Impact of cycling and walking on adiposity and healthcare costs among adults: longitudinal study

Orbolato, Rafael; Fernandes, Rômulo Araújo; Turi-Lynch, Bruna Camilo; Araujo, Monique Yndawe Castanho; Ferro, Izabela dos Santos; Gobbo, Luis Alberto; Zanuto, Everton Alex Carvalho; Codogno, Jamile Sanches

doi:10.1590/0102-311xen102623

Abstract:

Leisure-time physical activity seems relevant to prevent the development of chronic diseases and obesity. However, not much is known about the economic burden of these healthy behaviors, mainly in longitudinal designs. This study aimed to analyze the impact of walking and cycling on leisure-time on adiposity and healthcare costs among adults. This longitudinal study was conducted at a medium-size Brazilian city and included 198 participants with no missing data attended in the Brazilian Unified National Health System. Cycling and walking were assessed by a questionnaire with a face-to-face interview at four time-points (baseline, 6-month, 12-month, and 18-month). Healthcare costs were assessed using medical records. Adiposity markers included waist circumference and body fatness. Over the follow-up period, participants who were more engaged in cycling presented lower body fatness (p-value = 0.028) and healthcare costs (p-value = 0.038). However, in the multivariate model, the impact of cycling on costs was not significant (p-value = 0.507) due to the impact of number of chronic diseases (p-value = 0.001). Cycling on leisure-time is inversely related to adiposity in adults, whereas its role on preventing chronic diseases seems the main pathway linking it to cost mitigation.

Keywords:
Exercise; Body Mass Index; Health Care Costs

Resumo:

A atividade física no lazer parece relevante para prevenir o desenvolvimento de doenças crônicas e obesidade. No entanto, pouco se sabe sobre o impacto econômico destes comportamentos saudáveis, principalmente em estudos longitudinais. O objetivo deste estudo foi analisar o impacto da caminhada e do ciclismo como atividades de lazer na adiposidade e nos custos de saúde em adultos. Este estudo longitudinal foi realizado em uma cidade brasileira de médio porte e incluiu 198 participantes sem dados indisponíveis atendidos no Sistema Único de Saúde brasileiro. A caminhada e o ciclismo foram avaliados por meio de questionário e entrevista presencial em quatro momentos (linha de base, 6 meses, 12 meses e 18 meses). Os custos de saúde foram avaliados por meio de prontuários médicos. Os marcadores de adiposidade incluíram circunferência da cintura e gordura corporal. Durante o período de acompanhamento, os participantes que praticavam mais ciclismo apresentaram menos gordura corporal (p = 0,028) e custos de saúde (p = 0,038). Porém, no modelo multivariado, o impacto do ciclismo nos custos deixou de ser significativo (p = 0,507) devido ao impacto do número de doenças crônicas (p = 0,001). O ciclismo no momento de lazer está inversamente relacionado à adiposidade em adultos, enquanto o seu papel na prevenção de doenças crônicas parece ser o principal aspecto que o liga à redução de custos.

Palavras-chave:
Exercício Físico; Índice de Massa Corporal; Custos de Cuidados de Saúde

Resumen:

La actividad física en el ocio parece relevante para prevenir el desarrollo de enfermedades crónicas y la obesidad. Sin embargo, poco se sabe sobre el impacto económico de estos comportamientos saludables, especialmente en estudios longitudinales. El objetivo de este estudio fue analizar el impacto de caminar y andar en bicicleta como actividades de ocio sobre la adiposidad y los costos de salud en adultos. Este estudio longitudinal se llevó a cabo en una ciudad brasileña de tamaño mediano e incluyó a 198 participantes sin datos indisponibles atendidos en el Sistema Único de Salud brasileño. Se evaluaron los hábitos de caminar y andar en bicicleta mediante un cuestionario y una entrevista cara a cara en cuatro momentos (inicial, 6 meses, 12 meses y 18 meses). Los costos de atención médica se evaluaron utilizando registros médicos. Los marcadores de adiposidad incluyeron la circunferencia de la cintura y la grasa corporal. Durante el período de seguimiento, los participantes que practicaban más ciclismo presentaron menos grasa corporal (p = 0,028) y costos de salud (p = 0,038). Sin embargo, en el modelo multivariado, el impacto del ciclismo en los costos dejó de ser significativo (p = 0,507) debido al impacto del número de enfermedades crónicas (p = 0,001). El hábito de andar en bicicleta en los momentos de ocio está inversamente relacionado con la adiposidad en los adultos, mientras que su papel en la prevención de enfermedades crónicas parece ser el principal aspecto que lo vincula con la reducción de costos.

Palabras-clave:
Ejercicio Físico; Índice de Masa Corporal; Costos de Atención en Salud

Introduction

The high prevalence of insufficient physical activity constitutes a worldwide public health problem, which has significantly increased among adults ¹1. Guthold R, Stevens GA, Riley LM, Bull FC. Worldwide trends in insufficient physical activity from 2001 to 2016: a pooled analysis of 358 population-based surveys with 1·9 million participants. Lancet Glob Health 2018; 6:e1077-86.^,²2. Kohl 3rd HW, Craig CL, Lambert EV, Inoue S, Alkandari JR, Leetongin G, et al. The pandemic of physical inactivity: global action for public health. Lancet 2012; 380:294-305.. Insufficient physical activity is particularly harmful to human health due to its relevant role in the development of obesity and chronic diseases ³3. Fernandes RA, Christofaro DGD, Casonatto J, Codogno JS, Rodrigues EQ, Cardoso ML, et al. Prevalence of dyslipidemia in individuals physically active during childhood, adolescence and adult age. Arq Bras Cardiol 2011; 97:317-23.^,⁴4. Fernandes RA, Zanesco A. Early physical activity promotes lower prevalence of chronic diseases in adulthood. Hypertens Res 2010; 33:926-31.. Physical inactivity and sedentary behavior also increase the risk of premature mortality ⁵5. Turi BC, Monteiro HL, Lemes ÍR, Codogno JS, Lynch KR, Mesquira CAA, et al. TV viewing time is associated with increased all-cause mortality in Brazilian adults independent of physical activity. Scand J Med Sci Sports 2018; 28:596-603., whereas the regular engagement in good physical activity practice decreases mortality risk, regardless of chronic diseases ⁶6. Lee IM, Shiroma EJ, Lobelo F, Puska P, Blair SN, Katzmarzyk PT. Effect of physical inactivity on major non-communicable diseases worldwide: an analysis of burden of disease and life expectancy. Lancet 2012; 380:219-29.. Therefore, this background ratifies the relevance of public health programs targeting the promotion of physical activity among adults.

