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BMC Public Health volume 22, Article number: 2382 (2022)
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Nutritional status, health risk behaviors, eating habits, and other comorbidities (such as diabetes) may be associated with recommended amounts of physical activity (PA) and exercise (EX) in healthy older adults. However, these associations are still unclear for older hypertensive adults, who require greater care from health professionals. The purpose of this study was to associate the nutritional status, health risk behaviors, eating habits, and the presence of diabetes with recommended amounts of physical activity and exercise practice of older hypertensive adults.
Ten thousand seven hundred eighty-nine older hypertensive adults (70.9 ± 7.4 years) from the VIGITEL telephone survey were classified according to PA levels (insufficiently active/sufficiently active) and EX practice (non-practitioners/practitioners). Binary logistic regression was used to observe the odds ratio (OR) between independent variables (nutritional status [body mass index], sociodemographic characteristics [age/sex/years of study], risk behaviors [screen time/alcohol/tobacco consumption], eating habits [minimally/ultra-processed foods consumption score], and the presence of diabetes) with recommended amounts of PA/EX (dependent variable).
Highest nutritional status (ORPA = 0.975 [95%-CI: 0.965 – 0.985]; OREX = 0.981[95%-CI: 0.972 – 0.991]), age (ORPA = 0.955 [95%-CI: 0.949 – 0.961]; OREX = 0.980[95%-CI: 0.975 – 0.986]), screen time (ORPA = 0.909[95%-CI: 0.835 – 0.990]), alcohol consumption (ORPA = 0.683[95%-CI: 0.621 – 0.758]; OREX = 0.702[95%-CI: 0.637 – 0.779]), tobacco (ORPA = 0.601 [95%-CI: 0.492 – 0.736]; OREX = 0.464[95%-CI: 0.384 – 0.562]) ultra-processed foods consumption score (ORPA = 0.896[95%-CI: 0.871 – 0.921]; OREX = 0.886[95%-CI: 0.863 – 0.909]) and having diabetes (ORPA = 0.780[95%-CI: 0.708 – 0.859]; OREX = 0.831[95%-CI: 0.759 – 0.909]) reduced the odds of being sufficiently active/practicing exercise (p < 0.05). Male sex (ORPA = 1.633[95%-CI: 1.491 – 1.789]; OREX = 1.247[95%-CI: 1.140 – 1.363]), years of study (ORPA = 1.026[95%-CI: 1.018 – 1.035]; OREX = 1.050[95%-CI: 1.041 – 1.058]), and minimally processed foods consumption score increased the odds of being sufficiently active/practicing exercise (ORPA = 1.132[95%-CI: 1.109 – 1.155]; OREX = 1.167[95%-CI: 1.145 – 1.191], respectively; p < 0.05).
Nutritional status, health risk behaviors, eating habits, and the presence of diabetes were associated with the odds of older hypertensive adults complying with PA and EX recommendations. The results may help health professionals understand how these factors are associated with the changes of older hypertensive adults participating in physical activity and exercise.
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Aging is characterized by the progressive loss of adaptive capacity, which leads to a subsequent reduction in functionality [1]. Over the last few decades, geriatric populations have been occupying an increasingly high percentage of the demographic makeup of many countries [2, 3]. At the same time, an increase in noncommunicable diseases has been observed, responsible for the mortality and morbidity of older adults [4]. Among these diseases, cardiovascular diseases are the most prevalent in the world [5], and arterial hypertension is the main risk factor [4].
The first line of treatment for arterial hypertension, regardless of severity, focuses on the adoption of healthy lifestyles [1, 6]. Physical activity and exercise have been recommended as effective non-pharmacological methods of arterial hypertension control, contributing to the management of cardiovascular risk and quality of life of older adults [2, 3, 7,8,9,10,11,12,13]. Physical activity is characterized by any body movement produced by muscle contraction, resulting in higher energetic expenditure compared to basal rest levels [13]. Exercise is a subtype of physical activity that is characterized by the execution of planned movements, structured and performed to respond to a specific objective [13]. The benefits provided by regular physical activity and exercise on cardiovascular health are widely recognized [9] and support the international physical activity recommendations of the World Health Organization [14]. Supplementary Chart 1 reports detailed physical activity and exercise recommendations for cardiovascular benefits of older hypertensive adults. Briefly, recent evidence suggests a decrease in systolic and diastolic blood pressure and positive changes in metabolic profile with aerobic exercise (with an intensity of 70–80% of maximum oxygen consumption) [10]. For strength exercises, a decrease in systolic blood pressure (intensity of load: 9–15 maximum repetitions) and positive changes in oxidative stress and forearm vasodilatation (intensity of load: 6–10 maximum repetitions) [11, 12] were observed. For combined exercises (both aerobic and strength), positive changes in metabolic profile (intensity: 55–85% of maximal heart rate) and a decrease in arterial stiffness (intensity: 60–75% of maximal heart rate) are highlighted [7, 10].
Although many older adults exercise regularly, a significant amount does not seem to meet the 150 min of moderate to vigorous physical activity recommended by the World Health Organization [15, 16]. According to data from the Behavioral Risk Factor Surveillance System 2013 (sample of 139,723 older adults from a high-income country), approximately 45% of older adults meet the physical activity guidelines, and 36% are not enrolled in exercise programs [16]. For middle/low-income countries, the effort and compliance of older adults who meet the physical activity recommendations and are enrolled in exercise programs appear to be relatively low [17, 18]. Approximately, only 31% meet the physical activity guidelines and 76% are not enrolled in exercise programs [17, 18].
