Stanford Seven-Day Physical Activity Recall questionnaire in COPD

Benjamin E. Garfield, Jane L. Canavan, Cayley J. Smith, Karen A. Ingram, Ria P. Fowler, Amy L. Clark, Michael I. Polkey, William D-C. Man
European Respiratory Journal 2012 40: 356-362; DOI: 10.1183/09031936.00113611

Abstract

Quantification of daily physical activity is of clinical interest in chronic obstructive pulmonary disease (COPD). Objective measures using activity monitors may take several days to obtain reliable results. The aim of our study was to evaluate the Stanford Seven-Day Physical Activity Recall questionnaire (PAR) against the SenseWear armband (SWA) and compare its validity with three other physical activity questionnaires.

43 COPD patients wore the SWA for 7 days. Patients completed the PAR, Baecke, Physical Activity Scale for the Elderly (PASE) and Zutphen questionnaires. Spearman rank correlation, intraclass correlation coefficients (ICC) and receiver-operating characteristics (ROC) curves were used to assess the relationship between the questionnaires and SWA.

Assessed by PAR, time spent at ≥3.0 metabolic equivalents (METs) correlated significantly (r=0.54, p<0.001) with equivalent measures from SWA, with an ICC of 0.40. No relationship was seen between the other questionnaires and the SWA. The PAR predicted active patients (≥30 min at ≥3.0 METs or a physical activity level (PAL) ≥1.55) and very inactive patients (PAL <1.40) with an area under ROC curve of 0.83, 0.77 and 0.70, respectively.

While the PAR did not measure physical activity sufficiently accurately to make individual recommendations, it was able to identify COPD patients at extremes of the physical activity spectrum, potentially reducing the number of patients requiring direct measurement.

Physical inactivity is a leading cause of mortality in the western world [1]. Chronic obstructive pulmonary disease (COPD) is characterised by breathlessness and limited functional capacity. Patients often have significantly reduced daily physical activity levels compared with age-matched controls [2], even at early stages of the disease [3]. Physical activity is of prognostic significance in COPD [4]. Patients who perform some level of physical activity have lower risk of hospital admission and mortality [5], whilst those who remain inactive after a severe exacerbation have a greater risk of hospital re-admission [6]. In a prospective study, moderate-to-high levels of regular physical activity were associated with reduced lung function decline and COPD risk among smokers [7]. Hence, increasing daily physical activity in COPD patients and smokers is a worthwhile therapeutic aim.

Although direct observation, double-labelled water and calorimetry are considered the gold standard for assessing physical activity, they are too time consuming and expensive to be used in large population studies [8]. Activity monitors, such as accelerometers, can measure intensity and quantity of physical activity in an objective way, and have been shown to detect physical activity more accurately in sedentary populations than pedometers or subjective measures. Unfortunately, they are relatively expensive and need to be worn for several days to obtain meaningful data [9]. Furthermore, compliance with accelerometers in some studies has been poor [10].

Activity questionnaires are commonly used for physical activity assessment. The methodology is cheap allowing application to large populations. However, disadvantages include the potential for overestimating or underestimating the amount of physical activity performed [8], meaning caution should be exercised when questionnaires are used to estimate physical activity on an individual basis [11]. Despite their widespread use, no physical activity questionnaire has been validated in patients with COPD [9].

Few studies have used objective and subjective measures of physical activity concurrently in patients with COPD. Steele et al. [12] demonstrated no relationship between output from the Tritrac triaxial accelerometer and the Modified Activity Recall Questionnaire. Moy et al. [13] showed that an activity checklist correlated with measured steps per day, but had accurate data from only 10 of the 17 patients studied, questioning the validity of these results. Finally, one study demonstrated that time spent in different activities measured by a diary correlated significantly with step count from the Yamax digiwalker pedometer [14]. However, the diary took the same time to collect data as the inexpensive pedometer limiting its usefulness.