Regarding physical activity promotion, leisure-time physical activity seems to be more relevant than other domains to prevent the development of chronic diseases and obesity. Regarding this domain, walking and cycling are important manifestations of physical exercise among adults ⁷7. Bassett Jr. DR, Pucher J, Buehler R, Thompson DL, Crouter SE. Walking, cycling, and obesity rates in Europe, North America, and Australia. J Phys Act Health 2008; 5:795-814., being potential behaviors to prevent chronic diseases and hence mitigate health costs. However, in developing nations, not much is known about the economic burden of walking and cycling ⁸8. Turi BC, Codogno JS, Fernandes RA, Monteiro HL. Walking and health care expenditures among adult users of the Brazilian public healthcare system: retrospective cross-sectional study. Ciênc Saúde Colet 2015; 20:3561-8.^,⁹9. Duijvestijn M, de Wit GA, van Gils PF, Wendel-Vos GCW. Impact of physical activity on healthcare costs: a systematic review. BMC Health Serv Res 2023; 23:572..

Consistent information supports the idea that building walking and cycling track networks is beneficial to society in terms of air pollution, public transport, and health population ¹⁰10. Sælensminde K. Cost-benefit analyses of walking and cycling track networks taking into account insecurity, health effects and external costs of motorized traffic. Transp Res Part A Policy Pract 2004; 38:593-606.. For healthcare costs, cross-sectional studies have described an inverse relationship between engagement in walking and lower healthcare costs ⁸8. Turi BC, Codogno JS, Fernandes RA, Monteiro HL. Walking and health care expenditures among adult users of the Brazilian public healthcare system: retrospective cross-sectional study. Ciênc Saúde Colet 2015; 20:3561-8.^,¹¹11. Tsuji I, Takahashi K, Nishino Y, Ohkubo T, Kuriyma S, Watanabe Y, et al. Impact of walking upon medical care expenditure in Japan: the Ohsaki Cohort Study. Int J Epidemiol 2003; 32:809-14.^,¹²12. Kato M, Goto A, Tanaka T, Sasaki S, Igata A, Noda M. Effects of walking on medical cost: a quantitative evaluation by simulation focusing on diabetes. J Diabetes Investig 2013; 4:667-72.^,¹³13. Wohlrab M, Klenk J, Delgado-Ortiz L, Chambers M, Rochester L, Zuchowski M, et al. The value of walking: a systematic review on mobility and healthcare costs. Eur Rev Aging Phys Act 2022; 19:31., whereas few studies address the economic impact attributed to cycling ¹⁴14. Veisten K, Saelensminde K, Alvaer K, Bjornskau T, Elvik R, Schistad T. Total costs of bicycle injuries in Norway: correcting injury figures and indicating data needs. Accid Anal Prev 2007; 39:1162-9.. Although walking and cycling are common and accessible forms of transportation among adults ⁷7. Bassett Jr. DR, Pucher J, Buehler R, Thompson DL, Crouter SE. Walking, cycling, and obesity rates in Europe, North America, and Australia. J Phys Act Health 2008; 5:795-814.^,¹⁵15. Reis RS, Hino AA, Parra DC, Hallal PC, Brownson RC. Bicycling and walking for transportation in three Brazilian cities. Am J Prev Med 2013; 44:e9-17., aging leads to reduction in both behaviors, while increasing chronic diseases occurrence and healthcare costs ⁴4. Fernandes RA, Zanesco A. Early physical activity promotes lower prevalence of chronic diseases in adulthood. Hypertens Res 2010; 33:926-31.^,¹⁵15. Reis RS, Hino AA, Parra DC, Hallal PC, Brownson RC. Bicycling and walking for transportation in three Brazilian cities. Am J Prev Med 2013; 44:e9-17.^,¹⁶16. Turi BC, Codogno JS, Sarti FM, Anokye NK, Fernandes RA, Monteiro HL. Determinants of outpatient expenditure within primary care in the Brazilian National Health System. São Paulo Med J 2017; 135:205-12., especially after the fifth decade of life ⁴4. Fernandes RA, Zanesco A. Early physical activity promotes lower prevalence of chronic diseases in adulthood. Hypertens Res 2010; 33:926-31.^,¹⁷17. Malta DC, Bernal RT, de Souza MF, Szwarcwald CL, Lima MG, Barros MB. Social inequalities in the prevalence of self-reported chronic non-communicable diseases in Brazil: National Health Survey 2013. Int J Equity Health 2016; 15:153., placing this portion of the population at increased risk and raising questions on how walking and cycling could be beneficial in reducing costs.

Moreover, most data describing the association of walking and cycling with economic aspects are based on cross-sectional surveys and carried out in developed settings ⁸8. Turi BC, Codogno JS, Fernandes RA, Monteiro HL. Walking and health care expenditures among adult users of the Brazilian public healthcare system: retrospective cross-sectional study. Ciênc Saúde Colet 2015; 20:3561-8.^,⁹9. Duijvestijn M, de Wit GA, van Gils PF, Wendel-Vos GCW. Impact of physical activity on healthcare costs: a systematic review. BMC Health Serv Res 2023; 23:572., leading to technical questions about its application in developing nations. Such issue seems even more relevant in the Brazilian scenario, in which healthcare assistance is financed by public fundings (at all levels of complexity).

Therefore, this study aimed to analyze, in a longitudinal design, the impact of walking and cycling on leisure-time on adiposity and healthcare costs among adults aged 50 years or older.

