Exercise testing in pulmonary arterial hypertension and in chronic heart failure

G. Deboeck, G. Niset, M. Lamotte, J‐L. Vachiéry, R. Naeije
European Respiratory Journal 2004 23: 747-751; DOI: 10.1183/09031936.04.00111904

Abstract

Exercise capacity is reduced in pulmonary arterial hypertension and in chronic left heart failure, but it is not known whether the cardiopulmonary exercise testing profile is different in the two conditions at the same severity of functional limitation.

Nineteen patients with pulmonary arterial hypertension and 19 with chronic heart failure underwent a 6‐min walk test and symptom-limited maximal incremental cycle ergometry.

The patients with pulmonary arterial hypertension and chronic heart failure did not differ in New York Heart Association Functional Class (mean±sem 2.8±0.1 versus 2.8±0.2), 6‐min walking distance (395±30 versus 419±20 m), peak work-rate, oxygen consumption, ventilation and cardiac frequency. However, patients with pulmonary arterial hypertension exhibited higher dyspnoea scores (5.8±0.6 versus 3.8±0.5) higher ventilatory equivalents for carbon dioxide (58±3 versus 44±3 at the anaerobic threshold) and lower peak oxygen pulse (5.9±0.4 versus 8.7±0.5 mL·beat−1, or 53±4 versus 64±4% of the predicted value).

It is concluded that the cardiopulmonary exercise testing profile in pulmonary arterial hypertension differs from that in chronic heart failure by showing more dyspnoea at comparable work-rates, related to greater reductions in ventilatory efficiency and stroke volume.

This study was supported by grant number 3.4567.00 from the Scientific Medical Research Funds and by the Foundation for Cardiac Surgery (both Brussels, Belgium).

Primary pulmonary hypertension (PPH) is a disease entity of dyspnoea, fatigue, chest pain and syncope defined by an increase in pulmonary arterial pressures and the absence of causal cardiac or pulmonary disease 1. The condition evolves over years, with prominent exercise-induced symptoms, due to the inability of the overloaded right ventricle to perfuse the lungs and to adapt systemic oxygen delivery to peripheral tissue oxygen demand. Accordingly, PPH patients present with reductions in peak oxygen uptake, anaerobic threshold, oxygen pulse, ventilatory efficiency and 6‐min walking distance 27, which have been found to be correlated with New York Heart Association Functional Class (NYHAFC) and survival better than with resting pulmonary haemodynamic measurements 6, 7. These concepts probably apply to pulmonary arterial hypertension (PAH) defined as PPH with identifiable associated conditions 8.

Chronic heart failure (CHF) is characterised by impairment of cardiac output adaptation to peripheral oxygen requirements, and also results in altered cardiopulmonary exercise testing variables and decreased 6‐min walking distances, which correlate better with NYHAFC and prognosis than with resting invasive or noninvasive measurements of cardiac function 913.

It was, therefore, questioned what the differences in exercise testing variables in CHF and in PAH patients evaluated at the same severity of functional limitation might be. For this purpose, incremental cycle cardiopulmonary exercise testing and 6‐min walking distance measurements were performed in PAH and CHF patients of comparable NYHAFC.

Methods

Patients

Thirty-eight patients were included in the study, which was approved by the Ethical Committee of Erasme University Hospital. Nineteen patients, 11 females and eight males, aged 23–66 yrs (mean 49 yrs), presented with PAH, defined by an increase in pulmonary artery pressures, normal pulmonary artery wedge pressure, no identifiable cardiac or pulmonary cause 1, and possibly association with conditions such as appetite suppressant intake, connective tissue disease, liver cirrhosis, human immunodeficiency virus infection and congenital left-to-right shunt 8. Fifteen of the PAH patients had pure PPH, and four PPH with associated conditions, which were previous intake of fenfluramines in two and connective tissue disease without significant lung function impairment in two. Absence of intrinsic left ventricular disease was checked by echocardiography. Six of the PAH patients were in NYHAFC II, 12 in NYHAFC III and one in NYHAFC IV. Nineteen patients, three females and 16 males, aged 50–70 yrs (mean 58 yrs), presented with CHF, defined by the syndrome of dyspnoea, fatigue and oedema related to altered left ventricular function, with echocardiographic left ventricular ejection fractions ranging 14–45% (mean±sem 27±11%). The cause of left ventricular failure was ischaemic cardiomyopathy in 13 of the patients and dilated idiopathic cardiomyopathy in the others. Seven of the CHF patients were in NYHAFC II, eight in NYHAFC III and four in NYHAFC IV.