The Stanford Seven-Day Physical Activity Recall questionnaire (PAR) is interviewer led and is widely used in epidemiological studies [15]. This questionnaire has not previously been validated in COPD patients, although a comprehensive review did identify its potential [9]. The aim of our study was to compare four physical activity questionnaires (the PAR; BAECKE [16]; Physical Activity Scale for the Elderly (PASE) [17]; and Zutphen Physical Activity questionnaire (ZPAC) [18]), against a validated activity monitor, the SenseWear Armband (SWA), in a cohort of well-characterised patients with COPD. The SWA is a biaxial accelerometer and motion sensor that has previously been used in large cohorts of COPD patients [3, 19] and validated against indirect calorimetry [20, 21]. We hypothesised that the PAR would correlate better with output from the SWA than the other questionnaires. We further hypothesised that the PAR could be a useful stratification tool in predicting active and very inactive COPD patients.

METHODS

Subjects

45 patients with COPD were recruited from respiratory clinics at Harefield Hospital, London, UK. All patients except two had completed an 8-week outpatient pulmonary rehabilitation programme within the last 12 months. Participants were excluded if they had a diagnosis of heart, renal or liver failure, a metabolic disorder or had experienced an exacerbation in the previous 4 weeks. The study was approved by the local research ethics committee. All patients gave informed written consent.

Measurements

The study consisted of two visits, 1 week apart. At the first visit, participants underwent the following measurements: spirometry; height, weight, body mass index (BMI); 6-min walk test (6MWT) [22]; health status using the St George's Respiratory Questionnaire (SGRQ) [23]; Medical Research Council (MRC) dyspnoea scale [24]; and calculated BODE (body mass index (B), the degree of airflow obstruction (O) and dyspnoea (D), and exercise capacity (E)) index [25]. Following assessments, patients wore the SWA over the triceps muscle of their right arm for 7 days until the next visit, as previously described [3]. At visit 2, the participants completed the interviewer-led PAR questionnaire with updated protocol (see online supplementary material) [26], and three self-complete questionnaires (PASE [27], BAECKE [28] and ZPAC [29]). Both patients and interviewer were blinded to the output of the SWA at the time of completion and analysis of the PAR.

Indices of physical activity

Participants wore the SWA 24 h a day except when performing any tasks that might put the armband at risk of getting wet. When <22.5 h of armband use were recorded during the day, data was excluded from analysis as described by Watz et al. [3]. Physical activity indices recorded from the SWA wereas follows. Total energy expenditure (TEE, total number of calories used per day); physical activity level (PAL, defined as total energy expenditure per minute divided by sleep energy expenditure per minute) as previously described [19]; and time spent in at least moderate physical activity (time ≥3 metabolic equivalents (METs), defined as number of minutes per day in activity ≥3 METs). Although the SWA also records step counts, this outcome was not used for analysis as it underestimates true step counts at low walking speeds [20].

The PAR allowed calculation of total energy expenditure and time spent in moderate (mean METs), hard (mean 6 METs) and very hard physical activity (mean 10 METs). From this, time spent in at least moderate activity (≥3 METs) was calculated.

The PASE and BAECKE questionnaires produce a physical activity score without specific units. The outputs from the ZPAC are energy expenditure in physical activity, and time spent in light, moderate and heavy physical activity. Unlike the SWA, moderate activity is defined by ZPAC as ≥2 METs [26]. Therefore, when comparing data output from the SWA and ZPAC the definition of time spent in moderate activity produced by the SWA was changed using the “professional” software module to time spent ≥2 METs [26].

Data analysis

Statistical analysis was undertaken using SPSS software version 18 (SPSS Inc., Chicago, IL, USA). For a significant Pearson correlation between questionnaire and SWA at the 0.05 level, a power of 90% and a large effect size (r=0.5), a minimum of 38 patients was needed. Assuming a study dropout rate of 15%, 45 patients were recruited. Spearman Rank correlation was actually performed to assess the relationship between questionnaires' output and SWA physical activity indices as data was not normally distributed. When comparing time spent in moderate physical activity between SWA and the PAR and ZPAC questionnaires, Bland–Altman plots were constructed and intraclass correlation coefficients (ICC) were calculated. ICC results were interpreted using recommendations by Fleiss [30], which define ICC at <0.40 as poor–fair, 0.40–0.74 as fair–good and ≥0.75 as excellent. Receiver operator characteristics (ROC) curves and area under curve (AUC) were used to assess the ability of the questionnaires to predict “active” and “very inactive” patients with COPD. “Active” was defined in two ways: 1) spending at least 30 min in at least moderate physical activity (≥3 METs) as per current recommendations [31]; and 2) achieving a PAL ≥1.55, the mean baseline PAL of a cohort of COPD patients alive after 4 yrs of follow-up [4]. “Very inactive” was conventionally defined as a SWA-derived PAL <1.4 as previously described [3, 4, 32]. A binary logistic regression model was used to assess whether the PAR time ≥3 METs offered additional information over 6MWT in predicting active patients with COPD. Percentage of variance explained by the model was estimated using the Nagelkerke R2 statistic. For the two factors, β-coefficients, Wald statistics, Wald statistic significance levels and odds ratios were obtained.