Methods

Sample and sampling

The sample was composed of adults aged 50 years or older who were selected in two basic health units (BHU) in two different geographical regions of the metropolitan area of Presidente Prudente (medium size municipality, with 220,000 inhabitants), Western São Paulo State, Brazil, and with Human Development Index (HDI) of 0.806. Sample size estimation considered a minimum difference for healthcare costs between sufficiently active (standard deviation [SD] = USD 22.86) and insufficiently active patients (SD = USD 15.03) of USD 6.27 ¹⁸18. Codogno JS, Fernandes RA, Monteiro HL. Physical activity and healthcare cost of type 2 diabetic patients seen at basic units of healthcare. Arq Bras Endocrinol Metabol 2012; 56:6-11., according to previous methodology ¹⁹19. Miot HA. Tamanho da amostra em estudos clínicos e experimentais. J Vasc Bras 2011; 10:275-8., 80% statistical power, and 5% alpha error (Z = 1.96). The minimum sample size was estimated in 75 participants per group (n = 75 higher engagement in cycling/walking, and n = 75 lower engagement in cycling/walking).

The Brazilian Unified National Health System (SUS) offers primary, secondary, and tertiary healthcare services to all population free of charge. The BHU are the most distal arm of SUS since every single Brazilian municipality has at least one BHU (small to medium facilities located in different regions of the city), offering a large variety of primary care services (e.g., medical consultations [different specialties], vaccination, dental care, physical therapy). Municipal Health Department pointed out the two BHU that held our longitudinal study, which were selected due to the high number of people attended.

The same research team contacted and took measurements (face-to-face interview, anthropometric measurements, and bioelectrical impedance analysis - BIA) of all participants at the BHU (the research team was composed of previously trained PhD, MSc, and undergraduate students of the physical education and physical therapy programs, as well as the researcher responsible by the study). The fieldwork lasted 30 days in each BHU, in which all patients with a scheduled appointment were considered eligible for the study. Participants were contacted and the research team checked all inclusion criteria, as follows: age ≥ 50 years old and at least one medical consultation scheduled in the BHU in the six months before the first contact.

All patients who agreed to participate and fulfilled all inclusion criteria were followed for 18 months and assessed every six months (baseline [March/2014], 6-month [September/2014], 12-month [March/2015], and 18-month [September/2015]). In all stages of the study, the researchers repeated the face-to-face interview, anthropometric measurements, and BIA. At baseline, the sample comprised 327 participants, but at the end of the 18-month follow-up, the final sample comprised 198 participants with no missing data. Regarding how the final sample was representative of the general Brazilian adult population, 82% of Brazilian adults are estimated to live in urban areas (like our sample) and, regardless of dwelling area, 78% of adults do not have access to private health insurance, leading them to search exclusively for healthcare services offered by SUS ¹⁷. Moreover, similar to the general Brazilian adult population, our sample had a higher number of women than men, and approximately 40% of adults were illiterate or had incomplete elementary education ¹⁷17. Malta DC, Bernal RT, de Souza MF, Szwarcwald CL, Lima MG, Barros MB. Social inequalities in the prevalence of self-reported chronic non-communicable diseases in Brazil: National Health Survey 2013. Int J Equity Health 2016; 15:153..

The Institutional Review Board of the São Paulo University previously approved the study protocol (n. 241,291/2013). At baseline, all participants signed a written consent form agreeing to participate in the follow-up study.

Dependent variable: healthcare costs

Direct healthcare costs were computed from the perspective of SUS in a time horizon of 18 months considering a bottom-up approach (focused on individual costs) ²⁰20. Silva EN, Silva MT, Pereira MG. Identifying, measuring and valuing health costs. Epidemiol Serv Saúde 2016; 25:437-9.. Healthcare costs were assessed using all procedures registered in the patients’ medical records (e.g., medical consultations [all specialties], medicine released, tests, physical therapy consultations) following previously validated methods ⁸8. Turi BC, Codogno JS, Fernandes RA, Monteiro HL. Walking and health care expenditures among adult users of the Brazilian public healthcare system: retrospective cross-sectional study. Ciênc Saúde Colet 2015; 20:3561-8.^,¹⁵15. Reis RS, Hino AA, Parra DC, Hallal PC, Brownson RC. Bicycling and walking for transportation in three Brazilian cities. Am J Prev Med 2013; 44:e9-17.^,¹⁸18. Codogno JS, Fernandes RA, Monteiro HL. Physical activity and healthcare cost of type 2 diabetic patients seen at basic units of healthcare. Arq Bras Endocrinol Metabol 2012; 56:6-11.. Additionally, all public expenditures related to the maintenance of the BHU (nurses’ wages, telephone, electric, and water bills of the BHU) were registered during the 18 months. All medical procedures in the last six months before the baseline were considered, as well as medical procedures registered during the 18-month follow-up, accounting for 24 months of healthcare costs. Regarding the period to observe real differences in healthcare costs, previous data identify that a minimum of 12 months of follow-up is sufficient to capture the potential impact of physical activity on healthcare costs among adults ¹¹11. Tsuji I, Takahashi K, Nishino Y, Ohkubo T, Kuriyma S, Watanabe Y, et al. Impact of walking upon medical care expenditure in Japan: the Ohsaki Cohort Study. Int J Epidemiol 2003; 32:809-14.^,¹⁴14. Veisten K, Saelensminde K, Alvaer K, Bjornskau T, Elvik R, Schistad T. Total costs of bicycle injuries in Norway: correcting injury figures and indicating data needs. Accid Anal Prev 2007; 39:1162-9..

To convert all these medical procedures and maintenance expenditures into currency (Brazilian currency, BRL), the Municipal Health Department provided all values paid for all procedures and services above described ¹¹11. Tsuji I, Takahashi K, Nishino Y, Ohkubo T, Kuriyma S, Watanabe Y, et al. Impact of walking upon medical care expenditure in Japan: the Ohsaki Cohort Study. Int J Epidemiol 2003; 32:809-14.^,¹⁷17. Malta DC, Bernal RT, de Souza MF, Szwarcwald CL, Lima MG, Barros MB. Social inequalities in the prevalence of self-reported chronic non-communicable diseases in Brazil: National Health Survey 2013. Int J Equity Health 2016; 15:153.^,¹⁸18. Codogno JS, Fernandes RA, Monteiro HL. Physical activity and healthcare cost of type 2 diabetic patients seen at basic units of healthcare. Arq Bras Endocrinol Metabol 2012; 56:6-11.. Costs were updated in accordance with the official Brazilian inflation index (Extended National Consumer Price Index - IPCA) ²⁰20. Silva EN, Silva MT, Pereira MG. Identifying, measuring and valuing health costs. Epidemiol Serv Saúde 2016; 25:437-9., from the date data was obtained until December 2022, and converted into USD using the official exchange rate of the same date (USD exchange rate at 5.21), published by the Brazilian Central Bank. The variable denoting all the healthcare costs accumulated by each participant during the follow-up period was named “Healthcare costs 24 months”.

