Research ArticleOriginal Research

Sedentary Behavior Is an Independent Predictor of Mortality in Subjects With COPD

Karina C Furlanetto, Leila Donária, Lorena P Schneider, José R Lopes, Marcos Ribeiro, Karen BP Fernandes, Nidia A Hernandes and Fabio Pitta
Respiratory Care May 2017, 62 (5) 579-587; DOI: https://doi.org/10.4187/respcare.05306

Abstract

BACKGROUND: The terms sedentary behavior and physical inactivity have been confusingly mixed. Although the association between physical inactivity and mortality has been shown previously in subjects with COPD, this association had not yet been investigated with regard to sedentarism. The aim of this work was to investigate the impact of sedentary behavior on mortality of subjects with COPD and to propose a cutoff point of sedentarism with prognostic value.

METHODS: In this retrospective cohort study, sedentary behavior was assessed with 2 activity monitors (DynaPort and Sensewear armband) in 101 subjects with COPD from 2006 to 2011. Vital status was then ascertained in 2015. The following 6 variables of sedentary behavior were analyzed: average of metabolic equivalent of task (MET)/d (reflecting intensity); time spent/d lying, sitting, and lying + sitting (reflecting duration of sedentary postures); and time spent/d in activities requiring <1.5 MET and <2 MET (reflecting intensity and duration of sedentary time). Cutoff points for sedentarism and their respective prognostic values were investigated for each variable.

RESULTS: Forty-one subjects (41%) died over a median (interquartile range) follow-up period of 62 (43–88) months. After adjusting for potential confounders in the Cox regression model, cutoff points from variables that combine duration of sedentary time and intensity <1.5 MET or <2 MET were associated with the increased risk of mortality. The strongest independent cutoff for predicting mortality was ≥8.5 h/d spent in sedentary activities <1.5 MET (area under the curve 0.76; hazard ratio 4.09, 95% CI 1.90–8.78; P < .001).

CONCLUSIONS: Sedentary behavior was an independent predictor of mortality in subjects with COPD, even adjusting for moderate-to-vigorous physical activity and a number of other variables. Mortality was higher in subjects with COPD who spend ≥8.5 h/d in activities requiring <1.5 MET. These findings may open room for future studies aiming at decreasing sedentary time as a promising strategy to reduce mortality risk in subjects with COPD.

Introduction

Reduced level of physical activity in daily life is an important predictor of mortality in patients with COPD.14 Increased sedentary behavior is also associated with deleterious health effects, which differ from those that can be attributed to reduced physical activity in daily life (or lack of moderate-to-vigorous physical activity).5 In fact, the terms sedentary behavior and physical inactivity have been confusingly mixed. However, these are different outcomes, since it is possible for an individual to accumulate large amounts of both moderate-to-vigorous physical activity and sedentary behavior throughout the same day.58

The differentiation between these terms has recently received interest.5,7,9,10 The 2 most common definitions of sedentarism are as follows: one based solely on low intensity (activities performed at an intensity <1.5 metabolic equivalent of task [MET]) and another that combines low intensity (≤1.5 MET) with a large proportion of the day spent in the seated or reclined posture.11 Common sedentary behaviors include reading, television viewing, and using a computer, among others.7 In contrast, “inactive” should be used to describe those who are performing insufficient amounts of moderate-to-vigorous physical activity,5,7,9 (ie, not meeting specified physical activity guidelines, such as engaging in 30 min/day of activities ≥3 MET on 5 d/week).12

Patients with COPD typically do very little activity at moderate or vigorous intensities,7,13 and sedentary behavior is predominant in their daily lives.7,14 Previous studies have shown the association between physical activity profile and mortality among many other outcomes in these subjects.1,1517 However, up to this moment, there is no study on COPD that has investigated the association between mortality and variables of sedentary behavior (instead of variables of physical activity), according to the above-mentioned definitions. In addition, there are no available cutoff points of objectively assessed variables of sedentarism that classify patients as sedentary or not as well as there are no studies investigating whether these classifications impact on mortality. Therefore, despite the well-known links between physical activity in daily life and mortality in COPD and between sedentarism and mortality in the general population,6,18 a similar link between sedentarism and mortality has not yet been clearly described in subjects with COPD. Based on this, it was hypothesized that subjects with COPD classified as sedentary would also present a higher risk of mortality than non-sedentary subjects. To investigate this hypothesis, the aims of this study were to propose a cutoff point for sedentarism in subjects with COPD and to investigate its association with mortality.

