Naoto Burioka1, Sachiko Nakamoto1, Takashi Amisaki2, Takuya Horie1, Eiji Shimizu3. 1. Department of Pathobiological Science and Technology, School of Health Science, Tottori University Faculty of Medicine, Japan. 2. Department of Biological Regulation, School of Health Science, Tottori University Faculty of Medicine, Japan. 3. Division of Medical Oncology and Molecular Respirology, Department of Multidisciplinary Internal Medicine, School of Medicine, Tottori University Faculty of Medicine, Japan.
Abstract
Objective The 6-min walk test (6MWT) is a simple test that is used to examine the exercise tolerance and outcomes in patients with chronic obstructive pulmonary disease (COPD). Although the 6MWT is useful for assessing exercise tolerance, it is difficult to evaluate time-dependent parameters such as the walking pattern. A modified 6MWT has been devised to assess the walking pattern by calculating the number of steps per second (NSPS). This study was performed to investigate walking pattern of COPD patients in the modified 6MWT before and after a single inhalation of the short-acting β2-agonist procaterol. Methods Nine male COPD patients participated in this study. The 6MWT was performed before and after the inhalation of procaterol hydrochloride. A digital video recording of the 6MWT was made. After the 6MWT, the number of steps walked by the subject in each 5-s period was counted manually with a hand counter while viewing the walking test on the video monitor. Results After the inhalation of procaterol, the 6-min walking distance increased significantly in comparison to baseline (p<0.01). The mean NSPS was also significantly increased after the inhalation of procaterol in comparison to baseline (p<0.01). The walking pattern was displayed on a graph of time versus NSPS, and the walking pace was shown by a graph of time versus cumulative steps. Conclusion The analysis of the COPD patients' walking test performance and their walking pattern and pace in the 6MWT may help to evaluate the effects of drug treatment.
Objective The 6-min walk test (6MWT) is a simple test that is used to examine the exercise tolerance and outcomes in patients with chronic obstructive pulmonary disease (COPD). Although the 6MWT is useful for assessing exercise tolerance, it is difficult to evaluate time-dependent parameters such as the walking pattern. A modified 6MWT has been devised to assess the walking pattern by calculating the number of steps per second (NSPS). This study was performed to investigate walking pattern of COPDpatients in the modified 6MWT before and after a single inhalation of the short-acting β2-agonist procaterol. Methods Nine male COPDpatients participated in this study. The 6MWT was performed before and after the inhalation of procaterol hydrochloride. A digital video recording of the 6MWT was made. After the 6MWT, the number of steps walked by the subject in each 5-s period was counted manually with a hand counter while viewing the walking test on the video monitor. Results After the inhalation of procaterol, the 6-min walking distance increased significantly in comparison to baseline (p<0.01). The mean NSPS was also significantly increased after the inhalation of procaterol in comparison to baseline (p<0.01). The walking pattern was displayed on a graph of time versus NSPS, and the walking pace was shown by a graph of time versus cumulative steps. Conclusion The analysis of the COPDpatients' walking test performance and their walking pattern and pace in the 6MWT may help to evaluate the effects of drug treatment.
The 6-min walk test (6MWT) has been used to evaluate the functional capacity and to predict mortality in patients with chronic respiratory disease (1, 2). This test assesses the maximum distance that a patient can walk during a 6-min period (3). Although the test is simple, it is useful for measuring clinical improvement in response to pulmonary rehabilitation and drug therapy (4).Chronic obstructive pulmonary disease (COPD) is one of the most important respiratory diseases and is associated with a high mortality rate (5). Physical activity and the number of steps walked per day are strong predictors of all-cause mortality in COPDpatients (6, 7). The functional status of COPDpatients is examined by performing lung function tests and timed walking tests such as the 6MWT. In COPDpatients, exercise causes dynamic lung hyperinflation and an increase in the end-expiratory lung volume (EELV) due to the trapping of air due to decreased elastic recoil, which occurs secondarily to the destruction of the alveoli and the narrowing of the small airways (8-10). The inspiratory capacity (IC) of COPDpatients is significantly decreased during the 6MWT (11). The decrease in the IC of COPDpatients was significantly attenuated and the 6-min walking distance (6MWD) was increased after the inhalation of the short-acting β2-agonist procaterol hydrochloride in comparison to patients who inhaled a placebo (11).However, many COPDpatients cannot walk for 6 minutes without stopping and may have to rest several times during the 6MWT due to dyspnea (12). Their walking pace and resting time may influence the results of the 6MWT, because oxygen desaturation can be improved by resting. Although the conventional 6MWT is useful for assessing the general exercise tolerance, it is difficult to evaluate time-dependent parameters such as the instantaneous walking speed. A modified 6MWT has been developed to examine the walking pattern by determining the number of steps per second (NSPS) (12). In the present study, we assessed the effect of a single dose of inhaled procaterol on the improvement of the walking distance, the resting time, and the walking pattern and pace (as NSPS) in COPDpatients who performed the 6MWT.