Dependent variable: anthropometry and bioelectrical impedance analysis

Body composition was assessed using the BIA (InBody, model 230, https://inbody.com/en) at baseline and follow-up periods. All assessments happened during the morning, respecting 24h without physical exercise, no caffeine consumption (coffee), and an empty bladder. The software provided by the manufacturer provided data about body fatness percentage (%BF). Body mass index (BMI [kg/m²]) was calculated using body weight (electronic scale [maximum 150kg]) and height (wall mounted stadiometer [maximum 200cm]). Waist circumference (WC - metallic tape [cm]) was used as a proxy for abdominal obesity.

Independent variable: walking and cycling

Physical activity was assessed with face-to-face interviews, using a validated questionnaire translated into Brazilian Portuguese ²¹21. Baecke JA, Burema J, Frijters JE. A short questionnaire for the measurement of habitual physical activity in epidemiological studies. Am J Clin Nutr 1982; 36:936-42.^,²²22. Florindo AA, Latorre MR, Jaime PC, Tanaka T, Zerbini CA. Methodology to evaluation the habitual physical activity in men aged 50 years or more. Rev Saúde Pública 2004; 38:307-14.. The questionnaire comprises 16 questions with Likert scale answers, and covers three physical activity domains: occupational, sport, and leisure-time (in this study, only the leisure-time domain was used). The leisure-time domain includes regular engagement in leisure-time activities, such as walking, cycling, watching television, and active transportation.

The frequency of cycling and walking (never, seldom, sometimes, often, and always) was assessed in all time points of the longitudinal study (baseline, 6-month, 12-month, and 18-month) and two new variables with score ranging from 4 to 20 points were created considering the sum of all responses. To categorize the sample according to the engagement in cycling and walking, participants who answered “never” in all four time points were classified as not engaged (cycling-no and walking-no, respectively) and those participants who reported any level of engagement during the 18 months were classified as engaged (cycling-yes and walking-yes, respectively).

Covariates

General information of each participant included chronological age (difference between birthday and measurement day), sex (male and female), economic condition and formal education (standardized questionnaire) ²³23. Associação Brasileira de Empresas de Pesquisa. Critérios de classificação econômica Brasil. http://www.abep.org/Servicos/Download.aspx?id=07 (accessed on 05/Aug/2017).
http://www.abep.org/Servicos/Download.as... , and blood pressure (systolic - SBP, and diastolic blood pressure - DBP; measured by Omron HEM-742 model; https://www.omron-oficial.com/). Moreover, the previous diagnosis of chronic disease was registered at baseline (diabetes mellitus, arterial hypertension, and dyslipidemia).

Statistical analysis

Descriptive statistics comprised mean, SD, and 95% confidence intervals (95%CI). Student’s t-test for independent samples compared participants engaged and not engaged in cycling and walking on leisure-time (Table 1). Spearman correlation assessed the relationship between healthcare costs accumulated during the 18 months and changes in physical activity, body composition, and blood pressure, as well as the stability of walking and cycling over time (Table 2). Analysis of variance (ANOVA) for repeated measures compared the impact of cycling and walking on body composition outcomes and healthcare costs (Tables 3 and 4, respectively). Sex, chronological age, economic condition score, and number of chronic disease were used as covariates in the ANOVA for repeated measures. Bonferroni’s post-hoc test was applied, when necessary, whereas measures of effect-size were expressed as eta-squared (ES-r). Statistical significance (p-value) was set at < 0.05 and the statistical software BioEstat, version 5.0 (https://mamiraua.org.br/downloads/programas/), ran all analyses.

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Table 1
General characteristics of the sample stratified according to walking and cycling on leisure-time (n = 198).

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Table 2
Frequency of cycling and walking over the follow-up period (n = 198).

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Table 3
Changes in body fatness markers and healthcare costs over 18 months follow-up according to cycling on leisure-time (n = 198).

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Table 4
Changes in body fatness markers and healthcare costs over 18 months follow-up according to walking on leisure-time (n = 98).

Results

The 198 participants that completed the study included more women than men (50 men [29.3%] and 148 women [70.7%]; p-value = 0.001), and the overall healthcare costs accumulated was USD 22,092.68. Men were older (p-value = 0.002), heavier (p-value = 0.006), taller (p-value = 0.001), and presented higher waist circumference (WC; p-value = 0.002) than women; they also had lower values %BF-BIA (p-value = 0.001) than women. Women were less engaged in cycling (p-value = 0.006) than men, and higher healthcare costs were observed among women (p-value = 0.029).

Participants engaged in cycling on leisure-time during the follow-up period had lower body fatness (p-value = 0.001), BMI (p-value = 0.001), healthcare costs (p-value = 0.038), and prevalence of arterial hypertension (p-value = 0.005) than participants not engaged in cycling. There was no significant difference according to the engagement in walking on leisure-time (Table 1).

Healthcare costs were inversely related to the 18-month cycling score (Spearman correlation - rho = -0.164; p-value = 0.021), but not the walking score (rho = -0.089; p-value = 0.215). Moreover, changes in WC (p-value = 0.210), %BF-BIA (p-value = 0.853), SBP (p-value = 0.301), and DBP (p-value = 0.953) were also unrelated to healthcare costs accumulated during the follow-up period.

In our sample, 86.4% (n = 171) of all participants reported “never” cycling in all four interviews, whereas 17.7% (n = 5) reported “never” walking in all four interviews. Prevalence of cycling was lower when compared with walking, and trends of the maintenance of walking over time were weak (rho ranging from 0.225 to 0.349) and for cycling were moderate (rho ranging from 0.561 to 0.641) (Table 2).

Over the follow-up period, participants who were more engaged in cycling presented lower %BF-BIA values (p-value = 0.028; cycling explained 2.7% of the variance observed on %BF-BIA [ES-r = 0.027]), but not WC (p-value = 0.293) (Table 3). In the crude analysis, participants with higher engagement in cycling presented lower healthcare costs over the follow-up period than those participants not engaged in cycling (p-value = 0.038; explaining 2.2% of all changes over time [ES-r = 0.022]). However, in the multivariate model, the impact of cycling was no longer significant (p-value = 0.507 [ES-r = 0.002]) mainly due to the impact of number of chronic disease (p-value = 0.001; ES-r = 0.194 [19.4%]).