QUICK LOOK

Current knowledge

The differentiation between “sedentary behavior” and “physical inactivity” has recently received interest. A sedentary lifestyle has been independently associated with mortality in the general population, regardless of physical activity level. Previous studies in subjects with COPD have shown the association between physical activity variables with mortality among many other outcomes, although the association of sedentary behavior with mortality was not yet investigated.

What this paper contributes to our knowledge

Sedentary behavior was associated with mortality in subjects with COPD, even adjusting for moderate-to-vigorous physical activity and a number of other variables. The study provides an analysis of the cutoff points with prognostic value to identify sedentary subjects with COPD. Avoiding long periods of sedentary behavior reduces mortality risk in subjects with COPD.

Methods

Sample and Study Design

This is a cohort retrospective study that used baseline data from a study previously published in this Journal by the present group.19 From May 2006 to July 2011, 102 subjects with diagnosis of COPD according to the Global Initiative for Chronic Obstructive Lung Disease (GOLD)20 gave written informed consent and were assessed at the Laboratory of Research in Respiratory Physiotherapy, State University of Londrina (Brazil). After baseline assessment, all subjects were enrolled in a prospective interventional study19 that investigated the effects of 2 different exercise programs performed during 3 months. However, in that study, no significant changes in physical activity in daily life or sedentary behavior were observed after 3 months of rehabilitation, which indicates that this cohort was not strongly influenced by the effects of pulmonary rehabilitation on physical activity in daily life, as shown previously.21 Furthermore, the groups of subjects included in the 2 different exercise programs presented similar time to death when compared with each other and also with the group of dropouts (P > .05; data not shown), indicating that the recruitment method did not impact the results.

Inclusion criteria were: diagnosis of COPD according to the GOLD criteria,20 clinical stability without infections and exacerbations within the last 3 months before the study, and an absence of severe and/or unstable cardiac disease and musculoskeletal comorbidity that could interfere with carrying out the proposed assessments. The exclusion criterion was the absence of available baseline data. The analysis of mortality or survival for each subject included in the previous study was performed a posteriori in August 2015, as described below. The study was approved by the institutional research ethics committee (approval 996.413).

Measurements

Sedentary Behavior

Sedentarism variables and time spent in moderate-to-vigorous physical activity (ie, >3 MET) were assessed at the study entry, when all subjects wore 2 activity monitors simultaneously over 2 weekdays (Tuesday and Wednesday) for 12 h/d. The 2-d average was used for the analysis. Reliability of this assessment period (ie, 2 d) was previously shown to be good in subjects with COPD.13,22 The 2 activity monitors were the multisensory SenseWear armband (BodyMedia, Pittsburgh, Pennsylvania), which is worn on the upper-posterior region of the right arm, and the triaxial DynaPort activity monitor (McRoberts, The Hague, The Netherlands), which is worn on the patient's waist. Both activity monitors have been validated for COPD.13,2325

Six sedentarism variables were used in this study, and they may be divided into 3 types: (1) 3 variables reflecting time spent/d in sedentary postures (lying time/d, sitting time/d, and the sum of lying and sitting time (lying + sitting time/d)5; (2) one variable reflecting intensity of performed activities during the day (average of MET/d)26; and (3) 2 variables reflecting the combination of time and intensity (sedentary time spent/d in activities requiring <1.5 MET [time/d <1.5 MET] and <2 MET [time/d <2 MET] [since it has been suggested that the range of sedentarism could be extended to activities <2.0 MET instead of 1.5 MET]27).

Mortality

Vital status was ascertained by telephone contact and officially confirmed by checking the data set of the Center for Information on Mortality, which is responsible for registering all death events in the municipality. These data were collected after formal authorization from the city's Health Secretary. The date of death was recorded (when applicable), and survival time was defined as the time from the baseline assessment to the date of death or the last contact. The last day of follow-up was August 7, 2015. The outcome of this study was all-cause mortality.

Secondary Outcomes

Lung function was assessed by spirometry according to international recommendations,28 and Brazilian reference values from Pereira et al29 were used. Exercise capacity was evaluated by the 6-min walk test30 also considering the reference values from the Brazilian population.31 Dyspnea during activities of daily living was assessed with the modified Medical Research Council scale.32,33 Anthropometric characteristics, such as height, weight, and subsequent calculation of the body mass index, were objectively assessed, and educational level was reported by all subjects.