Materials and Methods
Patients
Nine male patients with COPD (72.9±6.0 years) participated in this study. Spirometry was performed before and after the inhalation of 20 μg of procaterol hydrochloride (Meptin™, Otsuka Pharmaceutical, Tokyo, Japan) using a pulmonary function testing system (Chestac-7800, Chest, Tokyo, Japan) on another day (Table 1). The severity of airflow limitation in COPD was classified according to forced expiratory volume in one second (FEV1) after the inhalation of a bronchodilator (5). Five of the 9 patients inhaled tiotropium, 3 patients inhaled tiotropium and salmeterol, and 1 patient inhaled formoterol with budesonide, regularly. Patients who had experienced unstable angina or myocardial infarction during the previous month, those who had a resting heart rate of more than 120 bpm, a resting systolic blood pressure of more than 180 mmHg or a diastolic pressure of more than 100 mmHg, orthopedic or neurologic conditions were excluded from the study (3). The present study was approved by the ethics boards of Tottori University and Hitachi Memorial Hospital (No. 1845). All of the participants gave their written informed consent.
Table 1.
Pulmonary Function of Male COPD Patients (n=9).
before
after procaterol inhalation
FVC (L)
2.56 ± 0.73
2.80 ± 0.77
FEV1 (L)
1.21 ± 0.52
1.38 ± 0.68
FEV1/FVC (%)
46.7 ± 12.3
47.5 ± 13.3
FEV1 %pred. (%)
56.6 ± 25.2
62.0 ± 28.1
Values are the mean ± standard deviation.
FVC: forced vital capacity
FEV1: forced expiratory volume in one second
Pulmonary Function of Male COPDPatients (n=9).Values are the mean ± standard deviation.FVC: forced vital capacityFEV1: forced expiratory volume in one second
Study protocol
The baseline 6MWT was performed before the inhalation of procaterol. The subjects performed the baseline 6MWT and then inhaled 20 μg of procaterol using a spacer device. After resting on a chair for 20 minutes, the patients performed the 6MWT again. The 6MWT was performed in a flat corridor of 54 m in length at Tottori University Hospital or Hitachi Memorial Hospital; the other technical aspects of the 6MWT were in accordance with the published guidelines (3). Arterial blood oxygen saturation was measured by pulse oximetry (SpO2) with a finger sensor (Pulsox 300i, Konica-Minolta, Tokyo, Japan) and was continuously recorded during the test. The pulse oximetry variables were analyzed using the DS-5 Pulsox software program (Konica-Minolta). The severity of dyspnea was subjectively assessed before and after the 6MWT using a modified Borg scale (13). It has been reported that at least 2 practice walks should be performed before the 6MWT since training influences the results of the test (14, 15). The patients performed at least 2 practice walks on another day prior to the actual test because dyspnea and fatigue could have influenced the results of the 6MWT if they had practiced on the same day. The patients were allowed to sit on a chair to rest during the test, if needed, and resumed walking themselves when they had recovered. The duration of each rest was measured with a stopwatch. All of the walking tests were recorded on digital video and the 6MWD was measured.
The calculation of the number of steps per second (NSPS)
The NSPS is a new index (12); it is defined as the steps walked in A-second period divided by A, where A is a divisor of 360. We used A=5 (5-s interval) in the present study. The mean NSPS is calculated using the following formula:where ⌊ ⌋ is the floor function, and NSPS is the value of NSPS at the k-th 5-s interval (k=1,2,3,..., 72). NSPS shows the slope of time versus the cumulative steps in 5-s (12).The number of steps walked by a subject in each 5-s period was counted manually with a hand counter while viewing the walking test on the video monitor. The walking speed (m/s) was considered to be the average step length (m/step) × NSPS (step/s) (12). The NSPS was calculated as the number of steps walked in a 5-s period divided by 5, and this calculation was performed for 72 consecutive periods (360 s ÷ 5 s) in each subject. Because the NSPS is proportional to the walking speed, it usually decreases when a patient walks more slowly and falls to zero if the patient stops walking (12).