Over the follow-up period, the engagement in walking did not significantly change WC (p-value = 0.799), %BF-BIA (p-value = 0.815), and healthcare costs (p-value = 0.562) (Table 4).

Discussion

The 18-month longitudinal study involving adults showed that higher engagement in cycling on leisure-time affected body fatness levels, whereas its impact on economic parameters was explained by its role in the control of chronic diseas. Adopting a simple practice of physical activity during leisure-time seems relevant to prevent obesity and chronic disease, leading to a potential mitigation of healthcare costs.

In this study, men presented higher engagement in cycling than women, whereas walking was similar for the two genders. Regarding cycling, our findings are similar to other studies, describing that men have higher levels of leisure-time physical activity and use more cycling as transport than women ¹⁶16. Turi BC, Codogno JS, Sarti FM, Anokye NK, Fernandes RA, Monteiro HL. Determinants of outpatient expenditure within primary care in the Brazilian National Health System. São Paulo Med J 2017; 135:205-12.^,²⁴24. Gomes GA, Reis RS, Parra DC, Ribeiro I, Hino AAF, Hallal PC, et al. Walking for leisure among adults from three Brazilian cities and its association with perceived environment attributes and personal factors. Int J Behav Nutr Phys Act 2011; 8:111.. Regarding walking, the similar results for men and women also agree with previous data ⁸8. Turi BC, Codogno JS, Fernandes RA, Monteiro HL. Walking and health care expenditures among adult users of the Brazilian public healthcare system: retrospective cross-sectional study. Ciênc Saúde Colet 2015; 20:3561-8. and might be supported by walking being a cheaper physical activity, and its practice being spread out among adult population regardless of sex.

Another sex-dependent finding in our study was the higher healthcare costs among women. Cultural and biological aspects might support these differences in healthcare costs. Since early adolescence, girls are used to visit healthcare professionals to monitor aspects linked to birth control, which increases the use of primary care services and its costs. Moreover, menopause and its complications require close medical monitoring. On the other hand, men usually do not seek medical monitoring since culturally this act represents a demonstration of physical weakness, interfering in daily life activities that characterize their role as men in the society, such as labor activity ²⁵25. Gomes R, Nascimento EF, Araújo FC. Por que os homens buscam menos os serviços de saúde do que as mulheres? As explicações de homens com baixa escolaridade e homens com ensino superior. Cad Saúde Pública 2007; 23:565-74..

In general, participants with higher cycling engagement during the follow-up had lower adiposity, agreeing with previous studies that have assessed the relationship between cycling and weight gain ⁷7. Bassett Jr. DR, Pucher J, Buehler R, Thompson DL, Crouter SE. Walking, cycling, and obesity rates in Europe, North America, and Australia. J Phys Act Health 2008; 5:795-814.^,²⁶26. Flint E, Webb E, Cummins S. Change in commute mode and body-mass index: prospective, longitudinal evidence from UK Biobank. Lancet Public Health 2016; 1:e46-e55.^,²⁷27. Lusk AC, Mekary RA, Feskanich D, Willett WC. Bicycle riding, walking, and weight gain in premenopausal women. Arch Intern Med 2010; 170:1050-6.. Bassett et al. ⁷7. Bassett Jr. DR, Pucher J, Buehler R, Thompson DL, Crouter SE. Walking, cycling, and obesity rates in Europe, North America, and Australia. J Phys Act Health 2008; 5:795-814. assessed the prevalence of obesity, walking, and cycling in the United States, Europe, and Australia, describing that obesity prevalence was lower in geographical regions where active transport was more commonly reported by the participants. Moreover, among English workers aged 40-69 years-old (72,999 men and 82,788 women), those who commute using cycling and walking had lower average values for BMI and body fatness than those commuting by car ²⁶26. Flint E, Webb E, Cummins S. Change in commute mode and body-mass index: prospective, longitudinal evidence from UK Biobank. Lancet Public Health 2016; 1:e46-e55.. In fact, a reasonable explanation for this negative relationship might be the higher energy expenditure required to sustain physical activities such as cycling ²⁸28. Littman AJ, Kristal AR, White E. Effects of physical activity intensity, frequency, and activity type on 10-y weight change in middle-aged men and women. Int J Obes (Lond) 2005; 29:524-33.^,²⁹29. Pucher J, Buehler R, Bassett DR, Dannenberg AL. Walking and cycling to health: a comparative analysis of city, state, and international data. Am J Public Health 2010; 100:1986-92., leading to adiposity reduction when these activities are maintained for long periods ²⁹29. Pucher J, Buehler R, Bassett DR, Dannenberg AL. Walking and cycling to health: a comparative analysis of city, state, and international data. Am J Public Health 2010; 100:1986-92..

Previous cross-sectional studies have identified a significant association between leisure-time physical activity and economic variables ⁸8. Turi BC, Codogno JS, Fernandes RA, Monteiro HL. Walking and health care expenditures among adult users of the Brazilian public healthcare system: retrospective cross-sectional study. Ciênc Saúde Colet 2015; 20:3561-8.^,¹⁸18. Codogno JS, Fernandes RA, Monteiro HL. Physical activity and healthcare cost of type 2 diabetic patients seen at basic units of healthcare. Arq Bras Endocrinol Metabol 2012; 56:6-11.^,³⁰30. Codogno JS, Turi BC, Kemper HC, Fernandes RA, Christofaro DG, Monteiro HL. Physical inactivity of adults and 1-year health care expenditures in Brazil. Int J Public Health 2015; 60:309-16., but few addressed cycling. Cycling decreases the mortality risk by about 10% ³¹31. Kelly P, Kahlmeier S, Götschi T, Orsini N, Richards J, Roberts N, et al. Systematic review and meta-analysis of reduction in all-cause mortality from walking and cycling and shape of dose response relationship. Int J Behav Nutr Phys Act 2014; 11:132. and thus it may mitigate healthcare costs ³²32. Oja P, Titze S, Bauman A, Geus B, Krenn P, Reger-Nash B, et al. Health benefits of cycling: a systematic review. Scand J Med Sci Sports 2011; 21:496-509.^,³³33. Sener IN, Lee RJ, Elgart Z. Potential health implications and health cost reductions of transit-induced physical activity. J Transp Health 2016; 3:133-40.. In England and Wales, the promotion of higher engagement in walking and cycling would have the potential to save GBP 17 billion related to the prevention of chronic disease and reduction in the release of greenhouse gases in the atmosphere ³⁴34. Jarrett J, Woodcock J, Griffiths UK, Chalabi Z, Edwards P, Roberts I, et al Effect of increasing active travel in urban England and Wales on costs to the National Health Service. Lancet 2012; 379:2198-205.. Moreover, a cost-benefit analysis conducted in the United States indicated that each USD 2.79 spent building cycling paths would generate a gain of 0.0022 quality-adjusted life year ³⁵35. Gu J, Mohit B, Muennig PA. The cost-effectiveness of bike lanes in New York City. Inj Prev 2017; 23:239-43..