RESULTS

Two of the 45 patients recruited failed to complete the study (one developed severe headaches requiring hospital admission and the other withdrew because of discomfort from wearing the SWA). Baseline characteristics of the remaining participants are outlined in table 1.

View this table:
Table 1– Patient demographics

SWA monitor data

Mean daily usage was 23 h and 31 min. Median (interquartile range) TEE, PAL and time ≥3 METs were 1,910 (1707–2208) kcal·day−1, 1.41 (1.33–1.64) and 37 (25–72) min·day−1, respectively.

Physical activity questionnaires

The data generated by the questionnaires are summarised in table 2.

View this table:
Table 2– Data generated by the questionnaires

Relationship between physical activity questionnaires and SWA

TEE derived by PAR correlated significantly with TEE measured by SWA (r=0.83, p<0.001). Bias was 410 with 95% limits of agreements from -262 to 1,082. PAR-derived time ≥3 METs correlated significantly with SWA-derived time ≥3 METs (r=0.54, p<0.001) and with SWA-derived PAL (r=0.46, p=0.002) (fig. 1a and b). ICC for time ≥3 METs between PAR and SWA was 0.40. Bias for time ≥3 METs was 0.89 with 95% limits of agreements were from -112.9 to 114.7 (fig. 2a).

Figure 1–
Figure 1–

Spearman rank correlations between a) the Stanford 7-day Physical Activity Recall questionnaire (PAR) and SenseWear armband (SWA) time in ≥3 metabolic equivalents (METs); b) PAR time ≥3 METS and SWA physical activity level (PAL); c) Physical Activity Scale for the Elderly (PASE) score and SWA PAL; d) modified Baecke score and SWA PAL; e) Zutphen Physical Activity questionnaire (ZPAC) energy expenditure and SWA PAL; and f) ZPAC and SWA time in ≥2 METS.

Figure 2–
Figure 2–

Bland–Altman plot of the average time spent at ≥3 metabolic equivalents (METs) versus the difference in time spent in ≥3 METs derived from the Stanford 7-day Physical Activity Recall (PAR) questionnaire and the SenseWear armband (SWA).

No significant association was seen between PASE score, BAECKE score or ZPAC physical activity energy expenditure with TEE or PAL derived from SWA (fig. 1c–e). The PASE score, BAECKE score and ZPAC time at ≥2 METs did not correlate significantly with time in moderate activity derived by the SWA (fig. 1f). The ICC for the ZPAC and SWA time at ≥2 METs was 0.37.

ROC and logisitic regression

The ROC curve for PAR predicting patients with COPD achieving at least 30 min of moderate activity recorded by the SWA is shown in figure 3a. A PAR time spent in physical activity (≥3 METs) of ≥30 min had a sensitivity and specificity of 0.79 and 0.80, respectively, and an AUC of 0.83. With PAR time set at ≥33 min, AUC was 0.84 with a sensitivity of 0.79 and a specificity of 0.93. PASE, BAECKE and ZPAC had AUCs of 0.63, 0.64 and 0.57, respectively. A 6MWT >330 m had an AUC of 0.72 with a sensitivity of 0.66 and a specificity of 0.64 (fig. 3a).

