HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Full Text (PDF) Free All Versions of this Article: 97/2/697    most recent 00108.2004v1 Submit a response Alert me when this article is cited Alert me when eLetters are posted Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in ISI Web of Science Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via ISI Web of Science (8) Citing Articles via Google Scholar Google Scholar Articles by Robertson, H. T. Articles by Agostoni, P. Search for Related Content PubMed PubMed Citation Articles by Robertson, H. T. Articles by Agostoni, P.

Exercise response after rapid intravenous infusion of saline in healthy humans

¹Department of Medicine, University of Washington, Seattle, Washington 98195-6522; ²Centro di Fisiopatologia Respiratoria e di Studio della Dispnea, Azienda Ospedaliera S. Croce e Carle, 12100 Cuneo; ³Centro Cardiologico Monzino IRCCS, Istituto di Cardiologia, Università di Milano, 20138 Milano; and ⁴Servizio di Fisiopatologia Respiratoria, Dipartimento di Medicina Interna, Università di Genova, 16132 Genova, Italy

Submitted 2 February 2004 ; accepted in final form 15 April 2004

	ABSTRACT

TOP ABSTRACT METHODS RESULTS DISCUSSION REFERENCES

 
Patients with chronic heart failure have an abnormal pattern of exercise ventilation (E), characterized by small tidal volumes (VT), increased alveolar ventilation, and elevated physiological dead space (VD/VT). To investigate whether increased lung water in isolation could reproduce this pattern of exercise ventilation, 30 ml/kg of saline were rapidly infused into nine normal subjects, immediately before a symptom-limited incremental exercise test. Saline infusion significantly reduced forced vital capacity, 1-s forced expiratory volume, and alveolar volume (P < 0.01 for all). After saline, exercise ventilation assessed by the E/CO₂ slope increased from 24.9 ± 2.4 to 28.0 ± 2.9 l/l, (P < 0.0002), associated with a small decrease in arterial PCO₂, but without changes in VT, VD/VT, or alveolar-arterial O₂ difference. A reduction in maximal O₂ uptake of 175 ± 184 ml/min (P < 0.02) was observed in the postsaline infusion exercise studies, associated with a consistent reduction in maximal exercise heart rate (8.1 ± 5.9 beats/min, P < 0.01), but without a change in the O₂ pulse. Therefore, infusion of saline to normal subjects before exercise failed to reproduce either the increase in VD/VT or the smaller exercise VT described in heart failure patients. The observed increase in E can be attributed to dilution acidosis from infusion of the bicarbonate-free fluid and/or to afferent signals from lung and exercising muscles. The reduction in maximal power output, maximal O₂ uptake, and heart rate after saline infusion may be linked to accumulation of edema fluid in exercising muscle, impairing the diffusion of O₂ to muscle mitochondria.

edema; tidal volume; physiological dead space; exercise ventilation; maximal O₂ uptake

Rapid intravenous infusion of 30 ml/kg of saline in normal subjects reduced both forced vital capacity (FVC) and FEV₁ (23), thereby reproducing the spirometric abnormalities observed in chronic heart failure patients (2, 33). On the basis of the lack of changes in lung compliance after saline infusion, Pellegrino et al. (23) proposed that the primary abnormality produced by rapid saline infusion in healthy subjects was airway mucosal edema rather than alveolar edema. Utilizing the same rapid saline infusion protocol with healthy subjects, we sought to investigate the exercise-associated changes in ventilation, gas exchange, and exercise capacity produced by this intervention. Our goal was to characterize the exercise manifestations of extracellular volume excess in normal subjects and to relate those findings to exercise abnormalities observed in other edematous disease conditions.

	METHODS

TOP ABSTRACT METHODS RESULTS DISCUSSION REFERENCES

 
Subjects

Nine healthy subjects (mean age 45 ± 11 SD yr, six men and three women) familiar with cardiopulmonary exercise testing gave informed consent to participate in the study. Seven subjects had a body mass index (BMI) between 21 and 26 kg/m², and two were overweight (BMI of 28 and 30 kg/m²). All subjects were in good health and had no cardiac or respiratory abnormalities. The experimental protocol was approved by the Centro Cardiologico Monzino Human Subjects Committee.