Some behavior factors can increase the odds of older hypertensive adults adhering to exercise programs and being sufficiently active [19,20,21,22]. These factors include nutritional status, screen time, alcohol and tobacco use, and food (minimally/ultra-processed) consumption [19, 20]. Strong evidence demonstrates that these factors can dictate the adherence of older hypertensive adults to exercise programs and physical activity recommendations [21, 22]. However, the evidence is still limited and restricted to samples of young adults and older European healthy adults (from Portugal and New South Wales, respectively) [21, 22]. Older Brazilian hypertensive adults may be quite different from older Europeans due to biological, cultural, geographical, and sociodemographic reasons.
Thus, the purpose of this study was to verify the association of nutritional status, health risk behaviors, eating habits, and the presence of diabetes on recommended amounts of physical activity and exercise of older hypertensive adults. We hypothesized that nutritional status, health risk behaviors eating habits, and the presence of diabetes were associated with the odds of older hypertensive adults engaging in sufficient levels of physical activity and exercise.
The study design was observational and cross-sectional. The data originated from the epidemiological project called Estudo de Vigilância de Fatores de Risco e Proteção para Doenças Crônicas por Inquérito Telefônico [Surveillance of Risk and Protection Factors for Chronic Diseases by Telephone Survey] (VIGITEL). VIGITEL is conducted every year between January and December by the Ministry of Health in partnership with the Group of Studies, Research and Practices in Food and Health Environment of the Universidade Federal de Minas Gerais (GEPPAAS/UFMG) and the Nucleus for Epidemiological Research in Nutrition and Public Health of Universidade de São Paulo (NUPENS/USP). For this study, data from 2019 was used since this was the last year before the COVID-19 pandemic.
VIGITEL data collection is conducted through telephone survey systems with voluntary subjects between 18 and 106 years old, residents in the 26 Brazilian state capitals, and the Federal District. All subjects who have at least one telephone landline (52,443 participants) are eligible to participate in the survey. In short, participants (living in the 26 state capitals and Federal District) were called (recruited) randomly and those who completed the survey were selected as participants.
The inclusion criteria for participants in the study were: a) ages between 60 and 90 years old; b) arterial hypertension diagnosis; c) recorded body mass (kg) and height (m); and d) available information on physical activity and exercise, education level, screen time, alcohol and tobacco consumption, minimally and ultra-processed foods consumption, and the presence (or not) of diabetes. We only selected participants between 60 and 90 years old because nonagenarians and the oldest are in a situation of extreme longevity [23, 24]. Some regions in the world showed that extreme longevity is not universal [25]. In this sense, nonagenarians and the oldest should be studied separately, especially for the present study that involves behavioral factors [26].
In this sense, from a random sample (52,443), all participants that fit the inclusion criteria mentioned above were selected for our study.
Sociodemographic variables considered for the study were chronologic age, sex, and education level (years of study), self-reported at the time of the interview. Years of education were included with the question “Up to what grade did you study?”, and the responses were reported in years (never studied; 1–12 or over [refers to postgraduate]) (p. 117 of [20]).
Body mass (kg) and height (m) were self-reported during the phone interview (p. 117 of [20]). Body mass index (BMI) was subsequently calculated as kg/m2. Nutritional status was classified according to Lipschitz (1994) into three categories (underweight = BMI < 22 kg/m2; eutrophic = BMI 22 to 27 kg/m2; overweight = BMI > 27 kg/m2) [20].
Screen time (watching television and use of cell phone, tablet, or computer) was self-reported: a) “On average, how many hours a day do you usually spend watching TV?”; and b) “On average, how many hours of your free time (excluding work) do you spend on the computer, tablet or cell phone per day?” (p. 125 of [20]). Older adults were classified as spending ≥ 3 h/day on screen (‘yes’ and ‘no) [27]. Smoking (“Currently, do you smoke?”) (p. 126 of [20]) and alcohol consumption (“Do you usually consume alcoholic beverages?”) (p. 122 of [20]) were obtained as binary variables (‘yes’ or ‘no’).
Based on one question of the VIGITEL questionnaire (24-h recall method) “Now I’m going to list some foods and I would like you to tell me if you ate any of them yesterday (from when you woke up until when you went to sleep)” (p. 120–121 of [20]), food consumption score was recorded according to the daily presence of different foods. The 24-h recall method is a valid and reliable tool for assessing habitual intake of foods (energy and macronutrients at the group level) [28].
Foods were further stratified according to NOVA classification into groups of similar characteristics as minimally (obtained from plants or animals, without big changes in natural state until consumption) and ultra-processed (formulations of ingredients that result from a series of industrial processes, creating highly profitable, convenient, and hyper-palatable products) foods [29]. The foods were stratified into representative subgroups of similar features. For minimally processed foods, twelve subgroups were considered: 1) lettuce, kale, broccoli, watercress, or spinach; 2) pumpkin, carrot, sweet potato, or okra/caruru; 3) papaya, mango, yellow melon, or souari nut; 4) tomato, cucumber, zucchini, eggplant, chayote or beetroot; 5) orange, banana, apple or pineapple; 6) rice, pasta, polenta, couscous or corn; 7) beans, peas, lentils or chickpeas; 8) potato, cassava or yam; 9) beef, pork, chicken or fish; 10) fried, boiled or scrambled egg; 11) milk; 12) peanuts, cashew nuts or Brazil nuts. For example, if a person consumes lettuce and kale (both in 1° subgroup), a score of 1 is obtained. But, if consuming lettuce, kale (both in 1° subgroup), and pumpkin (2° subgroup), at score of 2 is obtained. For ultra-processed foods, thirteen subgroups were considered: 1) soda; 2) fruit juice in a box or can; 3) powdered refreshment; 4) chocolate drink; 5) flavored yogurt; 6) packet snacks or crackers/cookies; 7) biscuit/sweet wafer, stuffed biscuit or packaged cookie; 8) chocolate, ice cream, gelatin, flan or other industrialized desserts; 9) sausage, pork sausage, bologna or ham; 10) loaf of bread, hot dog or hamburger; 11) mayonnaise, ketchup or mustard; 12) margarine; 13) instant noodles, packet soup, frozen lasagna or another frozen ready-to-eat dish. Minimally and ultra-processed foods were counted continuously (e.g., the score of foods consumed per day).