Patients were included in the study if: 1) they had been clinically stable during the preceding month, 2) they were in NYHAFC II, III or IV, and 3) they were able to perform cycle ergometer exercise testing. The inclusions were consecutive, and with prior knowledge that approximately two-thirds of the patients would be in NYHAFC III and the others in NYHAFC II, resulting in a mean 6-min walking distance of ∼400 m.

Right heart catheterisation had been performed during the preceding month in 24 of the patients. In the PAH patients (n=17), mean pulmonary artery pressure was 47±3 mmHg, pulmonary artery wedge pressure 11±2 mmHg and cardiac index 2.1±0.1 L·min−1·m−2. In the CHF patients (n=7), mean pulmonary artery pressure was 32±6 mmHg, pulmonary artery wedge pressure 23±4 mmHg and cardiac index 1.9±0.2 L·min−1·m−2. Three of the PAH patients showed echocardiographic evidence of a patent foramen ovale and right-to-left shunting.

The PAH patients were treated with anticoagulants (n=19); calcium channel blockers (n=5); diuretics (n=15); oral, subcutaneous or intravenous prostacyclin derivatives (n=14); and the mixed endothelin receptor antagonist bosentan (n=2). The CHF patients were treated with diuretics (n=17), angiotensin-converting enzyme inhibitors or angiotensin II receptor antagonists (n=14), β-blockers (n=16) and nitrates (n=10).

Six-minute walk test

Measurement of the distance walked in 6 min was performed in all the patients according to a standardised protocol 14. The patients were instructed to walk back and forth at their own pace in a 35‐m corridor in order to cover as much ground as possible in the allotted time. A research assistant supervised the test, telling the patient the remaining exercise time every 2 min. The patients were allowed to stop and take a rest during the test, but were instructed to resume walking as soon as possible. In order to control for the learning effect, each patient underwent at least two tests on at least two separate days, and the final performance was used as the measure of walking ability. Pulse oximetric arterial oxygen saturation (Sp,O2) was measured using a Nonin 8500 M device (Nonin Medical, Minneapolis, MN, USA). Dyspnoea during the test was evaluated using the modified Borg dyspnoea score 15.

Cardiopulmonary exercise test

Each patient underwent physician-supervised standard incremental cardiopulmonary exercise testing until the symptom-limited maximum 16. The work-rate was increased by 10 W·min−1, after pedalling for 1 min at 0 W. The patients were instructed to stop exercising immediately if they felt dizziness or chest pain. Breath-by-breath ventilation, oxygen and carbon dioxide concentrations, and the derived minute ventilation, oxygen consumption (V'O2) and carbon dioxide production (V'CO2) were determined using the Cardiopulmonary Exercise System CPX/D (Medical Graphics, St Paul, MN, USA). Cardiac frequency was measured using a continuously monitored electrocardiograph. Blood pressure was measured at the end of each workload increment using an automatic sphygmomanometer. Peak V'O2 was defined as the V'O2 measured during the last 30 s of peak exercise. Oxygen pulse was calculated by dividing V'O2 by cardiac frequency. The anaerobic threshold was detected using the V-slope method 16. The ventilatory equivalent for carbon dioxide was measured by dividing ventilation by V'CO2 at baseline, at the anaerobic threshold and at peak V'O2. Work efficiency above the anaerobic threshold was calculated by the ratio of change in V'O2 per unit increase in work-rate (ΔV'O2/Δwork-rate) 16.

Statistics

Data are presented as mean±sem. Comparisons between the PAH and CHF groups were made by unpaired t-test. Correlations were calculated using linear regression analysis 17.

Results

The CHF patients were older than the PAH patients, and were more often male, but the two groups were otherwise well matched in height, weight, resting cardiac frequency, blood pressure, NYHAFC and 6‐min walking distance. The PAH patients exhibited a slightly but significantly lower Sp,O2 at rest and exercise-induced hypoxaemia (table 1).

View this table:
Table 1—

Anthropometric data and functional state of pulmonary arterial hypertension (PAH) and chronic heart failure (CHF) patients

As summarised in table 2, both PAH and CHF patients presented with lower-than-normal work-rate, V'O2, oxygen pulse, ventilation and cardiac frequency at peak exercise. Both PAH and CHF patients also had a lower-than-normal anaerobic threshold (absolute or percentage of the predicted value), ΔV'O2/Δwork-rate above the anaerobic threshold and cardiac frequency recovery. The peak respiratory exchange rate was within the limits of normal. Resting ventilation, anaerobic threshold (expressed as a percentage of peak V'O2) and ventilatory equivalents were higher than normal.