Figure 3–
Figure 3–

Receiver operating characteristic (ROC) curves for a) the Stanford Seven-Day Physical Activity Recall questionnaire (PAR) and 6-min walk test (6MWT) serving as a predictor of active patients with chronic obstructive pulmonary disease (COPD) (defined as ≥30 min per day in physical activity of ≥3 metabolic equivalents); b) ROC curves for the PAR and 6MWT serving as a predictor of active patients with COPD with increased survival rates (physical activity level (PAL) ≥1.55); and c) ROC curves for the PAR and 6MWT serving as a predictor of very inactive patients with COPD (PAL <1.4).

The ROC curve for PAR predicting a PAL ≥1.55 is shown in figure 3b. A PAR time spent in ≥3 METs of >35 min had an AUC of 0.77, a sensitivity of 0.85 and a specificity of 0.63. PASE, BAECKE and ZPAC had AUCs of 0.64, 0.64 and 0.66, respectively. A 6MWT of >330 m had an AUC of 0.64, with a sensitivity of 0.69 and specificity of 0.53 (fig. 3b).

A PAR calculated time spent in ≥3 METs of <33 min had an AUC of 0.70 in predicting “very inactive” patients (PAL <1.4) with a sensitivity of 0.73 and a specificity of 0.76 (fig. 3c). PASE, BAECKE and ZPAC had AUCs of 0.60, 0.55 and 0.49, respectively. A 6MWT of <330 m had an AUC of 0.60 in predicting very inactive patients with a sensitivity of 0.59 and a specificity of 0.61 (fig. 3c).

The PAR measured time spent in moderate physical activity (Wald Chi-squared test 5.194, p<0.05) was significant in predicting patients achieving ≥30 min of moderate activity measured by the SWA, with an odds ratio of 1.051 (95% CI 1.007–1.097). This is in contrast to the 6MWT (Wald Chi-squared teat 2.744, p>0.05), which was not significantly able to predict active patients with an odds ratio of 1.008 (95% CI 0.999–1.018). The Nagelkerke R2 for the model was 0.47, suggesting that 47% of the variance was accounted for. Sensitivity for the model was 0.90 and specificity was 0.71. Percentage correct classification was 83.7%.

DISCUSSION

This is the first study to simultaneously assess the validity of four physical activity questionnaires in COPD patients. Data from three of the four questionnaires bore no relationship to any activity index measured using a validated activity monitor. In contrast, data from the PAR questionnaire correlated significantly with equivalent indices of physical activity, although the ICC for PAR and SWA was at best fair. Furthermore, the PAR had reasonable predictive power in identifying active and very inactive COPD patients. Taken together, these results suggest that while the PAR may not be suitable for assessing physical activity on an individual level it may be a potentially useful tool for immediate stratification of COPD patients according to activity levels.

Critique of the method

In this study, we used data from the SWA as the criterion method to compare questionnaires. Although the traditional gold standard measurements of physical activity include direct observation, double-labelled water and calorimetry, these techniques are not possible in large numbers of patients due to expense, impracticality and patient tolerability. Hill et al. [21] demonstrated that energy expenditure measured by SWA was sensitive to small but important changes, had good repeatability and agreed well with energy expenditure measured by indirect calorimetry. Langer et al. [20] also demonstrated good agreement between SWA and indirect calorimetry in measuring energy expenditure and time spent in at least moderate physical activity (≥3 METs). Our cohort was sedentary with a median physical activity level of 1.41. They spent a median of 37 min per day in at least moderate physical activity. Mean daily use of SWA was >23 h. To date, these results are comparable with the data from the largest cohort of COPD patients using the SWA [3, 19].

This study has the usual limitations of cross-sectional studies. First, our cohort had moderate–severe disease (mean forced expiratroy volume in 1 s was 46% predicted), so the results may not be applicable to the general COPD population; indeed limits of agreement widened as function improved. Secondly, our patients were in the stable state and, hence, our study cannot shed light on what might happen during recognised triggers of physical inactivity, such as acute exacerbations. Thirdly, as mentioned previously, our study did not assess the reliability or responsiveness to change of the questionnaires.