The presence of diabetes was determined by the question “Has a doctor ever told you that you have diabetes?” (p. 130 of [20]) and the answer was given as binary variables (‘yes’ or ‘no’).
Exercise and physical activity levels were determined from VIGITEL’s questionnaire, which includes questions related to physical activities performed in the domains of leisure (used to determine physical exercise levels), occupational, and transportation (p. 123–125 of [20]).
For the construction of indicators related to occupational and transport physical activity, the following questions were considered: 1) “Do you travel on foot or by bicycle to go to or return to work?”; 2) “How much time do you spend going back and forth on this route (on foot or by bicycle)?”; 3) “Currently, are you attending a course/school or taking someone to a course/school?”; 4) “To go or return to this course/school, do you walk or cycle?”; 5) “How much time do you spend going back and forth on this route (on foot or by bicycle)?”. 6) “In the last three months, have you worked?”; 7) “In your work, do you carry weight or do other intense activities?”; 8) “In a normal week, how many days do you do these activities at work?”; 9) “When you perform these activities, how long does it usually last?”. Exercise levels classification was considered by physical/sport activities performed in the domain of leisure (e.g., gait and fitness activities), with the question “In the last three months, did you engage in any type of physical exercise or sport?” [20].
Participants were classified as “non-practitioners = 0” or “practitioners = 1” regarding their participation in physical exercise/sport [14]. Subsequently, the sample was classified according to habitual physical activity (with the recommendations of the World Health Organization) [14]. For this purpose, all physical activities performed in the domains of leisure, occupational, and transportation [20] were considered and the participants were classified as “sufficiently active” or “insufficiently active” if the sum of weekly physical activity in these three domains was above or below 150 min/week, respectively [30].
Descriptive statistical analysis considered measures of central tendency (mean, and 95% confidence interval [95% CI] of the mean) and relative frequency. Possible outliers were identified with the interquartile range (1.5) (considering BMI, education level, leisure exercise, and occupational and transportation physical activity [before categorizing as insufficiently or sufficiently active]). Binary logistic regression was used to verify the odds of older hypertensive adults being (or not) an exercise practitioner and sufficiently/insufficiently active. The classification of exercise (0 = non-practitioner; 1 = practitioner) and physical activity (0 = insufficiently active; 1 = sufficiently active) levels were considered as the dependent variables while sociodemographic characteristics, BMI, health risk behaviors, eating habits, and diabetes as independent variables. Four models were generated (crude: BMI; Model 1: BMI + sociodemographic characteristics; Model 2: BMI + sociodemographic characteristics + health risk behaviors; and Model 3: BMI + sociodemographic characteristics + health risk behaviors + eating habits + the presence of diabetes). The interpretation of the models was reported through odds ratio (OR). All analyses were performed using the SPSS, v. 20.0 (Inc., Chicago, IL, EUA), with a significance level previously established (α = 5%). This manuscript has been produced with the requirements of the Strengthening the Reporting of Observational Studies in Epidemiology (STROBE) checklist for cross-sectional studies.
11.122 participants were eligible for the study. After the detection of outliers, 10.789 older adults were included in the final sample (Fig. 1). Of this sample, 48.7% (n: 5.254) were classified as exercise non-practitioner and 51.3% (n: 5.535) as exercise practitioners (Fig. 1; Table 1). Among exercise practitioners, 39.6% (n: 2.122) were classified as insufficiently active while 7.7% (n: 404) were sufficiently active among non-practitioners.
Flowchart of selection of subjects for this study. Abbreviations: VIGITEL = Surveillance of Risk Factors and Protection for Chronic Diseases by Telephone Survey; BMI = Body mass index
Table 1 provides the total sample description according to exercise and physical activity levels regarding sociodemographic and anthropometric variables, physical activity (leisure, occupational, and transportation), health risk behaviors, eating habits, and the presence of diabetes. From the total sample, 49.2% are in the category ‘overweight’ (n: 5.308), and no significant differences were observed (p > 0.05) in BMI in the comparison between the groups of exercise non-practitioners vs. practitioners (avoiding the analysis bias in regression models). The frequency (percentage of older adults) related to the type of exercise performed by the participants in the practitioner group is shown in Supplementary Table 1.
Table 2 presents the logistic regression model, with OR of older hypertensive adults to be exercise practitioner and sufficiently active, in accordance with nutritional status (BMI), sociodemographic characteristics, health risk habits, eating habits, and the presence of diabetes.
All factors were associated with the OR of older hypertensive adults being exercise practitioners, except for screen time (Table 2). For each higher classification of BMI (OR: 0.981[95% CI: 0.972 – 0.991), age (OR: 0.980 [95% CI: 0.975—0.986]), alcohol (OR: 0.702 [95% CI: 0.637 – 0.779]) and tobacco consumption (OR: 0.464[95% CI: 0.384 – 0.562]) ultra-processed food consumption score (OR: 0.886[95% CI: 0.863 – 0.909]), and presence of diabetes (OR: 0.831[95% CI: 0.759 – 0.909]), there is a decrease of OR to be exercise practitioner (p < 0.001). The factors of male sex (OR: 1.247[95% CI: 1.140 – 1.363]), each year of schooling (OR: 1.050[95% CI: 1.041 – 1.058]) and minimally processed food consumption score (OR: 1.167 [95% CI: 1.145 – 1.191]) increase the OR to be exercise practitioner (p < 0.001).
