A step test to assess exercise-related oxygen desaturation in interstitial lung disease

Subjects

For participation in the present study, subjects (n = 45) were initially recruited from the ILD outpatient clinic of the hospital. Clinical and functional stability was confirmed by the absence of change in medication dosage and forced vital capacity (FVC) values (±5%) in the preceding 3 months. Inclusion criteria were as follows: 1) presence of diffuse interstitial infiltrate on high-resolution computed tomography with evidence of pulmonary fibrosis; 2) forced expiratory volume in one second/FVC >70% with reduced FVC (below the lower limit of normality) and/or decreased single-breath diffusing capacity of the lung for carbon monoxide (D_L,CO); and 3) resting arterial oxygen saturation measured by pulse oximetry (S_p,O2; Biox 3740; Ohmeda, Boulder, CO, USA) ≥90% in room air. None of the subjects were receiving long-term oxygen therapy.

During the study, 14 patients were excluded due to respiratory infections or exacerbation of the underlying disease. The final sample comprised 31 patients (19 males, aged 34–79 yrs), 25 with idiopathic pulmonary fibrosis (IPF) and six with biopsy-proven chronic hypersensitivity pneumonia. A total of 14 (56%) patients with IPF underwent open lung biopsy and presented with the pattern of usual interstitial pneumonia. Diagnosis of IPF in the remaining patients was performed according to the clinical criteria suggested by the American Thoracic Society (ATS)/European Respiratory Society 11. All subjects gave written informed consent, which was previously approved by the institutional medical ethics committee.

Study design

All patients initially rated their level of chronic breathlessness (baseline dyspnoea index (BDI)) 12 and underwent ramp-incremental cycle ergometer cardiopulmonary exercise testing (CPET_max). After a resting period (1 h), patients performed a 6MST with metabolic and ventilatory measurements. On another day (48 h apart), patients underwent a constant work-rate (WR) test (CPET_submax) at the same metabolic stress, i.e. at the same pulmonary oxygen uptake (V′_O2), of the 6MST. After 1 h, the 6MST was repeated.

Measurements

Data analysis

Data are presented as mean±sd or median (range) for variables with parametric and nonparametric distributions, respectively. One-way ANOVA (with post hoc Bonferroni) or Friedman’s test were used to evaluate differences among the tests. Pearson’s product-moment coefficients assessed linear association. Agreement between 6MST replicates or between test modalities was evaluated by the Bland–Altman procedure. Chi-squared (Fisher exact) test was used to evaluate the association between categorical data. Backward stepwise multiple regression analysis was used to determine the resting predictors of the number of steps climbed in the 6MST. The probability of a type I error was set at 5% (p<0.05).

Sample characteristics

On average, patients presented with mild-to-moderate restrictive dysfunction with low D_L,CO values, which were typically proportional to the level of lung volume reduction (table 1⇓). As expected, peak aerobic capacity was reduced as compared with the predicted values (peak V′_O2 = 69.9±14.9% predicted), with 25 out of 31 patients presenting with peak V′_O2 values below the lower limit of normality.

Reproducibility of the step tests

All patients were able to successfully complete the step tests without complications; supplemental oxygen was not needed in any patient. Two patients, however, showed very low levels of S_p,O2 (slightly <80%; fig. 1⇓) Supplemental oxygen was not administered as these patients did not present intense dyspnoea and the ECG tracing was within normal limits (see Methods and materials section). There were no significant between-test differences on the total number of steps climbed and the rate of climbing: mean bias±95% confidence interval (CI) of the differences was 1.1±1.5 and 1.3±2.0 steps·min^-1, respectively. Similarly, f_C, V′_O2, S_p,O2 and V′_E did not differ between the tests more than ±5 beats·min^-1, ±50 mL, ±1.5% and ±7 L·min^-1, respectively (p>0.05).

• Download figure
• Open in new tab
• Download powerpoint

Fig. 1—

A Bland–Altman plot of the between-test differences on the nadir of arterial oxygen saturation measured by pulse oximetry (S_p,O2) in patients with interstitial lung disease. The 95% confidence intervals for the 6-min step test submaximal cardiopulmonary exercise test differences (6MST CPET_submax; ○) were smaller than those found for 6MST maximal CPET (CPET_max; •). ———: mean bias±1.96sd for 6MST CPET_max data; – – –: mean bias±1.96sd for 6MST CPET_submax data.