Statistical analysis
The results are presented as the median (interquartile range) or mean ± SD. Comparisons were performed using the Wilcoxon matched-pairs signed-rank test or the paired t-test. The StatFlex software program was used to perform the statistical analyses (StatFlex, ViewFlex, Tokyo, Japan). p values of <0.05 were considered to indicate statistical significance.
Results
With regard to the severity of airflow limitation in our COPDpatients, 3 patients were classified as Global initiative for chronic Obstructive Lung Disease (GOLD) 1 (predicted FEV1 (%) ≥80%), 2 patients were classified as GOLD 2 (50% to <80%), 3 patient were GOLD 3 (30% to <50%), and 1 patient was classified as GOLD 4 (<30%) (5). The height, weight and body mass index of the 9 COPDpatients were 1.58±0.06 m, 51.6±9.2 kg and 20.7±4.2 kg/m2, respectively. Table 1 shows the results of a pulmonary function test before and after the inhalation of procaterol on another day. Table 2 shows the results of the 6MWT before and after the inhalation of procaterol. After a single inhalation of procaterol, the 6MWD was significantly longer in comparison to baseline (Fig. 1A). An increase of >30 m in the 6MWD is considered to be the minimal clinical important difference (MCID) for the patients with chronic respiratory disease (1, 2). After the inhalation of procaterol, the 6MWD changed by more than 30 m in 4 of the 9 COPDpatients. The resting heart rate was not significantly changed in comparison to that before the 6MWT. The total number of steps in 6 minutes was significantly increased by the inhalation of procaterol, but the mean step length did not change (Table 2). Six of the 9 patients had to rest on a chair during the baseline 6MWT. The median (range) number of rests before and after the inhalation of procaterol was 1 (0-3) and 1 (0-3), respectively. Although the number of rests was almost same, the total resting time was significantly shorter after the inhalation of procaterol (Table 2). The mean NSPS showed a significant increase after the inhalation of procaterol in comparison to the baseline value (Fig. 1B). On the other hand, the lowest SpO2 and mean SpO2 values were not significantly different after the inhalation of procaterol. There was no significant difference in the modified Borg scale values after the 6MWT before and after the inhalation of procaterol (Table 2).
Table 2.
Results of the 6-min Walk Test (6MWT) before and after Inhalation of Procaterol (n=9).
First 6MWT
Second 6MWT after procaterol inhalation
p value
6-min distance (m)
258.7 ± 124.0
293.4 ± 115.6
p<0.01 *
Total no. of steps
473.6 ± 153.9
526.1 ± 135.6
p<0.02 *
Resting HR before test (min-1)
91.5 ± 10.5
92.3 ± 9.1
p>0.43 *
Mean length of a step (m)
0.52 ± 0.09
0.54 ± 0.09
p>0.10 *
Mean NSPS (step/s)
1.32 ± 0.43
1.46 ± 0.38
p<0.01 *
Total resting time (s)
85 (20.3 - 149.8) †
59 (13.3 - 104.8) †
p<0.05 **
Borg scale after 6MWT
3.0 (1.8 - 4.2) †
3.0 (1.9 - 4.1) †
p>0.99 **
Lowest SpO2 (%)
88.7 ± 5.1
88.2 ± 5.5
p>0.45 *
Mean SpO2 (%)
91.4 ± 3.7
91.3 ± 3.8
p>0.75 *
HR: heart rate
Values are the mean ± standard deviation or median (interquartile range) †.
*: Paired t-test, **: Wilcoxon matched-pairs signed-rank test
Figure 1.
The 6-min walking distance (6MWD) and the mean of number of steps per second (NSPS) before and after the inhalation of procaterol. (A) The inhalation of procaterol significantly increased the mean 6MWD. (B) The mean NSPS was also significantly increased after the inhalation of procaterol.