Protocol

Two studies were performed on separate days with subjects in a resting, fasted state. After local injection of 0.5 ml of 2% lidocaine, a 3-Fr radial or brachial artery catheter was inserted by the Seldinger technique. On the saline infusion day, the subject remained at rest in the supine position for 30 min while receiving a 30 ml/kg intravenous infusion of normal saline. For the two overweight subjects, a saline dose appropriate for a BMI of 25 was used. On the alternate study day, the subject had an equivalent supine rest period. The day order of saline infusion was randomized among the subjects. Pulmonary function tests were completed immediately after the supine rest, followed by the incremental work exercise test.

Pulmonary Function Tests

Spirometry was performed with a SensorMedics 2200 Pulmonary Function Test System (SensorMedics, Yorba Linda, CA). The best of three measurements of FVC and FEV₁ were retained. Normal reference values for spirometry were those of Morris et al. (20). Diffusing capacity for CO (DL_CO) was measured by the single breath constant expiratory flow method (12), using 0.3% CO, 0.3% CH₄, 20% O₂, and balance N₂. For calculation of the DL_CO components, membrane diffusing capacity (Dm) and capillary volume (Vc) (29), two additional measurements were done with the same trace concentrations of CO and CH₄ but with 40% and 60% O₂. Lung volume (VA) was obtained as part of the single-breath DL_CO measurement.

Exercise Tests

Incremental work exercise tests were conducted on a cycle ergometer with the use of a SensorMedics Vmax 29C system (SensorMedics, Yorba Linda, CA). Ergometer power increments ranging between 20 and 30 W/min were selected on the basis of subject size and activity level, so that the exercise time from start of load to symptom-limited maximal effort would be 10 min. Identical power increments were applied to each subject for the control and postsaline exercise tests. Resting arterial blood samples were drawn with the subject seated on the cycle ergometer, breathing into the collection system. After a brief interval of unloaded pedaling, the selected ergometer load was initiated and exercise continued to maximal effort, defined as the highest power output attained before the subject was no longer able to sustain a pedal rate exceeding 50 rpm. Arterial blood samples were drawn at 2-min intervals beginning 2 min after the initiation of the loaded pedaling, with a final sample drawn at the maximal power output attained. Heart rate and breath-by-breath measurements of E, O₂ uptake (O₂), and CO₂ were recorded throughout the test. Anaerobic threshold was identified by concurrent judgment of two investigators primarily on the basis of V-slope analysis (3) confirmed by examination for increases in ventilatory equivalent for O₂ and end-tidal PO₂. Normal values for O_{2 max} were based on age, sex, and height (13).

Blood Gas Measurements

One-milliliter arterial blood samples were drawn in duplicate immediately after clearance of catheter dead space. A total of five or six paired samples were obtained from each subject. Measurements of arterial blood gases and hemoglobin concentration were taken with an ABL model 520 system (Radiometer, Copenhagen).

Data Reduction, Calculations, and Statistical Tests

The measurements taken during the final 20 s of exercise were averaged to define O_{2 max}, maximal ventilation, and maximal heart rate. Maximal power output was the highest value attained in the ramp test. For control and postsaline comparison of VT and RR responses, measurements were averaged for each complete minute of exercise. The E/CO₂ slope was calculated by linear regression on the breath-by-breath measurements of E and CO₂, beginning with the third minute of loaded exercise to the time where the subject's exercise end-tidal PCO₂ began to decrease, termed the end of the isocapnic buffering period (34). During that same exercise interval, breath-by-breath measurements of O₂, CO ₂, VT, and RR were plotted against exercise time for comparison of control and postsaline tests. The slope of breath-by-breath measurements of E plotted against exercise time was calculated from the third minute of loaded exercise to the onset of the anaerobic threshold, rather than the later-occurring end of the isocapnic buffering period.