View this table:
Table 2—

Cardiopulmonary exercise testing variables in pulmonary arterial hypertension (PAH) and chronic heart failure (CHF) patients

The PAH and CHF patients did not differ in work-rate (% pred), peak V'O2 (% pred), anaerobic threshold, peak respiratory exchange rate, peak ventilation, peak cardiac frequency and cardiac frequency recovery. However, CHF patients achieved higher absolute peak work-rate and peak V'O2, and PAH patients showed higher dyspnoea scores, ventilation and ventilatory equivalents, and lower maximum oxygen pulse and ΔV'O2/Δwork-rate above the anaerobic threshold. Ventilatory equivalents were on average higher in PAH patients at rest, at the anaerobic threshold and at peak V'O2 (fig. 1). Marked decreases in peak oxygen pulse were observed in both PAH and CHF patients (fig. 2).

Fig. 1.—
Fig. 1.—

Ventilatory equivalent for carbon dioxide (V'E/V'CO2) at rest, at the anaerobic threshold (AT) and at maximal (peak) exercise intensity in patients with pulmonary arterial hypertension (PAH; ♦) and in patients with chronic heart failure (CHF; ⋄). Horizontal bars represent means. **: p<0.01; ***: p<0.001.

Fig. 2.—
Fig. 2.—

Peak oxygen pulse in patients with pulmonary arterial hypertension (PAH) and in patients with chronic heart failure (CHF). Horizontal bars represent means. ***: p<0.001.

The 6‐min walking distance correlated with peak V'O2, NYHAFC, peak work-rate and ventilatory equivalents in both PAH and CHF patients (table 3). The 6‐min walking distance correlated less consistently with the anaerobic threshold, depending on whether it was expressed in absolute terms or relative to peak V'O2, and correlated with peak oxygen pulse in PAH but not CHF patients.

View this table:
Table 3—

Correlation coefficients for the relationship between the 6‐min walking distance and cardiopulmonary exercise test variables in pulmonary arterial hypertension (PAH) and chronic heart failure (CHF) patients

Discussion

The present results reveal that cardiopulmonary exercise testing in PAH and CHF patients at the same functional capacity, as graded by NYHAFC and distance walked in 6 min, shows similarly reduced peak work-rate and V'O2, with an early anaerobic threshold, and increased ventilatory equivalents. However, at a given level of exercise, the PAH patients appear to be more dyspnoeic in relation to more reduced ventilatory efficiency and stroke volume as assessed by higher ventilatory equivalent for carbon dioxide and lower oxygen pulse.

Previous studies have shown that advanced PAH and CHF are both characterised by decreased peak work-rate, peak V'O2, V'O2 at the anaerobic threshold and peak oxygen pulse, and increased ventilatory equivalents 27, 913. In the present patients, the anaerobic threshold occurred at a higher percentage of peak V'O2 than in normal subjects. This has been previously noted in PPH 4, CHF 19 and older patients with various diseases associated with a decrease in peak V'O2 20. It may be explained by the slower rise in V'O2 above the anaerobic threshold and by the fact that resting V'O2 already represents a considerable proportion of peak V'O2 4. It is also possible that, in these patients, many daily activities are frequently performed above the anaerobic threshold, with a corresponding endurance training effect.

Both the PAH and CHF patients presented with a decreased V'O2/work-rate relationship above the anaerobic threshold. This effect, which was more pronounced in the PAH patients, has been previously reported in patients with ischaemic heart disease 21 and PPH 4. This may be explained by cardiac output limitation, as also suggested by marked decreases in peak oxygen pulse and peak cardiac frequency in the present patients. An alteration in peripheral tissue oxygen extraction is less likely, since very low mixed venous blood oxygenation during exercise is known to occur in both PPH and CHF.

A decreased chronotropic response was observed in both the PAH and CHF patients. Although this is classically described in CHF 22, it has only been reported in one other study on PPH patients 4. Chronotropic incompetence in CHF is believed to be due to downregulation of β-adrenoreceptors 22. The same explanation may hold true in PAH patients, in whom downregulation of right ventricular myocardial β-adrenoreceptors has also been reported 23. It should, however, be noted that the decrease in chronotropic response appeared less important in the present PAH patients (p=0.06). This may be related to an additional contribution of β-blocker therapy in 16 of the 19 CHF patients.