Statistical Analysis

The Shapiro-Wilk test was performed to analyze normality in data distribution. Results are shown as median (interquartile range) or n (%). Subjects were classified as survivors or non-survivors according to their vital status at the end of the follow-up period, and differences between groups were investigated using an unpaired t test, Mann-Whitney test, or chi-square test, as appropriate.

Receiver operating characteristic curves were used to determine threshold values with the best sensitivity and specificity to predict mortality. Kaplan-Meier curves with the log-rank tests were performed to analyze the differences of survival over time according to the cutoff value of each sedentarism variable. Cox's proportional-hazard regressions estimated the survival probability of each sedentarism variable (univariate) and were adjusted (multivariate) for sex, age, body mass index, educational level, FEV1 (percent predicted), 6-min walk distance (percent predicted), and time spent in moderate-to-vigorous physical activity, in accordance with univariate regressions and previous studies on COPD.16,34 Estimated hazard ratio and 95% CI were calculated after stratifying for each sedentarism threshold. Skewed variables were log-transformed to normalize their distribution. Statistical analyses were carried out using SPSS 21 (SPSS, Chicago, Illinois) and GraphPad Prism 6.0 (GraphPad Software, La Jolla, California), and the significance level was set at P < .05.

Results

Baseline Characteristics

One subject was excluded from the study at baseline due to an incomplete daily physical activity assessment; therefore, 101 subjects with COPD were analyzed. Subject characteristics at baseline are shown in Table 1. No subject classified as GOLD I (ie, FEV1 >80% predicted) was included, whereas 26% were GOLD II, 50% were GOLD III, and 24% were GOLD IV.

View this table:
Table 1.

Baseline Characteristics of the Study Population According to Vital Status

Absolute values of moderate-to-vigorous physical activity were significantly correlated with 5 variables reflecting sedentary behavior, as follows: lying time (r = −0.48), lying + sitting time (r = −0.38), time/d <1.5 MET (r = −0.74), time/d <2 MET (r = −0.84), and average of MET (r = 0.80). There was no correlation between moderate-to-vigorous physical activity and sitting time (r = −0.07).

Survivors and Non-Survivors

There was no loss of data from any subject in the follow-up analysis. Forty-one of the subjects (41%) died over a median (interquartile range) follow-up period of 62 (43–88) months. Table 1 also compares the characteristics of survivors and non-survivors. Subjects who died were predominantly male and older and presented worse lung function, exercise capacity, and moderate-to-vigorous physical activity level, although with similar educational level, number of comorbidities, and dyspnea sensation during daily life. In addition, subjects who died spent more time in sedentary activities than survivors, as identified by 4 variables: lying + sitting time/d, time/d <1.5 MET; time/d <2 MET, and the average of MET/d (P < .05 for all). The same variables were associated with mortality in the univariate Cox regression model (P < .05 for all). The percentage of subjects who reported at least one comorbidity was similar in both groups (80% from group survivors and 74% from group non-survivors, P = .60). There were no between-group differences concerning each related comorbidity, such as arthritis, stable heart diseases, hypertension, diabetes, osteoporosis, or thyroid or vascular diseases (P > .05 for all).

Sedentarism Cutoff Points and Mortality

Table 2 presents the best threshold values of the 6 sedentarism variables to predict mortality in subjects with COPD over the follow-up period. The highest value of area under the curve was found for time/d <1.5 MET (0.76). Five of those 6 variables present the range within no or poor discrimination, with low sensitivity and specificity, which means that only time/d <1.5 MET presented acceptable discrimination.

View this table:
Table 2.

Sedentarism Cutoff Points for the Prediction of Mortality

Figure 1 shows the Kaplan-Meier curves with each log-rank test comparison. The negative impact of sedentarism was presented in 5 of the survival curves according to the identified cutoff points. Time to death (or time of survival) was shorter in more sedentary subjects (≥5 h 20 min of sitting time/d; ≥8 h of lying + sitting time/d; ≥8.5 h of time/d <1.5 MET; ≥9 h of time/d <2 MET; and average of MET ≤1.5 MET/d (P < .05 for all).

Fig. 1.
Fig. 1.

