Data used in this exploratory study were collected from the EVIDENT 3 study, where 650 Spanish adults were recruited and included in a randomized, controlled and multicenter trial which involved 5 health care centers from different Spanish regions and it aimed to promote healthy lifestyles to weight loss. At baseline visit, participants in both study arms of EVIDENT 3 study (control and intervention) received 5 minutes of counselling in diet and physical activity prior to randomization. In addition, the intervention group (IG) received a smartphone app and a smartband (Mi Band 2, Xiaomi, China), for 3 months. The EVIDENT application was designed to allow a daily self-reported dietary intake, integrating the data to create specific diet recommendations and weight loss goals. Smartband was used to establish the PA goal of 10,000 steps per day and set sitting time messages. At the 3-month visit, these devices were collected. The investigator who performed the intervention was different from the investigator who conducted the evaluation. The trial was registered at ClinicalTrial.gov with identifier NCT03175614. For this study purpose, data regarding changes in PA from baseline to 3-month visit and determinants at baseline were included in the analyses. Data were collected between June 2017 and November 2019.

The study was approved by the Clinical Research Ethics Committee of Health Area of Salamanca in April 2016. All procedures were performed in accordance with the ethical standards of the institutional research committee and with the 2013 Declaration of Helsinki. All patients signed written informed consent documents prior to participation in the study.

All current patients of the 5 health centers were eligible for the EVIDENT 3 study. Each collaborating healthcare professional listed potential participants among the users attending their consultation. Inclusion criteria were sedentary people with BMI 27.5-40 kg/m2 between 20-65 years and informed consent signed. Exclusion criteria were type 2 diabetes, neoplasm with active treatment or to be on a diet at baseline visit (Recio-Rodriguez et al., 2018). A researcher of the group identified those who met the criteria described and invite those potential participants by phone and provided the necessary study information. Figure 1.

Figure 1.

CONSORT flowchart.

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Sociodemographic data. Trained nurses gathered sociodemographic data at baseline visit, asking age, sex, educational level (illiterate, primary studies, high school, university degree or PhD) and working status (unemployed, student, homemaker, retired or working). In addition, smoking status (non-smoker, former smoker, smoker) and the number of cigarettes were evaluated. Personal history of hypertension, dyslipidemia, and diabetes mellitus was consulted on medical records and verified by the patient at the visit. A detailed information on how the data was collected could be consulted in the study protocol (Recio-Rodriguez et al., 2018).

Anthropometric measures. These values were measured with the subjects barefoot and wearing light clothing. Height was measured twice using a portable system (Seca 222; Medical scale and measurement system, Birmingham, UK). Body weight was measured twice using a calibrated electronic scale (Scale 7830; Soehnle Professional GmbH & Co, Backnang, Germany). Data recorded were the average of the two readings in both cases. Body Mass Index (BMI) was calculated by weight (kg) divided by the height squared (m2).

Physical activity Self-report: The short version of the International Physical Activity Questionnaire (IPAQ; Craig et al., 2003) was used to measure PA both at baseline and 3-month visit. The IPAQ is a self-reported questionnaire that provides an estimate of PA time and calculated energy expenditure global and for each activity level: light (walking), moderate and vigorous intensity, showing a reliability of about .65 (r = .76; CI 95% = .73 - .77). For each level, participants reported frequencies such as days per week and average duration in minutes over the past week. Accelerometer: The ActiGraph GT3X accelerometer (ActiGraph, Shalimar, FL, USA) was used to measure PA. At the final of both visits (baseline and 3-month follow-up), participants were asked to wear the accelerometer for 7 consecutive days to the right side of the waist throughout the day and to remove it only for water activities (e.g. swimming or bathing). After this period, the device was collected. Data from participants with at least 600 min of wearing time for at least 5 days (including 1 weekend day) were included in the analyses. Non-wearing time was defined as 60 min or more of consecutive zero counts. In both cases, the main outcome of physical exercise was total minutes of PA per week, corresponding to the sum of all PA levels minutes.

Determinants. Items to measure psychological determinants are shown in Table 1, and they were chosen from the baseline questionnaire (Appendix A, Supplementary data): Six self-reported items based on stages of change (Prochaska & Clemente, 1982) evaluated the readiness to change of participants as well as self-efficacy and motivation. All of these items had to be answered by a 5-point Likert scale (α = .67, ω = .69). IWQoL-Lite. The short form of Impact of Weight in Quality of Life is a 31-item, self-report, obesity-specific measure of health-related quality of life (Kolotkin et al., 2001) through assessing five dimensions using a 5-point Likert scale (α = .94, ω = .95). Items of the questionnaires above related to any of the determinants under study were included in the analyses (α = .87, ω = .89).

Data were input and managed using a REDCap (System Electronic Data Capture; Harris et al., 2019) database. Descriptive analysis was performed by IBM SPSS Statistics v.23 (IBM Corp, Armonk, NY, USA). Measures of central tendency and distribution of study variables were examined at baseline and 3-month visit, as well as tests for normality. The results were expressed as mean and SD for quantitative variables and as frequency distribution for categorical variables. For CIBER analyses, all determinants described above were included. Outcome variables were difference in minutes of PA between baseline and 3-month visit, measured by IPAQ and accelerometer.

The sample was analyzed per study group (CG and IG) to compare the possible differences in relevance of determinants between groups, as IG received an enhancing lifestyles intervention for 3 months while CG was given the common brief advice only. In addition, sub-analyses by BMI, classified as overweight (BMI between 27.5 kg/m2 and 30 kg/m2) and obesity (BMI ≥ 30 kg/m2), were conducted to explore differences, since other studies such as the Diabetes Prevention Program (Delahanty et al., 2002), reported that psychological and behavioral characteristics, including exercise and self-efficacy, were related to baseline BMI.