Abnormal cardiac frequency recovery immediately after completion of an exercise test has recently been shown by several studies to be associated with decreased survival in patients with coronary artery disease, with or without β-blocker therapy, and whether or not the exercise is followed by a cooling-down period 18. The limits of normal post-exercise cardiac frequency recovery remain somewhat arbitrary as 12 beats·min−1 18 and even 18 beats·min−1 24 have been proposed. In the face of these limits of normal, it appears that both the present PAH and CHF patients frequently exhibited an abnormally prolonged cardiac frequency recovery. The mechanisms of prolonged cardiac frequency recovery after exercise in cardiac patients remain incompletely understood 13.

In the present study, the peak oxygen pulse was lower in PAH than in CHF patients, with a tendency towards higher peak cardiac frequency. This could account for the relatively lower absolute value of peak V'O2 due to inability to increase cardiac output, as also suggested by the lower ΔV'O2/Δwork-rate above the anaerobic threshold. In PAH, the excessively afterloaded right ventricle may partially adapt by a relative decrease in stroke volume at a given mean flow output, which decreases the pulsatile component of ventricular hydraulic work 25. However, β-blocker therapy in CHF patients could also explain the relatively larger oxygen pulses.

Although absolute values of peak V'O2 and work-rate were higher in the CHF patients, peak V'O2 and work-rate expressed as a percentage of the predicted value were not different in the two study groups. This may, in part, be explained by the fact that the prediction equations include sex corrections. It is known that, everything else being equal, V'O2 and work-rate achieved are lower in females 16. Peak oxygen pulse is also lower in females 16, but remained lower when expressed as a percentage of the predicted value in the PAH compared to the CHF patients in the current study. The sex distributions in the present PAH and CHF groups were typical of these respective disease entities, with relatively more females and males respectively.

Peak ventilation was markedly decreased in both the PAH and CHF patients. However, ventilatory equivalents were abnormally increased, and this was more pronounced in the PAH patients. An increased ventilatory equivalent is a marker of poor prognosis in both PPH 6 and CHF 11. Increased ventilatory equivalents at exercise in CHF have been explained by a combination of increased dead space related to low cardiac output, early lactic acidosis 9 and increased chemosensitivity in the context of increased sympathetic nervous system tone 26. Additional factors in PAH could include a greater increase in physiological dead space because of pulmonary vascular obliteration, and hypoxaemia on right-to-left shunting through a patent foramen ovale 25, 27. The present PAH patients exhibited a slightly lower Sp,O2 at rest, and presented with exercise-induced hypoxaemia, which probably contributed to increase ventilatory equivalents and dyspnoea score. An increase in physiological dead space is a probable explanation. Previous studies on pulmonary gas exchange using the multiple inert gas elimination technique in patients with either primary or thromboembolic pulmonary hypertension showed only mild ventilation/perfusion (V'/Q') inequality limited to lower-than-normal-V'/Q' regions, with no high V'/Q' modes and no increase in dead space 2729. Exercise, in these studies, did not alter V'/Q' distributions, and, in particular, was shown not to be associated with an abnormal increase in dead space 29.

The 6‐min walk test is a submaximal exercise test that is frequently used to assess the functional status of cardiac and pulmonary patients. It is safe, easy to perform, inexpensive, highly reproducible, sensitive to therapeutic interventions and gives a good indication of the ability to perform daily life activities 30. Being a submaximal exercise test, the results correlated moderately with peak V'O2 and other cardiopulmonary exercise testing variables. The correlation coefficients for the relationship between the 6‐min walking distance and peak V'O2 range 0.51–0.71 in CHF 30, and have been reported to amount to 0.7 in PPH 7. Similar correlations were found in the present study. It must be emphasised that the 6‐min walk test did not appear to discriminate between PAH and CHF patients of the same functional class who presented with marked differences in cardiorespiratory adaptation to exercise pathophysiology that were disclosed by cardiopulmonary exercise testing.

In summary, pulmonary arterial hypertension patients exercise with relatively higher ventilatory equivalents and lower oxygen pulses than CHF patients, but otherwise present with similarly altered cardiopulmonary exercise test results. These differences might be explained by both relatively more altered right ventricular function and altered gas exchange in the high ventilation/perfusion regions of the lung, but more altered autonomic nervous system tone could also be involved.

Acknowledgments

M-T. Gautier and P. Jespers helped in the preparation of this report.

  • Received October 7, 2003.
  • Accepted December 11, 2003.

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Exercise testing in pulmonary arterial hypertension and in chronic heart failure
G. Deboeck, G. Niset, M. Lamotte, J‐L. Vachiéry, R. Naeije
European Respiratory Journal May 2004, 23 (5) 747-751; DOI: 10.1183/09031936.04.00111904
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