Kaplan-Meier figure of cumulative survival with the log-rank test of the variables separated according to the sedentarism cutoff points. A: ≥5 h 20 min/d of sitting time; B: ≥1 h 20 min/d of lying time; C: ≥8 h/d of lying + sitting time; D: ≥8.5 h/day of time spent in sedentary activities <1.5 MET; E: ≥9 h/d of time spent in sedentary activities <2 MET; F: Average of MET <1.5 MET/d. Log-rank tests were performed to compare time to death. ST <2 MET = time spent/d in sedentary activities requiring <2 MET. MET = metabolic equivalent of task.

The Cox regression models according to the proposed cutoff values showed that significant hazard ratios in the univariate survival analysis (Table 3) were observed for the same 5 variables with shorter time to death (Fig. 1) (P < .05 for all). After adjusting for all relevant confounders, only 2 threshold values of sedentarism variables were significant (Table 2). The strongest independent cutoff for predicting mortality was ≥8.5 h/d spent in sedentary activities <1.5 MET. Furthermore, univariate analysis showed that each h/d spent <1.5 MET increases mortality risk by 42% (hazard ratio 1.42, 95% CI 1.15–1.76, P = .001); however, this analysis was not significant in the adjusted model.

View this table:
Table 3.

Prognostic Values for Mortality of Six Sedentarism Cutoff Points by Cox Proportional Models

Discussion

The present study was the first to propose a cutoff point of objectively measured time spent in sedentary behavior in subjects with COPD and to investigate its association with mortality. It was found that mortality risk in subjects with COPD was 4.09 times higher in those subjects who spent ≥8.5 h/d in activities requiring <1.5 MET. It should be highlighted that there are available cutoff values to identify sedentary behavior in the general population that are based on subjective variables, such as self-reported time spent watching television.5,27 However, objective measures allow for more robust assessments of sedentarism variables in comparison with self-reported methods.7,10

Waschki et al2 found that objectively measured physical activity is the strongest predictor of all-cause mortality in subjects with COPD using the physical activity level of >1.70 to define an active person, between 1.40 and 1.69 to define a sedentary person, and <1.40 to define a very inactive person. Additionally, Garcia-Rio et al3 classified subjects with COPD according to the quartiles of vector magnitude units (ie, quartile 1: <130 vector magnitude units; quartile 2: 130–200 vector magnitude units; quartile 3: 200–270 vector magnitude units; quartile 4 >270 vector magnitude units) and concluded that daily physical activity reduction was also associated with a higher mortality risk. Although these studies present undisputed relevance, conceptualizing sedentary behavior as distinct from lack of physical activity is important to avoid confusion and differentiate deleterious effects from subjects physically inactive from those with a sedentary lifestyle. In fact, individuals can achieve high levels of moderate-to-vigorous physical activity and still present high levels of sedentary behavior.5

A recent study35 examined the association between self-reported average time of television viewing duration/d and COPD-related mortality. After a follow-up of 19 y, the study found that men who watched television for >4 h/d were more likely to die of COPD than those who watched television for <2 h/d (hazard ratio 1.63, 95% CI 1.04–2.55).35 By providing objective measurement instead of self-reported methods, the present study confirmed that time to death is shorter in those subjects who spent more time in sedentary postures (ie, sitting or lying + sitting) despite the poor discriminative power of these cutoff points. Furthermore, also by using an objective assessment, Hartman et al17 showed that longer sitting time in daily life is associated with a higher number of COPD exacerbations. The adjusted predictive value of sitting time/d for mortality in the present study was not significant as it was for time/d <1.5 MET or <2 MET. This indicates that activity intensity is also a key point for higher risk of death in COPD. The present results point out that the combination of time (duration) of sedentarism and very low intensity of activities (as in time/d <1.5 MET or <2 MET) may be a more relevant outcome as a prognostic factor than only time spent sitting/d. This is in line with the study by Donaire-Gonzalez et al,36 which recently suggested that benefits of physical activity on COPD hospitalization also depend on intensity. Future studies with larger samples may provide a more in-depth investigation of the role of sitting time/d by itself as a prognostic factor for mortality in subjects with COPD, as observed in the general population.5,6,8,27

