The 6‐min walk distance: change over time and value as a predictor of survival in severe COPD

Chronic obstructive pulmonary disease (COPD) ranks as one of the leading causes of death and disability in the world 1–3. Management of patients with COPD includes education, preventive care, smoking cessation, pharmacological and oxygen therapy, and pulmonary rehabilitation 2, 4–6. Traditionally, the severity of COPD is graded according to the degree of airflow limitation, expressed by the forced expiratory volume in one second (FEV₁) of the forced vital capacity (FVC) manoeuvre. This simple test is a useful predictor of morbidity and mortality. In addition, the defining characteristics of FEV₁ and its change over time in patients with COPD have been well studied 4, 7, 8. In spite of these characteristics, the FEV₁ incompletely describes other negative attributes of COPD. It is not a good predictor of dyspnoea, the most frequent clinical complaint of patients suffering from the disease, and in those patients with the most severe obstruction, it is also a poor predictor of survival, hospitalisation frequency and functional capacity 4, 9, 10.

The 6‐min walk distance (6MWD) is a test used to assess the functional status of patients with COPD. Introduced in 1976 as a 12‐min walk test to measure exercise capacity for patients with chronic lung disease 11, over time it has proved to be reliable, objective, inexpensive and easy to apply regardless of the patient's age or educational level 12–16. It has been shown to predict survival postpulmonary rehabilitation 9, and to predict postoperative morbidity and mortality after lung volume reduction surgery 17. In addition, a threshold for noticeable differences in patients' subjective comparison ratings of their walking has been determined 18. Owing to these advantages and its relative standardisation 19, the 6MWD test is increasingly used to complement the evaluation of patients with COPD.

In contrast to knowledge regarding the natural history of lung function decline over time, there is no longitudinal data about the 6MWD in patients with COPD. Reference equations have been proposed to calculate the distance walked by healthy adults, based on a single 6MWD test with no follow-up 20, 21. If the 6MWD represents a measurement that changes independently of FEV₁, it perhaps could be used as a parameter to evaluate the clinical status of patients, particularly those with the most severe COPD, in whom FEV₁ may not completely reflect functional and health status. The value of the 6MWD as a predictor of mortality has not been prospectively studied in a cohort of patients with severe disease without any other intervention (i.e. pulmonary rehabilitation). Finally, the value of the 6MWD as a predictor of mortality has not been compared prospectively with that of traditional markers of disease severity such as body mass index (BMI) or degree of comorbidity.

Material and methods

Results

A total of 198 patients with COPD and 41 age-matched controls were included in the study (table 1⇓). Both groups had statistically different BMI, FEV₁, 6MWD, and changes in FEV₁ and 6MWD during the study period.

Of the 198 patients, 114 (58%) were able to perform two different walking evaluations and concomitant pulmonary function tests, ≥1 yr apart, and were alive at the end of the study (group 1). Forty-two patients (21%) who completed two evaluations died during the study period (group 2) and 42 (21%) died after completing only one evaluation (group 3; fig. 1⇓). Eight patients were excluded from the study because they were involved in pulmonary rehabilitation <1 yr before the evaluation, and nine patients were included 1 yr after rehabilitation (four, three and two patients in groups 1, 2 and 3, respectively).

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Fig. 1.—

Flow diagram of patients enrolled in the study.

Table 2⇓ shows the clinical characteristics of the COPD patients divided in the three groups. The patients were different in terms of age, BMI and spirometric values. The nonsurvivors (group 2 and 3) were older, had lower BMI and FEV₁ values, and walked shorter distances. The duration of the follow-up period was similar between groups 1 and 2.

The majority of the patients in the COPD group were male (83%). There was no difference in age but females had sigificantly higher BMI values (26.80 versus 24.44 kg·m⁻²), FEV₁ values (40% versus 34%), and a tendency to walk shorter distances during the 6MWD (245 versus 208 m, p<0.07).

Figure 2⇓ shows the difference in the 6MWD during the first and second evaluation of groups 1 and 2. The distance walked by patients in group 1 (survivors) during the first evaluation was 275±98 m and it decreased to 236±111 m (p<0.001) in the follow-up evaluation. This represents a mean decrease of 21±31 m·yr⁻¹. In group 2 (dead after the second evaluation), the distance decreased from 221±103 m to 169±97 m (p<0.001), a mean decrease of 40±47 m·yr⁻¹. Similarly, there was a decrease in FEV₁ (group 1) from 1.13±0.40 L to 0.98±0.39 L (p<0.001), a mean decrease of 102±172 mL·yr⁻¹. In the second group, it decreased from 0.94±0.32 L to 0.77±0.28 L (p<0.001), with amean decrease of 118±130 mL·yr⁻¹. The change in the distance walked per year is significantly higher for group 2 compared with group 1 (−40 versus −21 m, respectively; p<0.004). The change in FEV₁, however, was not significantly different between both groups (−118 versus 102 mL·yr⁻¹, p<0.58).