PAR questionnaire

The PAR is a semi-structured interview that was originally developed in the early 1980s [15] and has since been widely used in clinical studies. To our knowledge, the PAR has been used once in a small study of patients with COPD [33]. There has been no previous attempt to validate the PAR in COPD patients, but data from other populations support its validity. In a validation study of five questionnaires against a uniaxial accelerometer, the PAR had the best correlation coefficient [34]. Furthermore, in a validation study of 10 questionnaires completed by healthy elderly males, the PAR correlated significantly with total energy expenditure measured by double-labelled water and compared favourably with the other questionnaires [35].

We found a significant (although relatively modest) correlation between output from the PAR and equivalent measures from the SWA in our COPD cohort. This is in contrast to the other three questionnaires evaluated. This may reflect the interview-led, semi-structured nature of the PAR in comparison with the other questionnaires, which were self-completed and unsupervised. The PAR adheres to the cognitive model of question response. The comprehension and decision making stages are aided by the use of unambiguous questions with clearly defined time scales and activity levels. Guided memory techniques are used to minimise recall error [36].

In clinical trial design, the sample size (and costs) can be reduced if the outcome measure occurs frequently in the study population. Since physical inactivity is associated with mortality [4], then a therapeutic trial that used mortality as an outcome could be performed more efficiently if the participants were restricted to those who were physically inactive. In the current study, the PAR had a reasonably good sensitivity and specificity in predicting both active and very inactive COPD patients. This suggests that it may have a potential role in stratifying COPD patients for clinical trials, either directly or as a screen prior to objective measurement. As a stratification tool, the PAR has some advantages over more objective measures of physical activity. First, it is cheap in comparison to most accelerometers used in COPD studies [9]. Although we did not make a formal economic evaluation, apart from the cost of the SWA itself, other associated costs include a personal computer and the necessary software, as well as investigator time required to measure basic anthropometric measurements, input patient details into the SWA and calculate the PAL (which is not automated by the current software). Secondly, it is a quick method of assessment. The PAR was generally completed within 15 min in our cohort. This is in comparison with a minimum of five consecutive days of measurement required for the SWA [3]. Thirdly, calculation of the data did not require any expensive software, as is the case with some activity monitors [9]. Finally, there was a 100% completion rate of the PAR. Although the SWA was very well tolerated in this and previous studies [3], patient compliance and technical issues have been noted with some activity monitors [10, 13].

Some argue that functional measures, such as 6MWT, may predict physical activity with similar accuracy to physical activity questionnaires, such as the PAR. In our study cohort, the PAR had a better combined sensitivity and specificity, and a higher AUC than 6MWT. Furthermore, the model describing a combination of 6MWT and PAR suggested that only the PAR was an independent predictor of active patients, lending support to the hypothesis that indirect measures of physical activity are epiphenomenon. They can also provide no information on the intensity or domain of physical activity the patient performed.

Conclusions

In summary, the estimation of physical activity by the PAR correlates with data from a validated activity monitor in COPD patients, and had a reasonably good sensitivity and specificity in identifying active and very inactive COPD patients. The PAR, although unlikely to be able to measure PA usefully on an individual basis, may be a useful tool to stratify COPD patients according to their level of physical activity.

Acknowledgments

W.D-C. Man is funded by a National Institute for Health Research (NIHR) Clinician Scientist award and a Medical Research Council (MRC) New Investigator Research Grant. This project was undertaken at the NIHR Biomedical Research Unit at the Royal Brompton and Harefield NHS Foundation Trust and Imperial College London. J.L. Canavan's salary is fully funded and M.I. Polkey's salary is partly funded by the Biomedical Research Unit. C.J. Smith's salary during this period was supported by a grant from GlaxoSmithKline. The views expressed in this publication are those of the authors and not necessarily those of the National Health Service, the NIHR or the Department of Health.

Footnotes

  • Received July 3, 2011.
  • Accepted November 26, 2011.

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Stanford Seven-Day Physical Activity Recall questionnaire in COPD
Benjamin E. Garfield, Jane L. Canavan, Cayley J. Smith, Karen A. Ingram, Ria P. Fowler, Amy L. Clark, Michael I. Polkey, William D-C. Man
European Respiratory Journal Aug 2012, 40 (2) 356-362; DOI: 10.1183/09031936.00113611
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