Exercise-related desaturation

There were no significant differences among the tests in relation to presence and severity of ERD (table 2⇓). As shown in figure 1⇑, mean bias±95% CI of the S_p,O2 differences between 6MST CPET_max and CPET_submax were -1.8±4.0 and -0.3±3.2%, respectively. In total, 25 patients had significant ERD (ΔS_p,O2 ≥4%) during the CPET_max. Of these, 24 also presented ERD in response to the 6MST (p<0.05). Similarly, 25 out of 26 patients who presented with ERD during the CPET_submax showed significant desaturation in response to stepping (p<0.05; table 3⇓). Interestingly, however, four patients had ERD in response to 6MST but not in the CPET_max. Of these, three also did not desaturate in the CPET_submax. Similarly, although there was a significant between-test association in relation to ERD severity, some patients desaturated below 88% only in response to the 6MST (table 3⇓). There was a significant correlation between ΔS_p,O2 with V′_O2 achieved in the 6MST (r = 0.78; p<0.01).

Physiological responses to stepping and cycling

Stepping was associated with a near-maximum metabolic stress as compared with CPET_max (table 2⇑). As shown in figure 2⇓, mean bias±95% CI of the between-test peak V′_O2 differences was only -60±115 mL·min^-1. Importantly, the total number of steps climbed was significantly related to both peak V′_O2 in the CPET_max and BDI (r = 0.52 and 0.55, respectively; p<0.05).

• Download figure
• Open in new tab
• Download powerpoint

Fig. 2—

The 6-min step test (6MST) was related to a near-maximum metabolic stress as compared with maximal cardiopulmonary exercise tests: a) oxygen uptake (V′_O2) values were close to the line of identity; and b) a Bland–Altman analysis revealed a narrow 95% confidence interval for the between-test differences. ———: mean bias±1.96sd.

No significant differences in the physiological adjustments were found between 6MST and CPET_submax tests (at same V′_O2; table 2⇑). However, there was a trend for higher V′_CO2/V′_O2 and V′_E/V′_O2 values during cycling as compared with stepping, i.e. V′_CO2 values tended to be higher at same metabolic demand during CPET_submax than stepping (table 2⇑).

Determinants of performance in the 6MST

In the present study, the physiological determinants of the exercise capacity in the 6MST (number of steps climbed) were also analysed. In a similar manner to other tests of functional capacity in ILD patients 19, D_L,CO (% pred) and alveolar–arterial oxygen tension difference (P_A–a,O2) were found to account for 40% (R² = 0.40) of the variability in this outcome after a multiple regression analysis:

Number of steps in the 6MST = (0.59×D_L,CO)–(0.88×P_A–a,O2 in mmHg)+90.8 (4)

Stepping as an ergometric modality

The present study seems to constitute the first published investigation of the prospective validation of a step test in patients with fibrotic ILD. It was found that between-day reproducibility of the 6MST was very high (table 2⇑). This was true not only for the physiological variables but also for the total “work” performed (as estimated by the number of steps climbed) and the rate of climbing. In this context, it could be hypothesised that, owing to the repetitive nature of the exercise movements, the patients tended to adopt a relatively constant rate of climbing throughout the test. Intra-individual variability of a number of physiological variables (f_C, V′_O2, S_p,O2 and V′_E) were also quite low and they compare well to those described in response to more traditional exercise tests in these patients 19. An important aspect was the use of a single 20-cm step: lower steps may provide insufficient metabolic stress (i.e. the subjects would need to climb up faster, increasing the risk of falls) 4, 5 and higher steps would prove too difficult to climb for older subjects with knee and hip problems.

The rationale for using a 6-min test was based on the well-validated 6MWT. It could be speculated, however, that a shorter test would improve patients’ compliance and test safety. As mentioned, the rate of stepping was remarkably constant in all patients (table 2⇑), suggesting that a 2–3-min test would also provide a reasonable estimate of exercise capacity 7. Nevertheless, it is possible that peak V′_O2 was underestimated in these patients, especially considering ILD patients may present with very slow V′_O2 kinetics during exercise 20. In addition, the nadir of S_p,O2 could not be reached in a test shorter than 6 min in duration, as ERD was significantly related to V′_O2 at exercise cessation, which has been found to increase progressively during the test (data not shown). Future studies are therefore needed to evaluate whether shorter step tests 7, even those using a different number of steps, are also clinically useful in the patient population.