All factors were associated with the OR of older hypertensive adults being sufficiently physically active. For each higher classification of BMI (OR: 0.975 [95% CI: 0.965 – 0.985]), screen time (OR: 0.909[95% CI: 0.835 – 0.990]), alcohol (OR: 0.683[95% CI: 0.621 – 0.758) and tobacco (OR: 0.601 [95% CI: 0.492 – 0.736]) consumption ultra-processed food consumption score (OR: 0.896[95% CI: 0.871 – 0.921]), and presence of diabetes (OR: 0.780[95% CI: 0.708 – 0.859]), there is a decrease of OR on older adults to be sufficiently active (p < 0.05). The factors of male sex (OR: 1.633[95% CI: 1.491 – 1.789), each year of schooling (OR: 1.026[95% CI: 1.018 – 1.035]) and minimally processed food consumption score (OR: 1.132 [95% CI: 1.109 – 1.155]) increase the OR to be sufficiently active, respectively (p < 0.001).
This is the first study that aimed to investigate the relationship between physical activity and exercise participation in older Brazilian hypertensive adults with nutritional status (BMI), health risk behaviors, eating habits, and the presence of diabetes. The results showed that BMI, age, screen time (only for physical activity), alcohol and tobacco consumption, ultra-processed food consumption scores, and having diabetes decreased the odds of being exercise practitioners or sufficiently active. On the other hand, male sex, years of study, and minimally processed foods increased the odds of older hypertensive adults being exercise practitioners or sufficiently active. Therefore, this study advances the investigation of hypertension and behavioral factors that are associated with exercise and physical activity participation of older adults in a region so far not investigated (Brazil).
Previous findings indicated that higher nutritional status (overweight/obesity) is associated with lower odds of compliance with exercise and physical activity [21, 22, 31]. In this sense, a higher nutritional status over the ideal body weight may be associated with lower odds of adherence to exercise programs and reduced habitual physical activity [32]. Consequently, deleterious behaviors tend to combine and co-exist (for example, higher sedentary behavior [increased exposure to cell phone, television, and computer; time sitting or lying] [33], alcohol [21], and tobacco consumption [31]). Moreover, inadequate eating habits (with high consumption of ultra-processed foods) are inversely related to sufficient physical activity levels (high consumption of ultra-processed foods and low physical activity levels) [34]. Recent findings reported that insufficiently active subjects consume 6% more ultra-processed foods (in calories) compared to sufficiently active subjects [34]. One possible explanation for this is that subjects with sufficient physical activity had more satiety with lower amounts of high-density food intake (e.g., ice cream, instant noodles) when compared with insufficiently active subjects, who needed a higher intake amount (of ultra-processed foods) to have satiety [35]. The need to ingest larger amounts of ultra-processed foods to satisfy satiety in insufficiently active subjects increases their odds of going over the daily caloric balance, favoring overweight and obesity [36]. Therefore, the interaction between nutritional status and associated risk factors (screen time, use of licit drugs, and inadequate eating habits) compromises the odds of older hypertensive adults being practitioners of exercise and complying with the recommendations of physical activity in daily life [37].
Another relevant finding from our study is the distribution of combinations of different exercise (non-practitioners/practitioners) and physical activity (insufficiently active/sufficiently active) characteristics of older hypertensive adults. Some older hypertensive adults presented sufficient weekly physical activity but did not engage in exercise (n = 404). Even older non-practitioners of exercise can be sufficiently active through occupational and transportation activities. Leisure activities (i.e., exercise) are not the only way in which older people can be sufficiently active. Therefore, these sufficiently active older adults may benefit from a more active lifestyle compared to insufficiently active older adults, as regular physical activity reduces the risk of coronary heart disease, obesity, and some cancers [6, 22]. This makes it valuable to develop simple strategies to increase all physical activity that can be performed whenever possible, such as using the stairs instead of the elevator, parking the car farther away, or getting off the bus before the final stop to walk to the destination [30].
On the other hand, this study demonstrated that some older hypertensive adults who engaged in exercise programs were classified as insufficiently active (39.6%). Although exercise is well recommended as an effective non-pharmacological mean of controlling blood pressure and decreasing cardiovascular risk, it is necessary to have an adequate weekly volume and frequency (Supplementary Chart 1) [37, 38]. The prescription of types of exercise (aerobic, strength, or combined) and variables (intensity, volume, frequency, and duration) must be assertively chosen by exercise professionals to maximize the benefits of each intervention [7, 9, 10, 37]. Therefore, in addition to raising awareness of the regular performance of exercise, the exercise prescription must be adjusted in volume and weekly frequency to maintain good health status for older hypertensive adults [39].
One strength of this study is the large number of participants, with a good sample representation from all Brazilian regions. Data collection through telephone interviews carried out by a highly qualified team allowed clear and precise explanations on each issue, avoiding misunderstandings. The identification of outliers minimized the analyses biased results (a discrepant value that could interfere with the confidence level of the results), homogenizing the sample [40, 41]. Somehow, outliers can under/overestimate the results of the analysis. For example, we analyzed the data without removing the outliers and the results provided were not similar to the current results. When the outliers were not removed, the OR of alcohol consumption was > 1 to be an exercise practitioner or sufficiently active in physical activity (Supplementary Table 2). In other words, alcohol consumption was positively associated with physical activity and exercise. However, when the outliers were removed, the OR was < 1 (Table 2). Previous literature [42, 43] demonstrates that alcohol consumption has a negative influence on older adults being exercise practitioners or sufficiently active. Therefore, our caution in considering discrepant values was carried out.
Another strength is the regression model adjustment with a wide range of confounding factors that influence the odds of exercise and sufficient physical activity minimized analyses’ bias. As a result, this study is the first to suggest that nutritional status, health risk behaviors, eating habits, and the presence of diabetes have an association with the odds of older hypertensive adults being exercise practitioners and sufficiently active in a developing country [22]. The authors considered that adequate physical activity was independently associated with sex (male), age, self-independence, lower psychological distress, rural residence, not having diabetes, adequate minimally processed food intake, and speaking a language other than English at home [22]. In contrast, our study discusses barriers to physical activity and exercise practice, and our findings suggest that some behaviors are associated with sufficient physical activity and exercise practice. Considering the previous findings, and the lack of literature about the associated factors to sufficient physical activity and exercise practice of older hypertensive adults, our results are promising.