Reliability analysis of the questionnaires was conducted by psych package (Revelle, 2020), CIBER analyses were conducted using the behavior change package (Peters, 2021) and R version 3.6.3. In order to foster accurate replication and facilitate future studies, the R script used for the analyses presented in this article are available at Open Science Framework (Lugones-Sanchez & Crutzen, 2021).

A total of 650 participants were included in the program and randomized to the IG or CG. Loss to follow-up was 13.40% (IG 8.80%, CG 17.70%). Testing at the 3-month visit was completed by 563 (86.60%) participants. Besides the 87 subjects which dropped out during the study, 77 participants were excluded from the analysis because of missing accelerometer data, not reaching a minimum of days registered or because person refused to wear it. Thus, 486 participants, (IG: n = 251, CG: n = 235) were finally included in the physical activity analyses. The mean age of the entire sample was 47.80 ± 9.71. Both groups had a similar mean age (47.30 ± 9.9 IG and 48.62 ± 9.4 CG) and most participants were women (68.10% and 68.50%, respectively) (Table 2). Mean baseline minutes of physical activity measured by IPAQ was 334.93 ± 336.3 min/week in IG and 328.48 ± 362.3 min/week in CG, while PA measured by accelerometer was 1806.54 ± 626.24 min/week and 1827.50 ± 590.76 min/week respectively in each group (Figure 2). No differences at baseline characteristics were observed between groups.

Figure 2.

Violin plot of total PA differences distribution by study group measured by IPAQ and accelerometer.

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Figure 3 shows the output following the proposed analytical approach dividing by study group (CG and IG). The selected items are shown to the left of the left-hand panel. Possible responses to the items, numbered from 1 to 5, are shown below the left-hand panel. The coding of each number can be consulted in Table 1.

Figure 3.

CIBER plot dividing by study group (IG: Intervention group [left], CG: Control group [right]).

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Diamonds for each item show a 99% Cl, and its fill color shows the item means -the redder the diamonds are, the lower the item means (left-skewed); the greener the diamonds are, the higher items means (blue is indicative of means in the middle of the scale). The dots show each participant response to the item with jitter added to prevent overpotting. The diamonds on the right-hand panel show the association strengths (correlation coefficients with 95% CI) between individual items (minutes of PA difference measured by questionnaire and accelerometer in this case) and determinants. The fill color of these diamonds indicates the association strengths and their direction–red diamonds mean strong and negative association, green diamonds strong and positive association and grey means weak association. Diamonds with a yellow stroke show the association with IPAQ and the diamonds with a green stroke show the association with the accelerometer. The CI of the explained variance (R2) of IPAQ and accelerometer on all determinants are depicted at the top of the figure. Figure 4 depicts the results dividing by BMI –overweight (27.50 kg/m2 < BMI < 30 kg/m2) and obese (BMI ≥ 30 kg/m2)-in the intervention group and Figure 5 in the control group.

Figure 4.

CIBER plots of intervention group (IG) divided by overweight (left) and obese (right).

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Figure 5.

CIBER plots of control group (CG) dividing by overweight (left) and obese (right).

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The IG shows a positive association between total PA and Self-efficacy (M2) but the scores of this determinant are slightly right-skewed. No association has been found with any other determinant. Otherwise, the CG shows no clear association as expected, with similar distribution in answers. Both groups show an explained variance (R2) rather low, likely indicating the influence of some characteristics of the population not included in the analyses.

Dividing each group by BMI, the two types of measurements have greater differences in the overweight group than in the obese group. In the intervention group (Figure 4), sample with overweight shows a positive association between PA minutes on one hand and motivation (M1) and self-efficacy (M2) on the other hand with accelerometer only. The distribution of answers is right-skewed but near the middle of the scale, indicating that the majority of people referred to some degree of motivation or self-efficacy to change at baseline. Although distribution is not centered, they might be considered relevant to the target, as influencing positively increased PA after the intervention. However, the obese group shows no remarkable associations nor with IPAQ neither accelerometer, even though the distribution of answers for motivation and self-efficacy items are similar.

While in the control group (Figure 5), strong associations have not been found. However, the results suggest a positive-trend association (but not significative) with self-esteem and work stress in self-reported measure, but not with PA assessed by accelerometers, in the overweight group.

The intervention group shows a positive association between total PA and Self-efficacy (M2). Dividing by BMI, motivation (M1) and self-efficacy (M2) show the highest associations with PA in people with overweight, while there are no clear associations with any determinant in the obese group. However, the control group shows no association. There are no strong associations in the overweight group, nevertheless the diamonds trend towards a negative association with health value (A8, A9) and risk perception (A11).

There are not associations with IPAQ in the IG, trending to the central line in the majority of determinants. Same results can be observed dividing this group by BMI. In the case of the CG, there are also no association with any determinant. Despite the lack of relevant associations, there are positive trends between Self-esteem (B3) and work stress (E2) with PA in the overweight group. Regarding their distribution (trending to left-skewed in both cases) this may suggest that an absence of work stress might be related to a higher level of self-reported PA.

All figures show a lower R2 than expected, which implies that there are factors involved in the behavior not included in the analyses. Nonetheless, it is worthy to point out the R2 differences between methods. Accelerometer has obtained higher results in the intervention group, both people with overweight [.10, .55] and obesity [.03, .19], while, in the control group, IPAQ reached better results in people with overweight ([.12, .49] and similar to the accelerometer in the obese group [.03, .18]. These discrepancies are likely based on the intervention since IG increased minutes of PA (measured by accelerometer) while CG, knowing the PA recommendations, may over report their PA time at 3-month visit.