Results of the 6-min Walk Test (6MWT) before and after Inhalation of Procaterol (n=9).HR: heart rateValues are the mean ± standard deviation or median (interquartile range) †.*: Paired t-test, **: Wilcoxon matched-pairs signed-rank testThe 6-min walking distance (6MWD) and the mean of number of steps per second (NSPS) before and after the inhalation of procaterol. (A) The inhalation of procaterol significantly increased the mean 6MWD. (B) The mean NSPS was also significantly increased after the inhalation of procaterol.Fig. 2A shows an example of the walking pattern and pace (as the NSPS) in a 73-year-old patient with moderate COPD. The 6MWD improved by 30.5 m following the inhalation of procaterol. Note that NSPS falls to zero when the patient stops walking. The patient rested for a total of 32-s before the inhalation of procaterol (Fig. 2A). After the inhalation of procaterol, this patient could walk for 6 minutes without rest. Fig. 2B shows the numbers of the cumulative steps during the 6MWT for the same patient. The results of the two tests (before and after the inhalation of procaterol) shared a common slope (except for during the rest periods), and the slope was constant (Fig. 2B), which suggested that, with the exception of the rest periods, the walking pace was almost the same during the 6MWT. The mean NSPS before and after the inhalation of procaterol in the 6MWT was 1.57 and 1.78 (step/s), respectively. The mean NSPS is increased by a decrease in the rest time and/or an increase in the walking pace. In this case, the inhalation of procaterol led to a decrease in the rest time, resulting in an increase in the mean NSPS. Figure 3, 4 show that when the resting time was decreased by the inhalation of procaterol, the 6MWD was improved by more than 30 m after the inhalation of procaterol.
Figure 2.
Determining the walking pattern and pace from the number of steps per second (NSPS) and the cumulative steps before and after the inhalation of procaterol. The patient was a 73-year-old man with COPD. Although the patient walked 302 m in the 6-min walk test (6MWT) with 32 s of rest before the inhalation of procaterol (closed circle), he could walk 332.5 m without a rest after the inhalation of procaterol (closed triangle). The walking pattern is clearly displayed on this graph of time versus NSPS (A). During the 6MWT, the NSPS falls to zero each time the patient stops walking. The cumulative number of steps is shown as a function of time for each test (B). The slope indicates the walking pace. This patient walked at the same pace before and after the inhalation of procaterol, except for during rest periods.
Figure 3.
Determining the walking pattern and pace from the number of steps per second (NSPS) and the cumulative steps before and after the inhalation of procaterol. The patient was an 80-year-old man with COPD. Although the patient walked 177 m in the 6-min walk test (6MWT) with 114 s of rest before the inhalation of procaterol (closed circle), he could walk 249.5 m with 62 s of rest after the inhalation of procaterol (closed triangle) (A). The cumulative number of steps is shown as a function of time for each test (B). The slope indicates the walking pace. This patient walked at the same pace before and after the inhalation of procaterol, except for during rest periods.
Figure 4.
Determining the walking pattern and pace from the number of steps per second (NSPS) and the cumulative steps before and after the inhalation of procaterol. The patient was an 81-year-old man with COPD. Although the patient walked 125 m in the 6-min walk test (6MWT) with 158 s of rest before the inhalation of procaterol (closed circle), he could walk 188 m with 77 s of rest after the inhalation of procaterol (closed triangle) (A). The cumulative number of steps is shown as a function of time for each test (B). The slope indicates the walking pace. This patient walked at the same pace before and after the inhalation of procaterol, except for during rest periods.