Measurements of arterial PO₂, arterial PCO₂ (Pa_CO2), R (CO₂/O₂), and mixed expired CO₂ were used for standard calculations of A-aDO₂ and the Enghoff modification of the Bohr VD/VT. For gas-exchange calculations, the breath-by-breath measurements of R and mixed expired CO₂ were averaged for the 20-s period surrounding the time of arterial blood sampling. Because a slightly lower hemoglobin concentration was observed after the saline infusion, the postsaline O₂ pulse calculations (O_{2 max}/heart rate) were adjusted by the factor [maxHb(control)/maxHb(saline)], where maxHb is the Hb concentration at maximal effort, to compare potential alterations in stroke volume between studies. Paired t-tests were used for comparison of the blood gas, pulmonary function, and gas-exchange measurements in control and postsaline tests. P < 0.05 was considered statistically significant. Data are presented as means ± SD.

	RESULTS

TOP ABSTRACT METHODS RESULTS DISCUSSION REFERENCES

 
Pulmonary Function

Rapid saline infusion produced significant reductions in FVC, FEV₁, and VA (P < 0.01 for all), whereas Vc was moderately increased and no change was noted in either DL_CO or Dm (Table 1). Thus, although the spirometry changes are consistent with those described from previous studies of rapid saline infusion in normal subjects, the unchanged diffusing capacity measurements do not suggest the development of appreciable alveolar edema.

The infusion of saline consistently reduced the resting bicarbonate concentration (24.6 ± 1.2 to 22.3 ± 0.6 meq/l, P < 0.001) and the hemoglobin concentration (14.4 ± 0.8 to 13.9 ± 0.9 g/dl, P < 0.02). Assuming that the immediate dilution of bicarbonate reflected a change in the extracellular volume and the dilution of hemoglobin reflected intravascular volume, these proportional changes (after correction of bicarbonate to standard base excess) suggest an expansion of extracellular fluid volume by 12% and an expansion of intravascular volume by 3.5%. At rest, no subject reported symptoms attributable to the rapid saline infusion, although all felt more fatigued postsaline infusion at maximal effort. During exercise after saline infusion, some subjects noted a sensation of increased leg tightness with exercise, although no measurements were taken to objectively confirm a change in leg volume. The subjects also noted a postexercise delay of at least 1 h before any sensation of bladder fullness.

Response to Exercise

Ventilation and gas exchange.   Plots of the breath-by-breath measurements of E against CO₂ revealed a good linear fit (Fig. 1) up to the end of the isocapnic buffering period, with a mean correlation coefficient (r) for all subjects of 0.987 ± 0.007. All subjects increased the E/CO₂ slope after saline infusion (24.9 ± 2.4 to 28.0.2 ± 2.9 l/l, P < 0.0002, Fig. 2A). Exercise ventilation normalized by power output (E/W) also increased after saline infusion (0.262 ± 0.026 to 0.290 ± 0.031 l·min^–1·W^–1, P < 0.005, Fig. 2B). The pattern of increase in E among subjects was typical for the midexercise interval of a progressive work test, characterized by a relatively larger increase in VT than in RR. When we compared individual plots of VT against E for the control and saline tests, the postsaline measurements for seven of the nine subjects could be superimposed on the control curves (Fig. 3). All subjects showed higher E for any given power output after saline infusion, with seven subjects showing the same pattern of increase in VT and RR to achieve the higher ventilation (Fig. 3). Of the two remaining subjects, one showed a postsaline reduction in VT for a given E, and the other showed a postsaline increase in VT for a given E. Among all subjects, there was no difference between tests in CO₂ or O₂ at identical power outputs. In the portion of the exercise ventilation response used for calculation of the E/CO₂ slope, a mean 1.6 ± 2.5 Torr decrease in Pa_CO2 (P < 0.01) was noted in the postsaline infusion studies when all measurements during that interval were pooled, although the change did not attain significance at the 0.05 level for any single measurement time (Table 2). Mean maximal E was not significantly different after saline infusion (92.6 ± 20.3 vs. 85.8 ± 25.7 l/min, P not significant). Compared with control measurements, the postsaline tests had small reductions in Pa_CO2, pH, and HCO₃ throughout the midexercise period (Table 2). At maximal exercise no acid-base differences were significant. No significant differences in arterial PO₂, hemoglobin saturation, VD/VT, or A-aDO₂ were noted at any exercise stage (Table 2).