This study also had limitations. VIGITEL is a telephone survey, which may be influenced by its methodological effect Some examples of methodological effect include the sampling type (Brazilian), questions (under/overestimation of questions [e.g., physical activity level]), means of data collection (telephone [not smartphone] line), interview time (longer-interviews tend to have more errors in some questions), and duration of the survey (reduced time to collect more data). Despite being comprehensive and representative, the cross-sectional design did not allow the establishment of cause-effect relationships. The extrapolation of these findings to populations from other countries should be considered with caution, considering other differences that can impact the odds of older adults being exercise practitioners and sufficiently active. The lack of cognitive assessment before the interview is a limitation because some answers could be misunderstood by the participants. The use of BMI to determine nutritional status also limited the study due to BMI not distinguishing body composition components. However, it is the most used epidemiological index in the world, being adequate and feasible for representative samples [44]. Another limitation is the lack of information on the presence of antihypertensive drugs and blood pressure values (for adjustment of logistic regression models). This information could, in a way, change the association of the older adult being an exercise practitioner and sufficiently active, based on the use of medication (yes/no, or quantity) and blood pressure measurement (given continuously, e.g., 120 × 80 mmHg). Another limitation is the no determination of association between the amount of tobacco and alcohol consumption on physical activity and exercise, in terms of daily amount and exposure time in years. Moreover, our study considered these variables in a categorical way (i.e., tobacco, alcohol, and screen time), preventing the test of multicollinearity and interaction between themselves. However, a study with other population (adolescents) showed positive associations between these variables (tobacco, alcohol, and screen time) [45]. The 24-recall method applied in only one day has a poorer association with total energy intake (r = 0.31) measured by the doubly labeled water (gold standard method) compared to the same method applied more times (two or more days; r between 0.39 and 0.47) [28]. Future studies need to consider more days of application of the 24-recall method. Finally, the physical activity assessment was carried out using a questionnaire from the VIGITEL study, which could under/overestimate the real level of physical activity performed by older adults. However, this questionnaire is validated against other common questionnaires (e.g., IPAQ; BAECKE) for physical activity assessment [46].
As practical implications of this study’s findings, health professionals responsible for the treatment and control of hypertension in older adults can educate older adults about the associated factors of exercise and physical activity participation. The magnitude of positive and negative associations of each factor (nutritional status, health risk behaviors, eating habits, and the presence of diabetes) may help change the lifestyle of older hypertensive adults. Future research should explore the underlying reasons for the frequency of health risk habits in insufficiently active older hypertensive adults to help the development of public health interventions. In the public health field, helping older hypertensive adults reach the physical activity recommendations will contribute to the reduction of healthcare services expenses [47]. One possibility for health professionals to stimulate older adults is to install and use applications for smartphones that measure and encourage physical activity (e.g., steps daily count). Recent evidence suggests that these devices may be effective in increasing physical activity in older adults (although larger trials with longer follow-ups are needed to clarify if these devices provide clinically important effects) [48, 49]. If massive intervention would be practiced, screen time could have a positive OR to be sufficiently active in the future. Moreover, health professionals’ knowledge may help with adequate exercise prescription, even if this prescription is done gradually.
From a multifactorial approach, many reasons could be associated with a reduced chance of being an exercise practitioner. Beyond what is explored in our study, other factors including accessibility to exercise (adequate space to exercise practice), monthly income (could lead to access to adequate spaces for exercise, even personalized service), and public policies promoted by the government [50] could be discussed. However, our study did not investigate these factors, and we cannot generalize the adoption of means of physical activity and exercise for all contexts. Therefore, more studies are needed to clarify this multifaceted phenomenon.
Additionally, we suggest the longitudinal analysis (cohort or intervention studies) of the associated factors and levels of exercise and physical activity of older hypertensive older adults to establish the causal relationships between the factors analyzed in our study and recommended amounts of physical activity and exercise. We also suggest reproducing the study in other countries for greater external validity, and as a result, generalization across other populations.
Nutritional status, sociodemographic characteristics, health risk behaviors, eating habits, and the presence of diabetes are associated with recommended amounts of physical activity and exercise in older hypertensive adults. Higher BMI, age, screen time (only for physical activity), and alcohol, tobacco, ultra-processed food consumption score, and having diabetes are negatively associated with exercise and physical activity suitability in older hypertensive adults. Being a male, level of education and minimally processed food consumption score are positively associated with exercise and sufficient levels of physical activity. The findings from this study may help health professionals understand how these factors are associated with the increase/decrease of the odds of older hypertensive adults participating in exercise and being sufficiently active. In this sense, best strategies can be elicited for treatment and arterial hypertension control.
All data are public and can be found on the official website of the study https://www.gov.br/saude/pt-br/assuntos/saude-de-a-a-z/v/vigitel-1/vigitel.
Dziechciaż M, Filip R. Biological psychological and social determinants of old age: bio-psycho-social aspects of human aging. Ann Agric Environ Med. 2014;21(4):835–8. https://doi.org/10.5604/12321966.1129943.
Article  Google Scholar 
Mostarda C, Wichi R, Sanches IC, Rodrigues B, De Angelis K, Irigoyen MC. Hipertensão e modulação autonômica no idoso: papel do exercício físico. Rev Bras Hipertens. 2009;16(1):55–60.
Google Scholar 
Pillatt AP, Nielsson J, Schneider RH. Efeitos do exercício físico em idosos fragilizados: uma revisão sistemática. Fisioter Pesqui. 2019;26:210–7. https://doi.org/10.1590/1809-2950/18004826022019.