Despite the low area under the curve value, the cutoff point of average MET/d with the best sensitivity and specificity values for mortality in the present study was 1.5 MET/d, exactly the same threshold of intensity present in the definition of the term sedentarism.11 The threshold of 2 MET as the lower limit for light activity has been used previously in subjects with COPD,37 since 2 MET is the minimum intensity associated with activities performed in the upright posture, such as folding clothes or preparing a meal.26 Moreover, a study examining the use of the 1.5 MET threshold in the definition of sedentary behavior in adults against indirect calorimetry concluded that some common sitting behaviors appeared to have an MET level above this threshold.38 These findings have specific relevance to the current definition of sedentary behavior and suggest that common sitting activities, such as typing (eg, working in a computer), are actually defined as non-sedentary in a large proportion of the population.38 Although it has been shown that there is influence of the use of different activity thresholds in subjects with COPD,22 this issue was not yet investigated in depth.

A previous study has shown that sedentary time of subjects with COPD was significantly and positively associated with metabolic risk factors, such as waist circumference and glucose levels.39 Surprisingly, we could not find any study investigating the prognostic value of mortality using 1.5 MET intensity as a threshold for sedentarism. This might have happened because the focus of the studies has instead been on physical activity/inactivity and not on sedentarism. Future research may focus on confirming this for different stages of disease severity.

In the present study, lying time had no influence on mortality when analyzed solely (Table 3). This was not surprising, since there was no difference in lying time/d between survivors and non-survivors (Table 1). A recent review about the use of time in daily life by subjects with COPD14 found a median of time spent lying of 88 min/d, therefore very close to our cutoff point of 80 min/d. Perhaps a discriminative cutoff point for lying time was not detected in the present sample. Additionally, it might be that this variable is not capable of discriminating its influence on mortality when analyzed separately, and this hypothesis is reinforced by its low specificity value (ie, 52%; Table 2), the lowest among the 6 studied variables.

Despite this study presenting some strengths, such as the clinical relevance and the addition of novel information to the literature, it also shows some limitations, such as the lack of assessment of bouts of sedentary time. Various studies in the general population have emphasized the importance of interrupting continuous periods of sedentary time,8,27,40 and this analysis would certainly also be interesting for subjects with COPD. Further, the best cutoff point suggested of 8.5 h/d spent <1.5 MET matches with approximately 70% of wearing time; therefore, the applicability of the proposed cutoff points of sedentarism and each respective proportion of wearing time must be tested in other populations with different wearing times of the activity monitors. Moreover, perhaps the relatively small sample size of the study underpowered the comparison analysis of comorbidities between survivors and non-survivors. Unfortunately, it was not possible to identify whether more severe (ie, life-threatening) comorbidities were more prevalent among non-survivors in this sample. Future prospective studies with larger samples are encouraged to investigate sedentary behavior in depth as well as to better investigate its association with comorbities, since comorbidities commonly impact physical activity variables in COPD.41

Conclusion

Sedentary behavior is an independent predictor of mortality in subjects with COPD, even adjusting for moderate-to-vigorous physical activity and a number of other variables. Cutoff points from variables that combine duration of sedentary time and intensity <1.5 MET or <2 MET were associated with increased risk of mortality. Sedentary patients with increased risk of mortality can be identified by spending ≥8.5 h/d (or equivalent to ≥70% of the objective monitoring wearing time, in the case of this study) in sedentary activities requiring <1.5 MET. These findings may open room for future studies aiming at decreasing sedentary time as a promising strategy to reduce mortality risk in patients with COPD.

Acknowledgments

We are grateful to the colleagues from the Laboratory of Research in Respiratory Physiotherapy and to the employees and management from the Center of Information on Mortality and the Health Secretary of Londrina for contributing to data collection.

Footnotes

  • Correspondence: Fabio Pitta PhD, Departamento de Fisioterapia, CCS, Hospital Universitário de Londrina, Av. Robert Koch, 60, Vila Operaria, 86038-350, Londrina, Paraná, Brazil. E-mail: fabiopitta{at}uol.com.br.

  • This work was supported by Fundação Araucária and CNPq, Brazil. Dr Furlanetto and Ms Donária are supported by PhD grants from CAPES/Brazil. Dr Pitta is supported by a research grant from CNPq/Brazil. The authors have disclosed no conflicts of interest.

  • Dr Furlanetto presented a version of this work at the European Respiratory Society Annual Congress 2016, held September 3–7, 2016, in London, UK.

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