Determining the walking pattern and pace from the number of steps per second (NSPS) and the cumulative steps before and after the inhalation of procaterol. The patient was a 73-year-old man with COPD. Although the patient walked 302 m in the 6-min walk test (6MWT) with 32 s of rest before the inhalation of procaterol (closed circle), he could walk 332.5 m without a rest after the inhalation of procaterol (closed triangle). The walking pattern is clearly displayed on this graph of time versus NSPS (A). During the 6MWT, the NSPS falls to zero each time the patient stops walking. The cumulative number of steps is shown as a function of time for each test (B). The slope indicates the walking pace. This patient walked at the same pace before and after the inhalation of procaterol, except for during rest periods.Determining the walking pattern and pace from the number of steps per second (NSPS) and the cumulative steps before and after the inhalation of procaterol. The patient was an 80-year-old man with COPD. Although the patient walked 177 m in the 6-min walk test (6MWT) with 114 s of rest before the inhalation of procaterol (closed circle), he could walk 249.5 m with 62 s of rest after the inhalation of procaterol (closed triangle) (A). The cumulative number of steps is shown as a function of time for each test (B). The slope indicates the walking pace. This patient walked at the same pace before and after the inhalation of procaterol, except for during rest periods.Determining the walking pattern and pace from the number of steps per second (NSPS) and the cumulative steps before and after the inhalation of procaterol. The patient was an 81-year-old man with COPD. Although the patient walked 125 m in the 6-min walk test (6MWT) with 158 s of rest before the inhalation of procaterol (closed circle), he could walk 188 m with 77 s of rest after the inhalation of procaterol (closed triangle) (A). The cumulative number of steps is shown as a function of time for each test (B). The slope indicates the walking pace. This patient walked at the same pace before and after the inhalation of procaterol, except for during rest periods.Fig. 5A shows an example of the increase in the walking pace after the inhalation of procaterol. This 68-year-old patient could walk in 6-minute without a rest. Fig. 5B shows a graph of time versus the cumulative steps during the 6MWT. The slope increased after the inhalation of procaterol (Fig. 5B), which suggests that the walking pace increased during the 6MWT. The mean NSPS before and after the inhalation of procaterol in the 6MWT was 1.78 and 1.88 (step/s), respectively. In this case, the increase in the walking pace following the inhalation of procaterol might have resulted in an increase in the mean NSPS; however, a placebo study will be necessary. The results in 5 participants in whom the improvement in the 6MWD was <30 m after the inhalation of procaterol are not shown.
Figure 5.
Determining the walking pattern and pace from the number of steps per second (NSPS) and the cumulative steps before and after the inhalation of procaterol. The patient was a 68-year-old man with COPD. Although the patient walked 356.5 m in a 6-min walk test (6MWT) without a rest before the inhalation of procaterol (closed circle), he could walk 422 m after the inhalation of procaterol (closed triangle) (A). The cumulative number of steps is shown as a function of time for each test (B). The slope indicates that the walking pace was increased by the inhalation of procaterol.
Determining the walking pattern and pace from the number of steps per second (NSPS) and the cumulative steps before and after the inhalation of procaterol. The patient was a 68-year-old man with COPD. Although the patient walked 356.5 m in a 6-min walk test (6MWT) without a rest before the inhalation of procaterol (closed circle), he could walk 422 m after the inhalation of procaterol (closed triangle) (A). The cumulative number of steps is shown as a function of time for each test (B). The slope indicates that the walking pace was increased by the inhalation of procaterol.
Discussion
The present study demonstrated that a single inhalation of procaterol significantly prolonged the 6MWD, and shortened the total resting time or increased the walking pace during the 6MWT, suggesting that the inhalation of procaterol may be useful for improving the exercise performance of COPDpatients undertaking this test. In addition, the steps per second and the cumulative steps were effective measures for analyzing the changes in the walking pattern and pace after the inhalation of procaterol in COPDpatients. Determining the number of steps walked per unit time and the consideration of the total resting time during the 6MWT may be important when assessing the functional status before and after drug treatment because some COPDpatients cannot walk continuously for 6-minute without resting.In COPDpatients, exercise causes an increase in the EELV along with an increase of ventilation, which is known as dynamic lung hyperinflation (8-10). A significant relationship has been reported between dynamic lung hyperinflation and dyspnea during exercise in COPDpatients (8). Several