Article  Google Scholar 
Oliveros E, Patel H, Kyung S, Fugar S, Goldberg A, Madan N, et al. Hypertension in older adults: assessment, management, and challenges. Clin Cardiol. 2020;43(2):99–107. https://doi.org/10.1002/clc.23303.
Article  Google Scholar 
Münzel T, Hahad O, Sørensen M, Lelieveld J, Duerr GD, Nieuwenhuijsen M, et al. Environmental risk factors and cardiovascular diseases: a comprehensive expert review. Cardiovasc Res. 2022;118(14):2880–902. https://doi.org/10.1093/cvr/cvab316.
Article  Google Scholar 
Bakker EA, Sui X, Brellenthin AG, Lee DC. Physical activity and fitness for the prevention of hypertension. Curr Opin Cardiol. 2018;33(4):394–401. https://doi.org/10.1097/HCO.0000000000000526.
Article  Google Scholar 
Cassiano A do N, Silva TS da, Nascimento CQ do, Wanderley EM, Prado ES, Santos TM de M, et al. Effects of physical exercise on cardiovascular risk and quality of life in hypertensive elderly people. Ciênc saúde coletiva. 2020;25:2203–12. https://doi.org/10.1590/1413-81232020256.27832018.
Article  Google Scholar 
Gimenes C, Arca EA, Paulino MA, Nicolau NV, Buitoni B, Pontes TP, et al. Redução da pressão arterial e circunferência abdominal e melhora da Capacidade Funcional de idosas hipertensas submetidas a Programa de Fisioterapia Funcional. Rev Kairós Gerontol. 2015;18(1):77–92. https://doi.org/10.23925/2176-901X.2015v18i1p77-92.
Article  Google Scholar 
Godinho AS, Lacerda MP, Abdalla PP, Roca LB, Júnior JRG, Araújo RG de, et al. A prática regular de exercício físico no controle da hipertensão arterial. Revista CPAQV – Centro de Pesquisas Avançadas em Qualidade de Vida – CPAQV J. 2021;13(3). https://doi.org/10.36692/804.
Nogueira IC, Santos ZM de SA, Mont’Alverne DGB, Martins ABT, Magalhães CB de A. Efeitos do exercício físico no controle da hipertensão arterial em idosos: uma revisão sistemática. Rev Bras Geriatr Gerontol. 2012;15:587–601. https://doi.org/10.1590/S1809-98232012000300019.
Article  Google Scholar 
Dantas FFO, Brasileiro-Santos M do S, Batista RMF, Nascimento LS do, Castellano LRC, Ritti-Dias RM, et al. Effect of strength training on oxidative stress and the correlation of the same with forearm vasodilatation and blood pressure of hypertensive elderly women: a randomized clinical trial. PLOS ONE. 2016;11(8):e0161178. https://doi.org/10.1371/journal.pone.0161178.
Article  CAS  Google Scholar 
Abrahin O, Abrahin RP, de Sousa EC, Cortinhas-Alves EA, Nascimento D da C, Guerreiro JF. Inter-individual variations in response to aerobic and resistance training in hypertensive older adults. J Hypertens. 2022;40(6):1090–8. https://doi.org/10.1097/hjh.0000000000003139.
Article  CAS  Google Scholar 
Caspersen CJ, Powell KE, Christenson GM. Physical activity, exercise, and physical fitness: definitions and distinctions for health-related research. Public Health Rep. 1985;100(2):126–31.
CAS  Google Scholar 
World Health Organization. Global recommendations on physical activity for health. 2010. Available from: http://www.ncbi.nlm.nih.gov/books/NBK305057/. [Cited 14 Feb 2020].
Harvey JA, Chastin SFM, Skelton DA. Prevalence of sedentary behavior in older adults: a systematic review. Int J Environ Res Public Health. 2013;10(12):6645–61. https://doi.org/10.3390/ijerph10126645.
Article  Google Scholar 
Keadle SK, McKinnon R, Graubard BI, Troiano RP. Prevalence and trends in physical activity among older adults in the United States: a comparison across three national surveys. Prev Med. 2016;89:37–43. https://doi.org/10.1016/j.ypmed.2016.05.009.
Article  Google Scholar 
Cardoso AS, Borges LJ, Mazo GZ, Benedetti TB, Kuhnen AP. Fatores influentes na desistência de idosos em um programa de exercício físico. Movimento. 2019. https://doi.org/10.22456/1982-8918.2303.
Ferrari G, Dulgheroff PT, Claro RM, Rezende LFM, Azeredo CM. Socioeconomic inequalities in physical activity in Brazil: a pooled cross-sectional analysis from 2013 to 2019. Int J Equity Health. 2021;20(1):188. https://doi.org/10.1186/s12939-021-01533-z.
Article  Google Scholar 
Lipschitz DA. Screening for nutritional status in the elderly. Prim Care. 1994;21(1):55–67.
Article  CAS  Google Scholar 
VIGITEL. Vigitel Brasil 2019: vigilância de fatores de risco e proteção para doenças crônicas por inquérito telefônico. Brasilia (DF); 2020. Available from: https://bvsms.saude.gov.br/bvs/publicacoes/vigitel_brasil_2019_vigilancia_fatores_risco.pdf.
Camões M, Lopes C. Fatores associados à atividade física na população portuguesa. Rev Saúde Pública. 2008;42:208–16.
Article  Google Scholar 
Lim K, Taylor L. Factors associated with physical activity among older people—a population-based study. Prev Med. 2005;40(1):33–40. https://doi.org/10.1016/j.ypmed.2004.04.046.
Article  Google Scholar 
Capri M, Salvioli S, Monti D, Caruso C, Candore G, Vasto S, et al. Human longevity within an evolutionary perspective: the peculiar paradigm of a post-reproductive genetics. Exp Gerontol. 2008;43(2):53–60. https://doi.org/10.1016/j.exger.2007.06.004.
