid loading (FL-1.0 L saline) on hemodynamics and pulmonary gas exchange were determined in 17 anesthetized, mechanically ventilated dogs. Both during HY and normoxia (NO), the total respiratory compliance was decreased by HD, attributable to pulmonary vascular congestion. The reductions in compliance were twice as great with FL, indicating pulmonary interstitial edema, which was supported by histological observation of lung tissue. Pressure-flow relationships in the pulmonary circulation indicated that superimposing HD on HY doubled the increase in vascular resistance due to HY alone, while in the systemic circulation the resistance was returned to below NO by HD. A significant positive correlation between the changes in blood volume and pulmonary artery pressure for experimental transitions suggests that a shift in blood volume from systemic to pulmonary circulations and changes in total blood volume probably contributed substantially to these apparent changes in resistance. Pulmonary gas exchange efficiency, whether expressed in terms of shunt or ventilation/perfusion distribution from arterial-end-tidal PCO2 and PO2 differences, showed a significant inverse relationship with pulmonary driving pressure for the experimental conditions imposed. No clear synergistic effects of HY on HD were evident in contributing to pulmonary edema when superimposed prior to FL, but after FL this risk must be considered.

Effects of acute hypoxia on cardiopulmonary responses to head-down tilt

Six male subjects were exposed on two separate occasions to simulated microgravity with 28 degrees head-down tilt (HD) for 1 h with baseline followed by recovery at + 17 degrees head-up. Pulmonary ventilation, gas exchange, spirometry, and central and cerebral blood flow characteristics were compared while breathing ambient air (PIO2 = 122 mm Hg) and reduced FIO2 equivalent to 14,828 ft (PIO2 = 81 mm Hg). With hypoxia (HY), the increased tidal volume served to attenuate the drop in arterial saturation by reducing deadspace ventilation. Arterial and mixed venous PO2 values, estimated from peripheral venous samples and cardiac output (CO), were both maintained during HD in HY. Mixed venous PO2 was elevated by an increase in CO associated with a reduction in systemic resistance. Changes in spirometric indices during HD were not accentuated by HY, making the presence of interstitial edema unlikely. Cerebral flow and resistance showed minor reductions with HD. Tissue oxygenation and cardiopulmonary function were not notably effected by HD during HY, but a combination of these two stressors may predispose subjects to subsequent orthostatic intolerance during initial recovery.

Work capacity, exercise responses and body composition of professional pilots in relation to age

Body composition and submaximal and maximal cardiorespiratory responses during a progressive upright bicycle ergometer test were measured in 410 professional male pilots, aged 20 to 68 years, and divided into four groups (30, 39, 49, and 59 years). Fat-free weight by hydrostatic weighing was not significantly different between groups and fat increased linearly with age, while height was lower and weight levelled off in the oldest group. Aerobic work capacity (VO2max) fell at a rate of 0.25 ml.min-1.kg-1 per year in this unique population of healthy, but generally sedentary men. A subgroup of 10 pilots, tested annually from age 31 to 47, demonstrated a reversal of the age-related decline in VO2max. This was attributable to regular physical activity, short of athletic training, and changes in personal health habits stimulated by self-assessment available from the repeated tests incorporated into the medical prevention program. These data considered in relation to more recent reports of stroke volume during similar maximal exercise protocols suggest that VO2max is limited during aging by a reduction in tissue diffusing capacity or increased maldistribution of perfusion in relation to O2 uptake in muscle and this can be partially prevented by training. Reference standards for heart rate, blood pressure and ventilation during submaximal and maximal exercise levels are presented in relation to energy requirements and work intensity at various ages.

Effects of pentoxifylline on pulmonary hemodynamics during acute hypoxia in anesthetized dogs

The effects of pentoxifylline on pulmonary hemodynamics were studied in anesthetized dogs during acute alveolar hypoxia. In Series A, 7 dogs received pentoxifylline orally (18 mg/kg/day) for 11 wk and 7 untreated dogs served as control animals. During anesthesia and controlled ventilation, acute alveolar hypoxia was induced (10 to 13% inspired O2) and pulmonary and systemic hemodynamic and blood rheologic measurements were compared with normoxia. In control dogs, cardiac index did not change during hypoxia, but pulmonary vascular resistance index (PVRI) increased 79%, erythrocyte filterability decreased significantly (p less than 0.05), and relative viscosity of blood corrected for hematocrit did not change. In the pentoxifylline-treated dogs, cardiac index increased 28% and PVRI increased only 20%; in contrast to the control dogs, relative viscosity of blood was decreased by 18% and no significant changes in filterability were observed. The increase in PVRI in relation to the drop in arterial O2 saturation was significantly larger (p less than 0.05) in the control dogs. Pentoxifylline also increased P50 by 2.8 mm Hg (p less than 0.05). In Series B, hemodynamic measurements were made during variations in blood flow (induced by restricting venous return) in 3 treated (26 mg/kg/day for 3 wk) and 3 control dogs. In these experiments, pulmonary artery pressure was significantly lower at comparable flows during both normoxia and hypoxia. In both studies, the hemodynamic effects of the drug on the systemic circulation were less than on the pulmonary circulation.(ABSTRACT TRUNCATED AT 250 WORDS)