In the crude analysis, the engagement in cycling on leisure-time affected healthcare costs by about 2%. In terms of magnitude, our findings are like other data from Canada and Brazil, ranging from 1% to 2.5% ³⁰30. Codogno JS, Turi BC, Kemper HC, Fernandes RA, Christofaro DG, Monteiro HL. Physical inactivity of adults and 1-year health care expenditures in Brazil. Int J Public Health 2015; 60:309-16.^,³⁶36. Katzmarzyk PT, Gledhill N, Shephard RJ. The economic burden of physical inactivity in Canada. CMAJ 2000; 163:1435-40.. On the other hand, multivariate models found that the association between cycling and lower chronic disease occurrence is the main contributor to the mitigation of healthcare costs. In fact, at baseline, participants engaged in cycling had a lower prevalence of arterial hypertension and this characteristic might affect its impact on costs during the follow-up period.

In terms of limitation, note that healthcare costs were based only in primary care services and, thus, secondary/tertiary services (e.g., surgeries, complex medical procedures), as well as productivity loss were not considered (e.g., absenteeism, presentism, and retirements due to health problems) ³⁷37. Araujo MYC, Sarti FM, Fernandes RA, Monteiro HL, Turi BC, Anokye N, et al. Association between costs related to productivity loss and modified risk factors among users of the Brazilian National Health System. J Occup Environ Med 2017; 59:313-9.. Second, the Likert scale used to describe the engagement in cycling and walking does not represent measures of both frequency and volume, limiting the exploratory analysis linking both behaviors to the outcomes assessed in our study. Third, the minimum sample size required to the statistical analysis (n = 75) was not reached in the group of participants engaged in cycling activities, limiting the power of our conclusions. Finally, cycling and walking are behaviors manifested in other physical activity domains (e.g., active transportation, labor activities), thus not monitoring these behaviors in other domains is a limitation of our study.

Conclusion

In summary, the findings of this longitudinal study hint that cycling on leisure-time is inversely related to adiposity in adults and that the role of cycling on chronic disease prevention seems to be the main pathway linking it to the mitigation of healthcare costs.

Acknowledgments

To Brazilian National Research Council (CNPq, process n. 401178/2013-7), Brazilian Coordination for the Improvent of Higher Education Personnel (CAPES) and São Paulo State Research Foundation (FAPESP, processes n. 2018/01744-7 and n. 2014/09645-7).