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Fig. 2.—

a) Patients who survived had a significantly higher mean 6‐min walking distance (6MWD) value (275±98 m) compared with patients who died (188±98 m). However, there is a significant overlap between the individual patients in both groups. b) Difference (mean±sd) between the first and second 6MWD evaluation in the group of survivors (group 1) and nonsurvivors (group 2). ***: p<0.001.

There was a good correlation between the first and second FEV₁ (r=0.89, p<0.01), 6MWD (r=0.84, p<0.01) and BMI (r=0.90, p<0.01) for the patients in groups 1 and 2. Other correlations were weaker for the same groups including first FEV₁ versus first 6MWD (r=0.44, p<0.001), and second FEV₁ versus second 6MWD (r=0.56, p<0.001). There was no significant correlation between the change in FEV₁ per year versus change in 6MWD per year (r=0.09, p<0.22), and change in BMI versus change in 6MWD (r=0.05, p=0.57).

Despite the difference in the distance walked by the group of survivors and nonsurvivors, there was a significant overlap of individual values in the 6MWD by these two groups, as shown in figure 2⇑. However, a Chi-squared test analysis showed a significant statistical difference (p<0.0001) between the distances walked, divided into 100 m categories, and the observed mortality (fig. 3⇓)

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Fig. 3.—

Mortality progressively decreases as the 6‐min walking distance (6MWD) increases. For distances <100 m, n=19; for 101–200 m, n=61; for 201–300 m, n=57; for 301–400 m, n=46; and for >400 m, n=15.

To confirm this finding adjusting for censoring, survival analyses were performed via the Kaplan-Meier method to compare patients by categories of 6MWD (fig. 4⇓). A log rank test showed that the categories had significantly different survival (p<0.001), with longer times to death observed in categories of longer 6MWD.

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Fig. 4.—

Kaplan-Meier curves comparing survival with four different walked distances. –––: >301 m; - - -: 201–300 m; ═: 101–200 m; –· – ·: <100 m.

The presence of comorbidities is displayed in table 3⇓. The combined comorbidity index by Charlson was used to control for the confounding influence of comorbid conditions on overall survival. There was no significant difference in the number of comorbidities among the three groups adjusted by age (p=0.09).

The potential independent effect of continuous 6MWD as a predictor of survival was assessed in a Cox proportional hazards regression model accounting for age, BMI, FEV₁ and comorbidities (table 4⇓). It was found that 6MWD was a significant predictor of survival with a risk ratio of death of 0.82 per 50 m increase in 6MWD (95% confidence interval 0.72–0.94, p<0.003).

Discussion

This study has three major findings. First, it describes the change over time in 6MWD in patients with severe COPD. Secondly, it shows that independent of comorbid conditions the 6MWD is a better predictor of mortality than FEV₁and BMI in this subset of patients. Thirdly, it shows that in patients with severe disease, the decline in 6MWD occurs independently of the change in FEV₁.

This is the first controlled study that describes longitudinal changes in the 6MWD in patients with severe COPD. Most of the previous reports emphasise the reliability of the test, its validity, safety, reproducibility, correlation among 2‐, 6‐ and 12MWD test 11–13, the effect of encouragement 14 and the value of the test, as a predictor of survival in different clinical conditions 9, 15, 17, 25, 26. However, all these characteristics and correlations have been described in a single 6MWD evaluation without any follow-up measurements. In this study all but 35 patients (23%) walked a shorter distance on the second evaluation. This implicates a deterioration in the patient's physiological status, which could be due to multiple factors. These include worsening of the pulmonary condition, deterioration of another organ system, physical deconditioning or systemic effects of COPD. It is impossible to determine the individual contribution of each of these factors in the observed change, but they must be important, as a lower 6MWD was associated with a higher mortality.

The authors believe that the 6MWD test should be considered in the evaluation of patients with severe COPD, and the decline in the distance walked that occurs over time should be followed closely for different reasons. First, the observed change in the 6MWD was independent of changes in the FEV₁. Secondly, the rate of decline in the 6MWD per year was different between the group of survivors and nonsurvivors, but the decrease in FEV₁ was not. Thirdly, there is an inverse relationship between the distance walked and mortality. Therefore, it seems that the FEV₁ and 6MWD have an important and independent value as monitors of patients with COPD. The FEV₁ is useful to classify patients at different levels of disease severity, and based on it, to predict mortality. However, when the disease becomes severe or very severe (i.e. FEV₁ <50% pred), the 6MWD test seems to be a better mortality predictor. The limited information provided by the spirometric value when used as the sole tool in the assessment of patients with severe COPD is supported by these results.