reports have also shown that the pretreatment of COPDpatients with inhaled procaterol improves dynamic lung hyperinflation and exercise tolerance (10, 11, 16-18). A previous report also indicated that the inhalation of formoterol increased the 6MWD (19). In addition, Fujimoto et al. reported that dynamic lung hyperinflation secondary to hyperventilation reduced the IC in COPDpatients, while the IC was increased by the inhalation of procaterol (10). Moreover, the use of procaterol has been shown to improve both the exercise tolerance and health-related quality of life (16). In the present study, the 6MWD was significantly increased after the inhalation of procaterol. It is reported that a >30-m increase in the 6MWD represents the minimal clinically important difference (MCID) for COPDpatients (1, 2). The 6MWD changed by >30 m following the inhalation of procaterol in 4 of the 9 COPDpatients. In a graph of time versus cumulative steps, 3 of the 4 patients who showed an improvement of >30 m after the inhalation of procaterol showed a shorter total rest time, and the walking pace of one patient increased during the 6MWT. Thus, the increase in the 6MWD after the inhalation of procaterol might be a clinically relevant effect in 4 patients.Although Golpe et al. found that exercise-related oxygen desaturation during the test was not an independent predictor in a multivariate analysis (20), the 6MWT has been reported to predict mortality in COPDpatients (20-22). However, patients with moderate or severe COPD frequently rest during the 6MWT, as was noted in the present study, and exercise-related oxygen desaturation could improve after resting. In this study, the modified Borg scale after the 6MWT, the lowest SpO2, and the mean SpO2 were not significantly changed by the inhalation of procaterol. This suggests that our COPDpatients walked as far as possible until they needed to rest during both tests, and recovered SpO2, resulting in no significant change in dyspnea or in the lowest or mean SpO2 values. Thus, it is important to take the rest time during the 6MWT into consideration when assessing the changes in SpO2 and desaturation during exercise. The previous reports did not clarify importance of a number of points, including the number of rests and the total resting time. The NSPS value, which decreases with rest during the 6MWT, can be used to evaluate the impact of resting in the 6MWT. An analysis of the walking pattern and pace during the 6MWT would be useful in clinical studies on COPD medications.The total steps walked during the 6MWT is reported to be useful for assessing the exercise capacity of patients with chronic heart disease (23, 24). We have developed a modified 6MWT, in which the walking pattern is examined by counting steps (12), allowing the walking pattern of COPDpatients to be displayed on a graph of time versus NSPS. In addition, the walking pace could be displayed by a graph of time versus cumulative steps because NSPS (k=1,2,3,..., 72) shows a slope in 5-s (12). Moreover, it has been reported that a 3-dimensional accelerometer can accurately detect steps while a subject is walking (23, 24), and evaluate daily physical activity (25). If a pulse oximetry system that incorporates a 3-dimensional accelerometer that can accurately count steps is developed, the device could record SpO2 continuously, compute the NSPS, and plot a graph of time versus NSPS automatically to display the walking pattern during the 6MWT.The present study is associated with several limitations, with the most obvious being its relatively small sample size. Furthermore, we did not investigate a random sample of COPDpatients who showed a spectrum of disease severity or use a placebo. Further studies that include a placebo group will be needed to clarify the effects of pretreatment with inhaled procaterol on the exercise performance of COPDpatients (26) and the usefulness of our new modified 6MWT with NSPS in assessing the response to drug treatment and the efficacy of pulmonary rehabilitation.The authors state that they have no Conflict of Interest (COI).
Authors: Anne E Holland; Martijn A Spruit; Thierry Troosters; Milo A Puhan; Véronique Pepin; Didier Saey; Meredith C McCormack; Brian W Carlin; Frank C Sciurba; Fabio Pitta; Jack Wanger; Neil MacIntyre; David A Kaminsky; Bruce H Culver; Susan M Revill; Nidia A Hernandes; Vasileios Andrianopoulos; Carlos Augusto Camillo; Katy E Mitchell; Annemarie L Lee; Catherine J Hill; Sally J Singh Journal: Eur Respir J Date: 2014-10-30 Impact factor: 16.671
Authors: Frank Sciurba; Gerard J Criner; Shing M Lee; Zab Mohsenifar; David Shade; William Slivka; Robert A Wise Journal: Am J Respir Crit Care Med Date: 2003-02-20 Impact factor: 21.405
Authors: Rafael Golpe; Luis A Pérez-de-Llano; Lidia Méndez-Marote; Alejandro Veres-Racamonde Journal: Respir Care Date: 2013-01-15 Impact factor: 2.258
Authors: Melissa Jehn; Sandra Prescher; Kerstin Koehler; Stephan von Haehling; Sebastian Winkler; Oliver Deckwart; Marcus Honold; Udo Sechtem; Gert Baumann; Martin Halle; Stefan D Anker; Friedrich Koehler Journal: Int J Cardiol Date: 2013-07-25 Impact factor: 4.164
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