Daily physical activity and related risk factors in COPD

This is a cross sectional analysis from a large prospective longitudinal study in COPD (The ARCADE study, Clinical Trials No NCT 01656421) [9]. A convenience sample of 93 patients with COPD confirmed with post bronchodilator spirometry and 42 controls, either current or ex-smokers free from respiratory disease were recruited.

All patients were clinically stable and had not had any oral corticosteroids or antibiotics 4 weeks prior to recruitment. Patients were excluded if they were known with inflammatory disease such as rheumatoid arthritis, had oral maintenance corticosteroids and long-term oxygen therapy or had attended pulmonary rehabilitation. Participants were recruited from respiratory outpatient clinics, smoking cessation referrals and general practice databases. Controls were recruited from general practice databases, smoking cessation clinic and patients’ relatives. All participants gave written informed consent and the study had approval from the South East Wales Research Ethics Committee.

In all participants, height and weight was measured barefoot with subjects wearing lightweight clothing and body composition was assesed using a single frequency segmental bioelectrical impedance analyser (BC-418 MA, Tanita Corp., Tokyo, Japan). Body mass index (BMI kg/m²), the fat free mass and fat mass were also determined. Waist and hip circumference were measured with a stretch resistant tape [10].

All participants performed spirometry (Vitalograph alpha, Bucks, UK) to measure the forced expiratory volume in 1 s (FEV₁), the forced vital capacity (FVC) and FEV₁/FVC ratio. Patients were given 400 μg of salbutamol via a spacer device and repeated the test 10 min post bronchodilator. Patients were asked to abstain using their inhalers for at least 6 h prior to their visit [11] .

Breathlessness was scored using the modified Medical Research Council (MRC) dyspnoea scale. The number of exacerbations in the last year (defined as requirement for antibiotic or oral corticosteroid therapy per year) were recorded. Patients and controls reported also the number of previously diagnosed comorbidities. Infrequent exacerbators were defined as < 2 in the previous year, while frequent exacerbators as ≥2 [12].

Patients completed the St George’s Respiratory Questionnaire (SGRQ) and the COPD assessment test (CAT), both validated measures of health status and symptoms [13, 14].

Participants were given a physical activity monitor (SenseWear™ BodyMedia, Inc. Pittsburgh, PA) on the day of their visit to Wales Heart Research Institute and asked to return the monitor after a week from their visit. The first and last days were excluded from the analysis because of incomplete measurements of the days. Therefore, data from 6 days (4 weekdays plus the weekend) of measurements were available for most participants. Participants were asked to wear the monitor the whole day except during shower or sleep. Wearing time was recorded by the monitor. For a valid day of activity measurement, the threshold was set at 16 h of monitor’s wearing time. Days below that threshold were excluded from analysis. The monitor has been found to be reliable and valid in patients with COPD [15]. To avoid seasonal changes, data were collected from the beginning of May until the end of September. The variables chosen for this analysis were the total daily number of steps (Steps) and daily time spent in at least moderate physical activity as defined by any activity ≥3 METs. Step count was divided to above or below 5000 steps/day as a cut-off value of recommended steps per day [16].

The 6MWD was performed once according to the American Thoracic Society (ATS) guideline using a 30-m level, straight indoor track [17]. Maximal handgrip strength (HGS) was determined twice in each hand and the mean was calculated for each one using a hand dynamometer (T.K.K. 5401 grip-D, Takei, Japan).

BODE index score was calculated by adding the score of each variable (BMI, post bronchodilator FEV₁, mMRC and 6MWD).

Peripheral systolic and diastolic BP was measured after 10 min rest in seated and supine positions (OMRON Corporation, Kyoto, Japan). Aortic PWV and central blood pressures including mean arterial pressure (MAP) measured noninvasively using SphygmoCor device (AtCor Medical, Sydney, Australia) [18].

High sensitivity C – reactive protein (HsCRP) and fibrinogen were determined by standard assays (Biochemistry, University Hospital of Wales).

The DPA was lower in the patients, mean (SD), 4095 (2720) steps than controls 6734 (3491) steps, p < 0.001, however, there was no difference in DPA for males and females in either group, p > 0.05. The DPA was not related to age in either patients or controls. Using the minimum recommended level of DPA of 5000 steps/day, only 31% of the patients had reached the recommended amount of physical activity; while in contrast, 73% of the controls met the minimum amount of the DPA.

The DPA related to FEV₁% predicted (r = 0.39, p < 0.001), oxygen saturation (r_s = 0.29, p = 0.012) and mMRC dyspnoea score (r = −0.45, p < 0.001), in the patients. Only was FEV₁% predicted related to DPA in the controls, r = 0.39, p = 0.017.

Level of DPA differed across the GOLD categories, between GOLD 1 and GOLD 4, p = 0.004 (Fig. 2). Patients with an FEV₁ > 50% had greater level of DPA, lower exacerbation rate, breathlessness score and CAT score than patients with an FEV₁ < 50%, p < 0.001. There was an association between level of DPA and BODE index, p < 0.001. Patients with BODE score of ≥6 walked less significantly than patients with a lower score, p < 0.001 (Fig. 3).

There was no relationship between body composition parameters and DPA in the patients or control group. However, in the patients, the time spent undertaking moderate activity was related to BMI, r = − 0.39, FM, r = − 0.37, FFM:FM, r = 0.50, all p < 0.001. Similar relationships were evident in the control group, all p < 0.05.

The 6MWD and HGS were less in patients than controls, both p < 0.001 (Table 1). In the patients, the level of daily of daily physical activity was related to the 6MWD, r = 0.45, p = 0.001, and controls, r = 0.49, p = 0.002, but it was not related to HGS, p > 0.05. The 6MWD and HGS were all related to each other in the patients, p < 0.01.

In the patients, the time spent undertaking moderate activity was related to aortic stiffness (rs = − 0.28, p < 0.01), resting oxygen saturation (rs = − 0.38, p < 0.002). This was not evident in controls. Aortic stiffness was greater in patients, 9.5 (2.2), than controls, 8.2 (1.4),p < 0.01.

The level of DPA and the SGRQ total score were related (r = − 0.38, p < 0.001), as was the SGRQ activity domain (r = − 0.40, p < 0.001). The CAT score was also related to the level DPA (r = − 0.34, p = 0.003). The 6MWD also related to the total SGRQ score, r = − 0.63, and the CAT score r = − 0.54, (all p < 0.001).

Circulating CRP and fibrinogen were greater in patients than controls (p < 0.001) and both were related to the level of DPA, CRP, r_s = − 0.29, p = 0.013, and fibrinogen, r = − 0.30, p = 0.009, but were unrelated to the level of DPA in the control group.

In the patients, a stepwise multivariate regression analysis including DPA as a dependent variable and FEV₁%, mMRC and the number of exacerbations as the independent variables showed that mMRC and number of exacerbations explained 28% of the variability in the DPA with FEV₁% predicted excluded from the analysis, adjusted R² = 0.28,p < 0.001. The mMRC and the number of exacerbations explained 34 and 25% of the reduction in the DPA, respectively.

A key limitation of this study is its cross-sectional nature, and this issue is being addressed in the ongoing longitudinal ARCADE study. We had a limited number of DPA monitors so which curtailed recruitment.