View larger version (16K): [in this window] [in a new window]   Fig. 1. Breath-by-breath measurements of minute ventilation (E) and CO2 production (CO2) for 1 subject during the control incremental exercise test () and postsaline infusion test ().

View larger version (17K): [in this window] [in a new window]   Fig. 2. A: increase in exercise E-to-CO2 ratio (E/CO2) after rapid intravenous infusion of saline (slope increased postsaline, P < 0.0002). B: increase in slope of E per watt after rapid saline infusion (slope increased postsaline, P < 0.005).

View larger version (12K): [in this window] [in a new window]   Fig. 3. Comparison of 1-min averaged ventilation measurements of tidal volume during control () and postsaline () exercise tests for a typical subject.

O_{2 max}.

View larger version (15K): [in this window] [in a new window]   Fig. 4. A: maximal O2 uptake (O2 max) at control and after rapid saline infusion. B: maximal exercise heart rate at control and after rapid saline infusion.

View larger version (20K): [in this window] [in a new window]   Fig. 5. Plot of heart rate and O2 consumption in a typical subject during control study () and after saline infusion ().

	DISCUSSION

TOP ABSTRACT METHODS RESULTS DISCUSSION REFERENCES

The subjects of the present study demonstrated a consistent increase in exercise ventilation at any exercise level after rapid saline infusion. For both our subjects and heart failure patients, an increased E/CO₂ slope could arise from any combination of three mechanisms: an increase in alveolar ventilation, an increase in VD/VT, or a reduction in CO₂ at any given power output. No change in either CO₂ production or VD/VT was observed, leaving an increase in alveolar ventilation as the sole mechanism to explain the increased E/CO₂ slope after saline infusion in our normal subjects. The observed response of these saline-infused normal subjects differs from that of previously described heart failure patients, in that the patients demonstrate both alveolar hyperventilation and abnormally elevated physiological dead space during exercise (22, 31, 33).

Thus the augmentation of exercise ventilation after saline infusion represented by the change in E/CO₂ slope reflects an increase in alveolar ventilation alone. This increase could arise as a consequence of two different mechanisms. First, a mild dilution acidosis was produced in all subjects after the rapid infusion of the large volume of bicarbonate-free solution, thus providing a stimulus to increase E. The average saline-induced 10% increase in E was associated with a mean 0.026 unit decrease in pH, although there was a range of response among our subjects (See Fig. 2). To confirm whether the increased ventilation was due to the metabolic acidosis alone, our same subjects would have to be restudied after induction of an equivalent degree of metabolic acidosis without volume expansion. A second potential mechanism to contribute to the observed respiratory alkalosis would be augmentation of E by edema-responsive neural afferent signals either from lung or from exercising muscle. In lung, the unmyelinated C fibers in airway mucosa respond to airway edema, triggering afferent ventilation stimuli in experimental animals (10). In muscle, Piepoli et al. (24) described an increased ventilation stimulus from forearm exercise in chronic heart failure patients, attributed to afferent signals from the muscle. More direct evidence of unmyelinated muscle afferent signals in response to vascular congestion has been described in experimental animals (11).

Although our intervention with rapid saline infusion induced changes in spirometry consistent with the presence of airway mucosal edema, eight of our nine normal subjects failed to demonstrate any decrease in exercise VT for a given E. There is no obvious explanation for the divergent changes noted in postsaline ventilation pattern for two of the subjects, but the remaining seven subjects had RR and V responses after saline that fit well to their respective control measurements. The increased E observed after saline infusion did not change the relationship between the RR and V. Gallagher et al. (8) noted a similar pattern of V preservation in ventilation exercise response when comparing normal subjects at a specified E with or without hypercapnia. Thus the reductions in exercise V manifested by heart failure patients may be more likely related to afferent signals responding to exercise-associated increases in left atrial pressure rather than an effect related to lung edema.

The consistent reductions in O_{2 max}, anaerobic threshold, and maximal exercise heart rate after rapid saline infusion were unexpected findings. The subjects had no knowledge of the subsequently discovered saline-induced reduction in exercise capacity during testing and appeared to give full equivalent efforts for both tests, findings supported by the observation of nonsignificant decreases in maximal exercise pH and bicarbonate during the postsaline maximal effort (Table 2). In addition, the consistent reduction in the anaerobic threshold after saline infusion provided additional support for the view that there was a true reduction in maximal exercise capacity. The subjects could not be blinded to the rapid saline infusion, but we were not aware of any subject concern that the intervention would limit maximal exercise performance.