Article  Google Scholar 
Scelzo A, Di Somma S, Antonini P, Montross LP, Schork N, Brenner D, et al. Mixed-methods quantitative-qualitative study of 29 nonagenarians and centenarians in rural Southern Italy: focus on positive psychological traits. Int Psychogeriatr. 2018;30(1):31–8. https://doi.org/10.1017/s1041610217002721.
Article  Google Scholar 
Aliberti SM, De Caro F, Funk RHW, Schiavo L, Gonnella J, Boccia G, et al. Extreme longevity: analysis of the direct or indirect influence of environmental factors on old, nonagenarians, and centenarians in Cilento, Italy. Int J Environ Res Public Health. 2022;19(3):1589. https://doi.org/10.3390/ijerph19031589.
Article  CAS  Google Scholar 
Rea JNM, Carvalho A, McNerlan SE, Alexander HD, Rea IM. Genes and life-style factors in BELFAST nonagenarians: Nature, Nurture and Narrative. Biogerontology. 2015;16(5):587–97. https://doi.org/10.1007/s10522-015-9567-y.
Article  Google Scholar 
Katzmarzyk PT, Lee IM. Sedentary behaviour and life expectancy in the USA: a cause-deleted life table analysis. BMJ Open. 2012;2(4): e000828. https://doi.org/10.1136/bmjopen-2012-000828.
Article  Google Scholar 
Foster E, Lee C, Imamura F, Hollidge S, Westgate K, Venables M, et al. Validity and reliability of an online self-report 24-h dietary recall method (Intake24): a doubly labelled water study and repeated-measures analysis. Journal of Nutritional Science. 2019;8:E29. https://doi.org/10.1017/jns.2019.20.
Article  CAS  Google Scholar 
Monteiro CA, Cannon G, Levy RB, Moubarac JC, Louzada ML, Rauber F, et al. Ultra-processed foods: what they are and how to identify them. Public Health Nutr. 2019;22(5):936–41. https://doi.org/10.1017/s1368980018003762.
Article  Google Scholar 
Haskell WL, Lee IM, Pate RR, Powell KE, Blair SN, Franklin BA, et al. Physical activity and public health: updated recommendation for adults from the American college of sports medicine and the American heart association. Med Sci Sports Exerc. 2007;39(8):1423–34. https://doi.org/10.1249/mss.0b013e3180616b27.
Article  Google Scholar 
Varo JJ, Martínez-González MA, de Irala-Estévez J, Kearney J, Gibney M, Martínez JA. Distribution and determinants of sedentary lifestyles in the European Union. Int J Epidemiol. 2003;32(1):138–46. https://doi.org/10.1093/ije/dyg116.
Article  Google Scholar 
Hortencio MN da S, Silva JKS da, Zonta MA, Melo CPA de, França CN. Efeitos de exercícios físicos sobre fatores de risco cardiovascular em idosos hipertensos. Revista Brasileira em Promoção da Saúde. 2018;31(2). https://doi.org/10.5020/18061230.2017.6631
Rezende LFM de, Rey-López JP, Matsudo VKR, Luiz O do C. Sedentary behavior and health outcomes among older adults: a systematic review. BMC Public Health. 2014;14(1):333. https://doi.org/10.1186/1471-2458-14-333.
Article  Google Scholar 
Silva CL da, Sousa AG, Borges LPSL, Costa THM da. Usual consumption of ultra-processed foods and its association with sex, age, physical activity, and body mass index in adults living in Brasília City, Brazil. Rev Bras Epidemiol. 2021;24. https://doi.org/10.1590/1980-549720210033
Beaulieu K, Hopkins M, Blundell J, Finlayson G. Does habitual physical activity increase the sensitivity of the appetite control system? A systematic review. Sports Med. 2016;46(12):1897–919. https://doi.org/10.1007/s40279-016-0518-9.
Article  Google Scholar 
Rauber F, Steele EM, Louzada ML da C, Millett C, Monteiro CA, Levy RB. Ultra-processed food consumption and indicators of obesity in the United Kingdom population (2008–2016). PLoS One. 2020;15(5). https://doi.org/10.1371/journal.pone.0232676.
Whelton PK, Carey RM, Aronow WS, Casey DE, Collins KJ, Dennison Himmelfarb C, et al. 2017 ACC/AHA/AAPA/ABC/ACpM/AGS/APhA/ASH/ASPC/NMA/PCNA guideline for the prevention, detection, evaluation, and management of high blood pressure in adults: executive summary: a report of the American college of cardiology/American heart association task force on clinical practice guidelines. Hypertension. 2018;71(6):1269–324. https://doi.org/10.1161/HYP.0000000000000066.
Article  CAS  Google Scholar 
Cornelissen VA, Smart NA. Exercise training for blood pressure: a systematic review and meta-analysis. J Am Heart Assoc. 2013;2(1): e004473. https://doi.org/10.1161/JAHA.112.004473.
Article  Google Scholar 
Ethisan P, Somrongthong R, Ahmed J, Kumar R, Chapman RS. Factors related to physical activity among the elderly population in rural Thailand. J Prim Care Community Health. 2017;8(2):71–6. https://doi.org/10.1177/2150131916675899.
Article  Google Scholar 
Kwak SK, Kim JH. Statistical data preparation: management of missing values and outliers. Korean J Anesthesiol. 2017;70(4):407–11. https://doi.org/10.4097/kjae.2017.70.4.407.
Article  Google Scholar 
Zijlstra WP, van der Ark LA, Sijtsma K. Outliers in questionnaire data: can they be detected and should they be removed? J Educ Behav Stat. 2011;36(2):186–212. https://doi.org/10.3102/1076998610366263.
Article  Google Scholar 
Cabanas-Sánchez V, Guallar-Castillón P, Higueras-Fresnillo S, García-Esquinas E, Rodríguez-Artalejo F, Martinez-Gomez D. Physical activity, sitting time, and mortality from inflammatory diseases in older adults. Front Physiol. 2018;2018(9): e898. https://doi.org/10.3389/fphys.2018.00898.