References

¹
Guthold R, Stevens GA, Riley LM, Bull FC. Worldwide trends in insufficient physical activity from 2001 to 2016: a pooled analysis of 358 population-based surveys with 1·9 million participants. Lancet Glob Health 2018; 6:e1077-86.
²
Kohl 3rd HW, Craig CL, Lambert EV, Inoue S, Alkandari JR, Leetongin G, et al. The pandemic of physical inactivity: global action for public health. Lancet 2012; 380:294-305.
³
Fernandes RA, Christofaro DGD, Casonatto J, Codogno JS, Rodrigues EQ, Cardoso ML, et al. Prevalence of dyslipidemia in individuals physically active during childhood, adolescence and adult age. Arq Bras Cardiol 2011; 97:317-23.
⁴
Fernandes RA, Zanesco A. Early physical activity promotes lower prevalence of chronic diseases in adulthood. Hypertens Res 2010; 33:926-31.
⁵
Turi BC, Monteiro HL, Lemes ÍR, Codogno JS, Lynch KR, Mesquira CAA, et al. TV viewing time is associated with increased all-cause mortality in Brazilian adults independent of physical activity. Scand J Med Sci Sports 2018; 28:596-603.
⁶
Lee IM, Shiroma EJ, Lobelo F, Puska P, Blair SN, Katzmarzyk PT. Effect of physical inactivity on major non-communicable diseases worldwide: an analysis of burden of disease and life expectancy. Lancet 2012; 380:219-29.
⁷
Bassett Jr. DR, Pucher J, Buehler R, Thompson DL, Crouter SE. Walking, cycling, and obesity rates in Europe, North America, and Australia. J Phys Act Health 2008; 5:795-814.
⁸
Turi BC, Codogno JS, Fernandes RA, Monteiro HL. Walking and health care expenditures among adult users of the Brazilian public healthcare system: retrospective cross-sectional study. Ciênc Saúde Colet 2015; 20:3561-8.
⁹
Duijvestijn M, de Wit GA, van Gils PF, Wendel-Vos GCW. Impact of physical activity on healthcare costs: a systematic review. BMC Health Serv Res 2023; 23:572.
¹⁰
Sælensminde K. Cost-benefit analyses of walking and cycling track networks taking into account insecurity, health effects and external costs of motorized traffic. Transp Res Part A Policy Pract 2004; 38:593-606.
¹¹
Tsuji I, Takahashi K, Nishino Y, Ohkubo T, Kuriyma S, Watanabe Y, et al. Impact of walking upon medical care expenditure in Japan: the Ohsaki Cohort Study. Int J Epidemiol 2003; 32:809-14.
¹²
Kato M, Goto A, Tanaka T, Sasaki S, Igata A, Noda M. Effects of walking on medical cost: a quantitative evaluation by simulation focusing on diabetes. J Diabetes Investig 2013; 4:667-72.
¹³
Wohlrab M, Klenk J, Delgado-Ortiz L, Chambers M, Rochester L, Zuchowski M, et al. The value of walking: a systematic review on mobility and healthcare costs. Eur Rev Aging Phys Act 2022; 19:31.
¹⁴
Veisten K, Saelensminde K, Alvaer K, Bjornskau T, Elvik R, Schistad T. Total costs of bicycle injuries in Norway: correcting injury figures and indicating data needs. Accid Anal Prev 2007; 39:1162-9.
¹⁵
Reis RS, Hino AA, Parra DC, Hallal PC, Brownson RC. Bicycling and walking for transportation in three Brazilian cities. Am J Prev Med 2013; 44:e9-17.
¹⁶
Turi BC, Codogno JS, Sarti FM, Anokye NK, Fernandes RA, Monteiro HL. Determinants of outpatient expenditure within primary care in the Brazilian National Health System. São Paulo Med J 2017; 135:205-12.
¹⁷
Malta DC, Bernal RT, de Souza MF, Szwarcwald CL, Lima MG, Barros MB. Social inequalities in the prevalence of self-reported chronic non-communicable diseases in Brazil: National Health Survey 2013. Int J Equity Health 2016; 15:153.
¹⁸
Codogno JS, Fernandes RA, Monteiro HL. Physical activity and healthcare cost of type 2 diabetic patients seen at basic units of healthcare. Arq Bras Endocrinol Metabol 2012; 56:6-11.
¹⁹
Miot HA. Tamanho da amostra em estudos clínicos e experimentais. J Vasc Bras 2011; 10:275-8.
²⁰
Silva EN, Silva MT, Pereira MG. Identifying, measuring and valuing health costs. Epidemiol Serv Saúde 2016; 25:437-9.
²¹
Baecke JA, Burema J, Frijters JE. A short questionnaire for the measurement of habitual physical activity in epidemiological studies. Am J Clin Nutr 1982; 36:936-42.
²²
Florindo AA, Latorre MR, Jaime PC, Tanaka T, Zerbini CA. Methodology to evaluation the habitual physical activity in men aged 50 years or more. Rev Saúde Pública 2004; 38:307-14.
²³
Associação Brasileira de Empresas de Pesquisa. Critérios de classificação econômica Brasil. http://www.abep.org/Servicos/Download.aspx?id=07 (accessed on 05/Aug/2017).
» http://www.abep.org/Servicos/Download.aspx?id=07
²⁴
Gomes GA, Reis RS, Parra DC, Ribeiro I, Hino AAF, Hallal PC, et al. Walking for leisure among adults from three Brazilian cities and its association with perceived environment attributes and personal factors. Int J Behav Nutr Phys Act 2011; 8:111.
²⁵
Gomes R, Nascimento EF, Araújo FC. Por que os homens buscam menos os serviços de saúde do que as mulheres? As explicações de homens com baixa escolaridade e homens com ensino superior. Cad Saúde Pública 2007; 23:565-74.
²⁶
Flint E, Webb E, Cummins S. Change in commute mode and body-mass index: prospective, longitudinal evidence from UK Biobank. Lancet Public Health 2016; 1:e46-e55.
²⁷
Lusk AC, Mekary RA, Feskanich D, Willett WC. Bicycle riding, walking, and weight gain in premenopausal women. Arch Intern Med 2010; 170:1050-6.
²⁸
Littman AJ, Kristal AR, White E. Effects of physical activity intensity, frequency, and activity type on 10-y weight change in middle-aged men and women. Int J Obes (Lond) 2005; 29:524-33.
²⁹
Pucher J, Buehler R, Bassett DR, Dannenberg AL. Walking and cycling to health: a comparative analysis of city, state, and international data. Am J Public Health 2010; 100:1986-92.
³⁰
Codogno JS, Turi BC, Kemper HC, Fernandes RA, Christofaro DG, Monteiro HL. Physical inactivity of adults and 1-year health care expenditures in Brazil. Int J Public Health 2015; 60:309-16.
³¹
Kelly P, Kahlmeier S, Götschi T, Orsini N, Richards J, Roberts N, et al. Systematic review and meta-analysis of reduction in all-cause mortality from walking and cycling and shape of dose response relationship. Int J Behav Nutr Phys Act 2014; 11:132.
³²
Oja P, Titze S, Bauman A, Geus B, Krenn P, Reger-Nash B, et al. Health benefits of cycling: a systematic review. Scand J Med Sci Sports 2011; 21:496-509.
³³
Sener IN, Lee RJ, Elgart Z. Potential health implications and health cost reductions of transit-induced physical activity. J Transp Health 2016; 3:133-40.
³⁴
Jarrett J, Woodcock J, Griffiths UK, Chalabi Z, Edwards P, Roberts I, et al Effect of increasing active travel in urban England and Wales on costs to the National Health Service. Lancet 2012; 379:2198-205.
³⁵
Gu J, Mohit B, Muennig PA. The cost-effectiveness of bike lanes in New York City. Inj Prev 2017; 23:239-43.
³⁶
Katzmarzyk PT, Gledhill N, Shephard RJ. The economic burden of physical inactivity in Canada. CMAJ 2000; 163:1435-40.
³⁷
Araujo MYC, Sarti FM, Fernandes RA, Monteiro HL, Turi BC, Anokye N, et al. Association between costs related to productivity loss and modified risk factors among users of the Brazilian National Health System. J Occup Environ Med 2017; 59:313-9.

Publication Dates

Publication in this collection
26 Feb 2024
Date of issue
2024

History

Received
02 June 2023
Reviewed
23 Oct 2023
Accepted
01 Dec 2023

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ¹
Guthold R, Stevens GA, Riley LM, Bull FC. Worldwide trends in insufficient physical activity from 2001 to 2016: a pooled analysis of 358 population-based surveys with 1·9 million participants. Lancet Glob Health 2018; 6:e1077-86.

[2] ²
Kohl 3rd HW, Craig CL, Lambert EV, Inoue S, Alkandari JR, Leetongin G, et al. The pandemic of physical inactivity: global action for public health. Lancet 2012; 380:294-305.

[3] ³
Fernandes RA, Christofaro DGD, Casonatto J, Codogno JS, Rodrigues EQ, Cardoso ML, et al. Prevalence of dyslipidemia in individuals physically active during childhood, adolescence and adult age. Arq Bras Cardiol 2011; 97:317-23.