Despite the reduction in expiratory flow rates after saline, there was no suggestion of a respiratory limitation to the maximal performance. Maximal exercise ventilation after saline was not different and was not associated with an increase in A-aDO₂ or Pa_CO2 at maximal exercise. Although a modest increase in the work of ventilation after saline infusion cannot be completely discounted, the exercise ventilation response did not manifest any of the findings of ventilation limitation that are ordinarily invoked to explain a reduction in maximal exercise performance. The mild metabolic acidosis itself could also be invoked as a potential cause of exercise limitation. Studies of maximal exercise capacity after induction of severe metabolic acidosis (standard base excess of –10 meq) have shown modest reductions in exercise time at maximal effort (14), but the mean pH reduction in the present study was far smaller. Nevertheless, this possibility cannot be completely excluded without repeat exercise tests on all subjects after induction of an equivalent mild metabolic acidosis without volume infusion.

If the observation of the lower postsaline maximal power output associated with a lower maximal heart rate cannot be ascribed to a ventilation limitation, acidosis, or reduced effort, a remaining issue for consideration would be impaired extraction of O₂ by the exercising muscle. Two mechanisms related to edema formation in exercising muscle could contribute to such a finding. First, if the edema fluid accumulating in the legs increased the intramuscular tissue pressure to a significant degree, maximal exercise perfusion of that muscle bed would be reduced. Williamson et al. (35) showed that subjects exercising with their legs enclosed in a pressurized chamber had a reduction in O_{2 max}, associated with alveolar hyperventilation. With application of external pressure to the legs, leg O₂ extraction was reduced simply because of reduced maximal blood flow to the exercising muscle. In the present study no measurement of an intramuscular pressure increase after saline infusion is available, but it is interesting to note that some subjects were aware of a sensation of leg tightness during the postsaline exercise test. A second potential mechanism of impaired maximal O₂ extraction is the development of a diffusion limitation secondary to accumulation of edema fluid between capillaries and the maximally recruited exercising muscle. An O₂ diffusion limitation within maximally exercising muscle has been proposed by Wagner (32) on the basis of measurements in normal subjects of femoral venous O₂ extraction during maximal exercise during differing degrees of arterial hypoxemia. On the basis of the assumptions of that model, any increase in diffusion distances secondary to edema fluid would be physiologically relevant. Two factors favor a disproportionate distribution of edema fluid to the exercising muscle of our subjects. First and most important, the stimulus of maximal exercise will redistribute almost 90% of the total cardiac output to the exercising muscle. Second, the infusion of a large volume of normal saline decreases the intravascular oncotic pressure and enhances the movement of saline from intravascular to extravascular spaces. The disproportionate size of the decrease in plasma bicarbonate after rapid saline infusion compared with the decrease in hemoglobin confirms that most of the saline went to the extravascular space soon after administration. By this increased capillary-myocyte diffusion distance hypothesis, the maximal O₂ extraction from the exercising muscle would be reduced, associated with a relatively higher venous O₂ exiting from exercising muscle. In contrast, the prediction from the increased intramuscular pressure hypothesis would be that there would be no difference between maximal exercise femoral venous O₂ extraction in control and postsaline infusion conditions.