Clinical implications

Abnormal gas exchange (hypoxaemia and increased alveolar–arterial gradient) plays a central role in limiting maximal exercise capacity in patients with ILD. In addition, ERD has been associated with health-related quality of life 21, pulmonary hypertension 22 and survival 23. More recently, ERD during field tests, such as the 6MWT and the shuttle walk test, has been shown to be significantly related to survival in idiopathic interstitial pneumonia 20, 24, 25.

Routine assessment of ERD by such exercise field tests in primary-care settings, however, has been hampered by the need for large spaces (≥30-m hallway for the 6MWT), specific equipment (an audio tape for the shuttle walking test) and additional personnel (e.g. physiotherapists). Moreover, the quantification of ERD during 6MWT may be unreliable in some ILD patients 25 and the test may require an examiner to walk with the patient to increase safety. In contrast, the 6MST requires a portable single-stage step, which can be made available in any medical attending room. In addition, test monitoring is simpler and the number of steps climbed can be easily counted. This test, therefore, may allow exercise capacity and ERD to be determined during routine consultations to the physician with major advantages in terms of reducing costs and increasing the frequency of functional evaluations of ILD patients.

Contrasting stepping versus cycling in ILD

As submaximal cycling is frequently used to assess ERD, the present authors also compared the ventilatory and cardiovascular responses at the same metabolic stress in both exercise modalities. However, the muscle mass involved in upright exercise is clearly larger than that in stationary cycling. Assuming a linear relationship between muscle mass and cardiac output, it is likely that patients needed to increase oxygen extraction during cycling to maintain the same V′_O2 of the 6MST. Moreover, the WR per unit of muscle mass is likely to be higher during cycling as compared to upright exercise 26. As a consequence, the lactate production/clearance ratio is also higher at a given submaximal V′_O2 in this exercise modality. In fact, a trend to higher V′_CO2 and respiratory quotient was observed during cycling as compared with 6MST, which is consistent with an earlier lactate threshold during cycling; this was also previously found in patients with COPD 27–29.

In this context, Palange et al. 27 found that ERD was more prominent in walking than cycling and Poulain et al. 30 demonstrated that the 6MWT was more sensitive than cycling to induce ERD in patients with COPD. Interestingly, this was also the case for some of the patients in the present study, especially when the 6MST was compared to CPET_max (table 2⇑). As previously mentioned, upright exercise is likely to be associated with lower mixed venous oxygen saturation and higher cardiac output than cycling, two factors known to conspire against the homeostasis of intrapulmonary gas exchange in ILD patients. In addition, upright exercise may have a higher impact on pulmonary gas exchange inefficiency (i.e. higher dead space volume/V_T) due to differences in body posture, lung volumes and/or central haemodynamics 27.

Study limitations

Stepping was not compared to treadmill or walking tests in the present study; it is therefore conceivable that patients’ maximum potential for ERD was not reached. Pulse oximetry was used to follow exercise oxygenation levels. Although this is a clinically valid alternative, it should be recognised that signal reliability and stability decreases markedly with readings <80% 31. In the present study, however, only two patients showed such low levels of S_p,O2 (fig. 1⇑). Future studies involving more severe patients should assess whether pulse oximetry remains reliable during stepping exercise. It also remains to be determined whether the test is an acceptable strategy of exercise evaluation in more severe patients. In fact, the present study did not include patients receiving long-term oxygen therapy because they would be likely to need supplemental oxygen during exercise and V′_O2 was a relevant study outcome. Additionally, further studies should be performed to investigate whether the test is sensitive to interventions in fibrotic ILD, such as supplemental oxygen.

Conclusions

A single-stage, self-paced 6-min step test was able to provide reliable and reproducible estimates of exercise capacity and oxyhaemoglobyn desaturation in patients with stable, mild-to-moderate interstitial lung disease. The test may prove to constitute an inexpensive and portable method for the routine functional evaluation of the patient population in primary care.