A weak correlation was found between the distance walked and the FEV₁. This finding is consistent with that of McGavin et al. 11 who initially reported a poor correlation between the distance walked and FEV₁ (r=0.28). Subsequent work from the same authors described a better correlation (r=0.44) between both values, but they concluded that the scatter of the results made exercise performance difficult to predict from respiratory function tests 12. In this study, a poor correlation was also found between the 6MWD and the FEV₁ during the second walking test evaluation and this correlation was even weaker when the rate of change in both tests was compared. There has been no report, prospective or retrospective, of this poor relationship over time in a group of COPD patients. It seems reasonable to conclude that when patients reach a severe degree of airflow limitation, the correlation between FEV₁ and 6MWD is weak at best. The best explanation for this observation is that the distance walked depends not only on respiratory function, but also on the cardiopulmonary, nutritional and peripheral muscle status of the individual 15–17, 25, 26. It also suggests that both tests measure different aspects of the patient's disease state. The FEV₁ most likely expresses the respiratory system involvement, whereas the 6MWD may represent the systemic effects associated with the disease.

These results are supported by several outcome studies in different patient populations, in which the value of timed walking distance measurements predicting morbidity and mortality has been tested. One previous publication described an association between the distance walked and increased mortality and morbidity in patients with left ventricular dysfunction 15. The group of patients who walked less (<300 m) had a significantly greater chance of dying or being hospitalised compared with the group with better performance. Similar results were obtained by Cahalin et al. 26 in patients with heart failure, in whom they found an increased likelihood of death or pretransplant hospital admission for continuous inotropic or mechanical support within 6 months, if patients walked <300 m over 6 min. Miyamoto et al. 25 found the 6MWD test to be the only variable independently related to mortality in primary pulmonary hypertension. In this study, patients walking <332 m had a significantly lower survival rate than those walking farther. In a retrospective analysis, Gerardi et al. 9 studied 158 patients after pulmonary rehabilitation (40±17 months), and observed that the 12MWD test was the most significant variable related to prognosis. Indeed, the 12MWD was better than FEV₁, arterial blood gases, BMI, age, albumin and common comorbid conditions in predicting mortality. A more recent study by Bowen et al. 27 showed that postrehabilitation functional activities score (measured by a self-completed questionnaire), being married and a longer 6MWD were associated with increased survival. In a study of 41 patients with COPD undergoing lung volume reduction surgery, the inability to walk ≥200 m over 6 min was a good predictor of postoperative complications and overall mortality 17. Taken together these reports strongly support the value of a walking distance test in the global assessment of patients with chronic debilitating diseases.

The present study has some limitations. First, 86% of the patients had severe COPD (FEV₁ <50% pred) with elevated mortality (21% per year), limiting the conclusions to this subset of patients. The high mortality was attributed to the fact that both pulmonary divisions constitute referral centres of COPD patients treated by internal medicine practitioners and pulmonary disease specialists, who usually refer the most ill and physically limited patients for evaluation. Although the authors did not select the population, they are “selected” by their referral physician. Nevertheless, this is the group of patients with the highest mortality and probably the one in which the 6MWD may better predict this outcome. Secondly, only two evaluations were performed during the study period and the time span between them was relatively short (2 yrs) to better estimate the rate of decline in FEV₁. However, other groups have also used two measurements to estimate the rate of decline in FEV₁ 28, and despite the short interval, the authors were able to show a change of 37 mL·yr⁻¹ in FEV₁ in the control group, a value similar to those reported in the literature 4. The COPD group had a higher rate of decline (106±173 mL·yr⁻¹) and this may represent a subset of patients with severe disease and “rapid decline” in lung function. Thirdly, the narrow range in spirometry values may have prevented the authors from finding a better relationship between the change in FEV₁ and decline in 6MWD. Nevertheless, a nonsignificant correlation was also found in the control population (r=0.29 p<0.06), thereby supporting the findings. Fourth, there was an overlap in the individual values of 6MWD between survivors and nonsurvivors (fig. 2⇑). Although the 6MWD did not provide perfect discrimination in predicting death, as a group, the individuals who died during the study period walked shorter distances, on average, particularly those who walked <200 m (figs 3⇑ and 4⇑). Also, the probability of dying increased by 18% for every reduction of 50 m in the distance walked. Fifth, there was a disparity in the sex distribution, with more females in group 1 (alive with two evaluations). From previous reports 20, 21, it is known that the 6MWD is shorter in females compared with males, as it was in this case (43 m). Therefore, the presence of a larger number of females in group 1 makes the difference between survivors and nonsurvivors smaller than it could have been if the sexes were equally represented in both groups. Sixth, a few patients (n=9) underwent pulmonary rehabilitation, which usually increases the 6MWD and may alter the results. However, the number of patients who were included in the study after pulmonary rehabilitation were similar in each group, they were studied ≥1 yr postrehabilitation to minimise the potential benefit of it 29, 30, and there was no difference in the statistical analysis whether they were included or not.

In summary, this study shows that the distance walked during a 6MWD test by patients with severe COPD progressively declines over time. This decline occurs independently from the change in lung function. In spite of significant overlap in individual values, a shorter walked distance was confirmed to be associated with a higher mortality in COPD patients. The authors estimated the risk of dying by changes in the 6MWD and demonstrated that the 6MWD is a better predictor of mortality than FEV₁, BMI or associated comorbidities.

The authors believe that a 6‐min walk distance test adds important independent information to the routine evaluation of patients with severe chronic obstructive pulmonary disease and should be considered in the evaluation of these patients.