The present findings in transiently fluid overloaded healthy subjects may offer an insight into chronic disease conditions with associated edema in which maximal exercise heart rate is decreased. Although the reduced maximal exercise heart rate of heart failure patients is most likely attributable to either myocardial or conducting system abnormalities, abnormalities of peripheral muscle function during exercise have also been postulated. In exercising heart failure patients, Koike et al. (16) described an end-exercise increase in femoral venous PO₂ for the most impaired subjects, suggesting an abnormality of muscle O₂ extraction. Wilson et al. (36) described a subset of heart failure patients with normal exercise leg blood flow at moderate exertion who nevertheless had abnormally elevated femoral venous lactate levels, again suggesting appropriate blood flow and impaired peripheral O₂ delivery. Chronic hemodialysis patients exercised on a nondialysis day (and hence mildly edematous) reproducibly demonstrated a reduced maximal exercise heart rate. When restudied after treatment with erythropoietin, there was an improvement in maximal exercise capacity but a significant additional decrease in maximal exercise heart rate, suggesting a primary abnormality of muscle O₂ extraction unrelated to O₂ delivery to exercising muscle (28). This postulate was confirmed by an exercise study of chronic hemodialysis patients investigating the effects of erythropoietin treatment on maximal femoral venous O₂ extraction (17). Those investigators found that erythropoietin treatment increased the maximal exercise femoral venous O₂ saturation of blood, compared with the preerythropoietin control exercise measurements, providing direct evidence for a muscle O₂ extraction abnormality in those patients.

In conclusion, the results of the present study of healthy subjects receiving an intravenous saline load and previous studies of patients with edematous conditions suggest that edema accumulation could impair maximal systemic O₂ extraction, related either to increased diffusion distances between the muscle microvasculature and myocytes and/or to the effects of an edema-mediated increase in intramuscular pressure. In addition, the rapid saline infusion protocol utilized in this study increased exercise alveolar ventilation, most likely in response to the mild dilution-induced acidosis, although contributing stimuli from edema-sensitive neural afferents in the lung or exercising extremities cannot be excluded.

	FOOTNOTES

 

Address for reprint requests and other correspondence: H. T. Robertson, Pulmonary and Critical Care Medicine, Box 356522, University Hospital, Seattle, WA 98195-6522 (E-mail: tomrobt{at}u.washington.edu).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

	REFERENCES

TOP ABSTRACT METHODS RESULTS DISCUSSION REFERENCES

 