The effects of head-down tilt on carotid blood flow and pulmonary gas exchange

Common carotid artery blood flow (CCF), pulmonary gas exchange and ventilation were measured in six subjects in the supine posture (SUP I), serially during 20 min of head-down tilt at -30 degrees (HDT) and after returning to the supine posture (SUP II). CCF was approximately 6% lower during HDT, with a transient increase during the second minute, and was about 7% higher during SUP II than during SUP I. The transition from SUP I to HDT caused increases in O2 uptake (VO2), CO2 output, respiratory exchange ratio and tidal volume in the first minute. Similar responses were apparent following the HDT to SUP II transition, except for VO2, which changed little. Correction of VO2 for changes in estimated lung O2 stores indicated that about 200 ml of blood were shifted within the circulation by the tilt transitions which provided a ventilatory stimulus. HDT can cause a loss in blood and tissue O2 stores and gain in CO2 stores by shifting blood volume toward and blood flow away from the dependent headward vascular compartment and perhaps by producing ischemia in the elevated lower extremities. Cerebral venous congestion during HDT appears to cause periodic breathing and reduce CCF, the latter being partially offset by reduced flow resistance in the carotid artery.

Acid-base status immediately following rapid changes of alveolar gas composition in awake dogs

To study the interrelationship between blood O2, CO2, and acid-base status during rapid changes of alveolar gas composition unanesthetized dogs were made to inhale high CO2 gas mixtures following air breathing or to rebreathe high CO2 and O2 mixtures following hypoxia. Before and immediately after each change in alveolar gases, sequential blood samples were taken from the carotid artery for measurement of pH, PCO2 and PO2. In the experiments at normoxia the calculated base excess (BE) decreased by about 0.7 mmol/L after 10 sec and then returned to baseline level. A smaller decrease (averaging 0.4 mmol/L) was found with hyperoxia following hypoxia. The changes in BE can be attributed to bicarbonate (or H+) exchange between blood and tissue. Lung tissue is probably responsible for the rapid initial change in BE.

Sleep apnea and autonomic cerebrovascular dysfunction

Changes in common carotid blood flow (CCF) and resistance index (RI), calculated from velocity waveforms by a noninvasive pulsed Doppler technique, were measured during apneic episodes and voluntary breath holding in five sleep apnea patients (SA) and during breath holding in five normal subjects (N). During apneic episodes averaging 27 s, CCF was reduced by 9% and RI increased by 4%, both trends being related to apneic duration. Internal carotid artery measurements in one SA indicated more dramatic changes in blood flow and RI than noted in CCF. During breath holding, CCF decreased significantly in SA but not in N, and RI showed a smaller reduction in SA. These changes in CCF and RI during sleep apnea are similar to those noted in anesthetized dogs where vasomotor waves and associated apneas were induced by elevating intracranial pressure. Previously reported recordings of ventilatory and systemic cardiovascular responses in SA are similar to these recordings in dogs, and it is therefore proposed that vasomotor responses to intermittent cerebral ischemia and hypercapnia may be the principle event in SA and periodic breathing only a secondary consequence of the prevailing autonomic dysfunction.

Validation and application of single breath cardiac output determinations in man

Cardiac outputs by single breath (Qsb) and Fick (Qf) procedures were compared in five healthy males during supine rest and exercise with Qf ranging from 6-19 L X min-1. The prolonged exhalation (SB) was not controlled. The Qsb calculations incorporated an equation of the CO2 dissociation curve and a "moving spline" sequential curve-fitting technique to calculate the instantaneous R from points on the original expirogram. The resulting linear regression equation for all 38 comparisons obtained (r = +0.76, p less than 0.001, mean difference +/- S.D. = 2.93 +/- 2.72 L X min-1) indicated a 24% underestimation of Qf. A substantial portion of the variability during exercise (n = 28) was due to a difference in alveolar ventilation between the time of the mixed expired (E) gas collection and the SB maneuver. When Qsb was corrected (Qsb) by a linear regression based on the difference between Re and Rsb during exercise and by adding 2.44 L X min-1 at rest (the mean difference), the relationship was greatly improved (Qsb = 0.14 + 0.99 Qf, r = +0.93, mean difference +/- S.D. = 0 +/- 1.47 L X min-1). A subsequent study during upright rest and exercise to 80% of VO2max in 6 subjects indicated a close linear relationship between Q'sb and VO2 for all 95 values obtained (r = +0.94), with slope and intercept close to published studies utilizing invasive cardiac output measurements. Considerations of measured blood gases in relation to estimated values suggested that underestimates of Qf arose, at least in part, from arterial desaturation during the SB maneuver. Detailed computational procedures are provided for implementing this improved Qsb procedure.

Transient PO2 and PCO2 differences between end-tidal gas and arterial blood during rebreathing in awake dogs

O2 and CO2 partial pressures in end-tidal gas (PA) and carotid artery blood (Pa) were measured during non-steady-state gas exchange in unanesthetized dogs. In 5 experiments (A), low O2 breathing in open circuit preceded prolonged rebreathing during maintained normoxia. In 6 experiments (B), steady-state hypoxia and hypercapnia were followed by rebreathing CO2 in hyperoxia which caused PAO2 to rise and then fall while PACO2 increased. Negative (Pa-PA)CO2, averaging -5 torr, were observed 10 sec after starting rebreathing in B and values between -1 and -2 torr were noted later in A and B. (PA-Pa)O2 showed considerable transient increases for 2 min in A and 20 sec in B. This behavior of (PA-Pa)O2 could be explained by a lung model with unequal distribution of alveolar ventilation and perfusion to alveolar volume. The negative (Pa-PA)CO2 values observed during rebreathing with rapidly increasing PACO2 were in part attributable to such unequal distribution effects, in part to lung-to-carotid artery transit time effects.