Article  Google Scholar 
Ko YC, Chie WC, Wu TY, Ho CY, Yu WR. A cross-sectional study about the relationship between physical activity and sarcopenia in Taiwanese older adults. Sci Rep. 2021;11(1):1–9. https://doi.org/10.1038/s41598-021-90869-1.
Article  CAS  Google Scholar 
Khanna D, Peltzer C, Kahar P, Parmar MS. Body Mass Index (BMI): a screening tool analysis. Cureus. 2022;14(2): e22119. https://doi.org/10.7759/cureus.22119.
Article  Google Scholar 
Williams GC, Battista K, Leatherdale ST. An examination of how age of onset for alcohol, cannabis, and tobacco are associated with physical activity, screen time and BMI as students are preparing to graduate from high school. Preventive Medicine Reports. 2019;15: 100956. https://doi.org/10.1016/j.pmedr.2019.100956.
Article  Google Scholar 
Moreira AD, Claro RM, Felisbino-Mendes MS, Velasquez-Melendez G. Validade e reprodutibilidade de inquérito telefônico de atividade física no Brasil. Rev bras epidemiol. 2017;20:136–46. https://doi.org/10.1590/1980-5497201700010012.
Article  Google Scholar 
Ding D, Lawson KD, Kolbe-Alexander TL, Finkelstein EA, Katzmarzyk PT, van Mechelen W, et al. The economic burden of physical inactivity: a global analysis of major non-communicable diseases. The Lancet. 2016;388(10051):1311–24. https://doi.org/10.1016/S0140-6736(16)30383-X.
Article  Google Scholar 
Yerrakalva D, Yerrakalva D, Hajna S, Griffin S. Effects of mobile health app interventions on sedentary time, physical activity, and fitness in older adults: systematic review and meta-analysis. J Med Internet Res. 2019;21(11): e14343. https://doi.org/10.2196/14343.
Article  Google Scholar 
Xie Z, Jo A, Hong YR. Electronic wearable device and physical activity among US adults: an analysis of 2019 HINTS data. Int J Med Inform. 2020;144: 104297. https://doi.org/10.1016/j.ijmedinf.2020.104297.
Article  Google Scholar 
Muellmann S, Steenbock B, De Cocker K, De Craemer M, Hayes C, O’Shea MP, et al. Views of policy makers and health promotion professionals on factors facilitating implementation and maintenance of interventions and policies promoting physical activity and healthy eating: results of the DEDIPAC project. BMC Public Health. 2017;17:932. https://doi.org/10.1186/s12889-017-4929-9.
Article  Google Scholar 
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School of Physical Education and Sport of Ribeirão Preto, University of São Paulo, Bandeirantes Avenue nº 3900, University Campus – Monte Alegre, Ribeirão Preto-SP, 14030-680, Brazil
Leonardo Santos Lopes da Silva
Study and Research Group in Anthropometry, Training, and Sport (GEPEATE), School of Physical Education and Sport of Ribeirão Preto, University of São Paulo, Ribeirão Preto, Brazil
Leonardo Santos Lopes da Silva & Pedro Pugliesi Abdalla
Physical Education Department, Paulista University, São José Do Rio Preto, Brazil
Daniel de Freitas Batalhão & Anderson dos Santos Carvalho
Faculty of Sports (FADEUP), University of Porto, Porto, Portugal
Lucimere Bohn
Research Center for Physical Activity, Health and Leisure (CIAFEL), University of Porto, Porto, Portugal
Lucimere Bohn
Laboratory for Integrative and Translational Research in Population Health (ITR), Porto, Portugal
Lucimere Bohn
Faculdade de Psicologia, Educação e Desporto, University Lusófona of Porto, Porto, Portugal
Lucimere Bohn
Coastal Carolina University, Conway, SC, USA
Nilo César Ramos
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LSLS and PPA: Conceptualization; Roles/Writing – original draft; PPA: Data curation, Visualization; LSLS and PPA: Methodology, LSLS and PPA: Formal analysis; PPA: Software; LB, DFB; ASC; and NCR: Writing – review & editing; PPA: Validation. All authors have read and approved the manuscript.
Correspondence to Leonardo Santos Lopes da Silva.
All participants volunteered for the study, were informed about the scope of the study, and provided orally consent at the time of telephone contact. The VIGITEL project was approved by the National Commission on Ethics in Research for Human Beings of the Ministry of Health (CAAE: 65610017.1.0000.0008). The data used in this manuscript were collected from the online and open access database from VIGITEL (http://svs.aids.gov.br/download/Vigitel/), which justifies the absence of the permission of the Research Ethics Committee. The authors confirm that all methods were carried out in accordance with declaration of Helsinki.
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 Supplementary Table 1. Percentage values (%) of exercise types practiced by hypertensive older adults’ from VIGITEL project (n=5.535).
 Supplementary Table 2. Binary logistic regression model (including outliers [n=333]; total sample=11,122) with the association of nutritional status (BMI) and other factors on exercise participation (be or not a practitioner) and recommended amount of physical activity (sufficiently active).
 Supplementary Chart 1. Summary of main benefits of exercise and physical activity and recommendations of corresponding intensity, duration, and frequency for older hypertensive adults.
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da Silva, L.S.L., de Freitas Batalhão, D., dos Santos Carvalho, A. et al. Nutritional status, health risk behaviors, and eating habits are correlated with physical activity and exercise of brazilian older hypertensive adults: a cross-sectional study. BMC Public Health 22, 2382 (2022). https://doi.org/10.1186/s12889-022-14873-4
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Received: 07 July 2022
Accepted: 14 December 2022
Published: 19 December 2022
DOI: https://doi.org/10.1186/s12889-022-14873-4
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