1. Agostoni P, Pellegrino R, Conca C, Rodarte JR, and Brusasco V. Exercise hyperpnea in chronic heart failure: relationships to lung stiffness and expiratory flow limitation. J Appl Physiol 92: 1409–1416, 2002.[Abstract/Free Full Text]
2. Agostoni PG, Guazzi M, Bussotti M, Grazi M, Palermo P, and Marenzi G. Lack of improvement of lung diffusing capacity following fluid withdrawal by ultrafiltration in chronic heart failure. J Am Coll Cardiol 36: 1600–1604, 2000.[Abstract/Free Full Text]
3. Beaver WL, Wasserman K, and Whipp BJ. A new method for detecting anaerobic threshold by gas exchange. J Appl Physiol 60: 2020–2027, 1986.[Abstract/Free Full Text]
4. Chua TP, Ponikowski P, Harrington D, Anker SD, Webb-Peploe K, Clark AL, Poole-Wilson PA, and Coats AJ. Clinical correlates and prognostic significance of the ventilatory response to exercise in chronic heart failure. J Am Coll Cardiol 29: 1585–1590, 1997.[Abstract]
5. Clark AL, Chua TP, and Coats AJ. Anatomical dead space, ventilatory pattern, and exercise capacity in chronic heart failure. Br Heart J 74: 377–380, 1995.[Abstract/Free Full Text]
6. Crandall ED and Effros RM. Historical perspectives on lung edema clearance. J Appl Physiol 93: 1527–1532, 2002.[Abstract/Free Full Text]
7. Francis DP, Shamim W, Davies LC, Piepoli MF, Ponikowski P, Anker SD, and Coats AJ. Cardiopulmonary exercise testing for prognosis in chronic heart failure: continuous and independent prognostic value from VE/VCO(2)slope and peak VO(2). Eur Heart J 21: 154–161, 2000.[Abstract/Free Full Text]
8. Gallagher CG, Brown E, and Younes M. Breathing pattern during maximal exercise and during submaximal exercise with hypercapnia. J Appl Physiol 63: 238–244, 1987.[Abstract/Free Full Text]
9. Guazzi M, Agostoni P, Bussotti M, and Guazzi MD. Impeded alveolar-capillary gas transfer with saline infusion in heart failure. Hypertension 34: 1202–1207, 1999.[Abstract/Free Full Text]
10. Gunawardena S, Ravi K, Longhurst JC, Kaufman MP, Ma A, Bravo M, and Kappagoda CT. Responses of C fiber afferents of the rabbit airways and lungs to changes in extra-vascular fluid volume. Respir Physiol Neurobiol 132: 239–251, 2002.[CrossRef][ISI][Medline]
11. Haouzi P, Hill JM, Lewis BK, and Kaufman MP. Responses of group III and IV muscle afferents to distension of the peripheral vascular bed. J Appl Physiol 87: 545–553, 1999.[Abstract/Free Full Text]
12. Huang YC, Helms MJ, and MacIntyre NR. Normal values for single exhalation diffusing capacity and pulmonary capillary blood flow in sitting, supine positions, and during mild exercise. Chest 105: 501–508, 1994.[Medline]
13. Jones NL, Makrides L, Hitchcock C, Chypchar T, and McCartney N. Normal standards for an incremental progressive cycle ergometer test. Am Rev Respir Dis 131: 700–708, 1985.[ISI][Medline]
14. Jones NL, Sutton JR, Taylor R, and Toews CJ. Effect of pH on cardiorespiratory and metabolic responses to exercise. J Appl Physiol 43: 959–964, 1977.[Abstract/Free Full Text]
15. Kleber FX, Vietzke G, Wernecke KD, Bauer U, Opitz C, Wensel R, Sperfeld A, and Glaser S. Impairment of ventilatory efficiency in heart failure: prognostic impact. Circulation 101: 2803–2809, 2000.[Abstract/Free Full Text]
16. Koike A, Wasserman K, Taniguchi K, Hiroe M, and Marumo F. Critical capillary oxygen partial pressure and lactate threshold in patients with cardiovascular disease. J Am Coll Cardiol 23: 1644–1650, 1994.[Abstract]
17. Marrades RM, Roca J, Campistol JM, Diaz O, Barbera JA, Torregrosa JV, Masclans JR, Cobos A, Rodriguez-Roisin R, and Wagner PD. Effects of erythropoietin on muscle O₂ transport during exercise in patients with chronic renal failure. J Clin Invest 97: 2092–2100, 1996.[ISI][Medline]
18. Matthay MA, Folkesson HG, and Clerici C. Lung epithelial fluid transport and the resolution of pulmonary edema. Physiol Rev 82: 569–600, 2002.[Abstract/Free Full Text]
19. Mead J, Takishima T, and Leith D. Stress distribution in lungs: a model of pulmonary elasticity. J Appl Physiol 28: 596–608, 1970.[Free Full Text]
20. Morris JF, Koski A, and Johnson LC. Spirometric standards for healthy nonsmoking adults. Am Rev Respir Dis 103: 57–67, 1971.[ISI][Medline]
21. Myers J, Gullestad L, Vagelos R, Do D, Bellin D, Ross H, and Fowler MB. Clinical, hemodynamic, and cardiopulmonary exercise test determinants of survival in patients referred for evaluation of heart failure. Ann Intern Med 129: 286–293, 1998.[Abstract/Free Full Text]
22. Myers J, Salleh A, Buchanan N, Smith D, Neutel J, Bowes E, and Froelicher VF. Ventilatory mechanisms of exercise intolerance in chronic heart failure. Am Heart J 124: 710–719, 1992.[CrossRef][ISI][Medline]
23. Pellegrino R, Dellaca R, Macklem PT, Aliverti A, Bertini S, Lotti P, Agostoni P, Locatelli A, and Brusasco V. Effects of rapid saline infusion on lung mechanics and airway responsiveness in humans. J Appl Physiol 95: 728–734, 2003.[Abstract/Free Full Text]
24. Piepoli M, Clark AL, Volterrani M, Adamopoulos S, Sleight P, and Coats AJ. Contribution of muscle afferents to the hemodynamic, autonomic, and ventilatory responses to exercise in patients with chronic heart failure: effects of physical training. Circulation 93: 940–952, 1996.[Abstract/Free Full Text]
25. Ponikowski P, Francis DP, Piepoli MF, Davies LC, Chua TP, Davos CH, Florea V, Banasiak W, Poole-Wilson PA, Coats AJ, and Anker SD. Enhanced ventilatory response to exercise in patients with chronic heart failure and preserved exercise tolerance: marker of abnormal cardiorespiratory reflex control and predictor of poor prognosis. Circulation 103: 967–972, 2001.[Abstract/Free Full Text]
26. Puri S, Baker BL, Oakley CM, Hughes JM, and Cleland JG. Increased alveolar/capillary membrane resistance to gas transfer in patients with chronic heart failure. Br Heart J 72: 140–144, 1994.[Abstract/Free Full Text]
27. Puri S, Dutka DP, Baker BL, Hughes JM, and Cleland JG. Acute saline infusion reduces alveolar-capillary membrane conductance and increases airflow obstruction in patients with left ventricular dysfunction. Circulation 99: 1190–1196, 1999.[Abstract/Free Full Text]
28. Robertson HT, Haley NR, Guthrie M, Cardenas D, Eschbach JW, and Adamson JW. Recombinant erythropoietin improves exercise capacity in anemic hemodialysis patients. Am J Kidney Dis 15: 325–332, 1990.[ISI][Medline]
29. Roughton FJ and Forster RE. Relative importance of diffusion and chemical reaction rates in determining rate of exchange of gases in the human lung, with special reference to true diffusing capacity of pulmonary membrane and volume of blood in the lung capillaries. J Appl Physiol 11: 290–302, 1957.[Abstract/Free Full Text]
30. Staub NC. Pulmonary edema. Physiol Rev 54: 678–811, 1974.[Free Full Text]
31. Sullivan MJ, Higginbotham MB, and Cobb FR. Increased exercise ventilation in patients with chronic heart failure: intact ventilatory control despite hemodynamic and pulmonary abnormalities. Circulation 77: 552–559, 1988.[Abstract/Free Full Text]
32. Wagner PD. Diffusive resistance to O₂ transport in muscle. Acta Physiol Scand 168: 609–614, 2000.[CrossRef][ISI][Medline]
33. Wasserman K, Zhang YY, Gitt A, Belardinelli R, Koike A, Lubarsky L, and Agostoni PG. Lung function and exercise gas exchange in chronic heart failure. Circulation 96: 2221–2227, 1997.[Abstract/Free Full Text]
34. Whipp BJ, Davis JA, and Wasserman K. Ventilatory control of the 'isocapnic buffering' region in rapidly-incremental exercise. Respir Physiol 76: 357–367, 1989.[CrossRef][ISI][Medline]
35. Williamson JW, Raven PB, Foresman BH, and Whipp BJ. Evidence for an intramuscular ventilatory stimulus during dynamic exercise in man. Respir Physiol 94: 121–135, 1993.[CrossRef][ISI][Medline]
36. Wilson JR, Mancini DM, and Dunkman WB. Exertional fatigue due to skeletal muscle dysfunction in patients with heart failure. Circulation 87: 470–475, 1993.[Abstract/Free Full Text]

This article has been cited by other articles:

				E. M. Snyder, K. C. Beck, S. T. Turner, E. A. Hoffman, M. J. Joyner, and B. D. Johnson Genetic variation of the beta2-adrenergic receptor is associated with differences in lung fluid accumulation in humans J Appl Physiol, June 1, 2007; 102(6): 2172 - 2178. [Abstract] [Full Text] [PDF]

				M. K. Stickland, R. C. Welsh, M. J. Haykowsky, S. R. Petersen, W. D. Anderson, D. A. Taylor, M. Bouffard, and R. L. Jones Effect of acute increases in pulmonary vascular pressures on exercise pulmonary gas exchange J Appl Physiol, June 1, 2006; 100(6): 1910 - 1917. [Abstract] [Full Text] [PDF]

This Article Abstract Full Text (PDF) Free All Versions of this Article: 97/2/697    most recent 00108.2004v1 Submit a response Alert me when this article is cited Alert me when eLetters are posted Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in ISI Web of Science Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via ISI Web of Science (8) Citing Articles via Google Scholar Google Scholar Articles by Robertson, H. T. Articles by Agostoni, P. Search for Related Content PubMed PubMed Citation Articles by Robertson, H. T. Articles by Agostoni, P.