[4] ⁴
Fernandes RA, Zanesco A. Early physical activity promotes lower prevalence of chronic diseases in adulthood. Hypertens Res 2010; 33:926-31.

[5] ⁵
Turi BC, Monteiro HL, Lemes ÍR, Codogno JS, Lynch KR, Mesquira CAA, et al. TV viewing time is associated with increased all-cause mortality in Brazilian adults independent of physical activity. Scand J Med Sci Sports 2018; 28:596-603.

[6] ⁶
Lee IM, Shiroma EJ, Lobelo F, Puska P, Blair SN, Katzmarzyk PT. Effect of physical inactivity on major non-communicable diseases worldwide: an analysis of burden of disease and life expectancy. Lancet 2012; 380:219-29.

[7] ⁷
Bassett Jr. DR, Pucher J, Buehler R, Thompson DL, Crouter SE. Walking, cycling, and obesity rates in Europe, North America, and Australia. J Phys Act Health 2008; 5:795-814.

[8] ⁸
Turi BC, Codogno JS, Fernandes RA, Monteiro HL. Walking and health care expenditures among adult users of the Brazilian public healthcare system: retrospective cross-sectional study. Ciênc Saúde Colet 2015; 20:3561-8.

[9] ⁹
Duijvestijn M, de Wit GA, van Gils PF, Wendel-Vos GCW. Impact of physical activity on healthcare costs: a systematic review. BMC Health Serv Res 2023; 23:572.

[10] ¹⁰
Sælensminde K. Cost-benefit analyses of walking and cycling track networks taking into account insecurity, health effects and external costs of motorized traffic. Transp Res Part A Policy Pract 2004; 38:593-606.

[11] ¹¹
Tsuji I, Takahashi K, Nishino Y, Ohkubo T, Kuriyma S, Watanabe Y, et al. Impact of walking upon medical care expenditure in Japan: the Ohsaki Cohort Study. Int J Epidemiol 2003; 32:809-14.

[12] ¹²
Kato M, Goto A, Tanaka T, Sasaki S, Igata A, Noda M. Effects of walking on medical cost: a quantitative evaluation by simulation focusing on diabetes. J Diabetes Investig 2013; 4:667-72.

[13] ¹³
Wohlrab M, Klenk J, Delgado-Ortiz L, Chambers M, Rochester L, Zuchowski M, et al. The value of walking: a systematic review on mobility and healthcare costs. Eur Rev Aging Phys Act 2022; 19:31.

[14] ¹⁴
Veisten K, Saelensminde K, Alvaer K, Bjornskau T, Elvik R, Schistad T. Total costs of bicycle injuries in Norway: correcting injury figures and indicating data needs. Accid Anal Prev 2007; 39:1162-9.

[15] ¹⁵
Reis RS, Hino AA, Parra DC, Hallal PC, Brownson RC. Bicycling and walking for transportation in three Brazilian cities. Am J Prev Med 2013; 44:e9-17.

[16] ¹⁶
Turi BC, Codogno JS, Sarti FM, Anokye NK, Fernandes RA, Monteiro HL. Determinants of outpatient expenditure within primary care in the Brazilian National Health System. São Paulo Med J 2017; 135:205-12.

[17] ¹⁷
Malta DC, Bernal RT, de Souza MF, Szwarcwald CL, Lima MG, Barros MB. Social inequalities in the prevalence of self-reported chronic non-communicable diseases in Brazil: National Health Survey 2013. Int J Equity Health 2016; 15:153.

[18] ¹⁸
Codogno JS, Fernandes RA, Monteiro HL. Physical activity and healthcare cost of type 2 diabetic patients seen at basic units of healthcare. Arq Bras Endocrinol Metabol 2012; 56:6-11.

[19] ¹⁹
Miot HA. Tamanho da amostra em estudos clínicos e experimentais. J Vasc Bras 2011; 10:275-8.

[20] ²⁰
Silva EN, Silva MT, Pereira MG. Identifying, measuring and valuing health costs. Epidemiol Serv Saúde 2016; 25:437-9.

[21] ²¹
Baecke JA, Burema J, Frijters JE. A short questionnaire for the measurement of habitual physical activity in epidemiological studies. Am J Clin Nutr 1982; 36:936-42.

[22] ²²
Florindo AA, Latorre MR, Jaime PC, Tanaka T, Zerbini CA. Methodology to evaluation the habitual physical activity in men aged 50 years or more. Rev Saúde Pública 2004; 38:307-14.

[23] ²³
Associação Brasileira de Empresas de Pesquisa. Critérios de classificação econômica Brasil. http://www.abep.org/Servicos/Download.aspx?id=07 (accessed on 05/Aug/2017).
» http://www.abep.org/Servicos/Download.aspx?id=07

[24] ²⁴
Gomes GA, Reis RS, Parra DC, Ribeiro I, Hino AAF, Hallal PC, et al. Walking for leisure among adults from three Brazilian cities and its association with perceived environment attributes and personal factors. Int J Behav Nutr Phys Act 2011; 8:111.

[25] ²⁵
Gomes R, Nascimento EF, Araújo FC. Por que os homens buscam menos os serviços de saúde do que as mulheres? As explicações de homens com baixa escolaridade e homens com ensino superior. Cad Saúde Pública 2007; 23:565-74.

[26] ²⁶
Flint E, Webb E, Cummins S. Change in commute mode and body-mass index: prospective, longitudinal evidence from UK Biobank. Lancet Public Health 2016; 1:e46-e55.

[27] ²⁷
Lusk AC, Mekary RA, Feskanich D, Willett WC. Bicycle riding, walking, and weight gain in premenopausal women. Arch Intern Med 2010; 170:1050-6.

[28] ²⁸
Littman AJ, Kristal AR, White E. Effects of physical activity intensity, frequency, and activity type on 10-y weight change in middle-aged men and women. Int J Obes (Lond) 2005; 29:524-33.

[29] ²⁹
Pucher J, Buehler R, Bassett DR, Dannenberg AL. Walking and cycling to health: a comparative analysis of city, state, and international data. Am J Public Health 2010; 100:1986-92.

[30] ³⁰
Codogno JS, Turi BC, Kemper HC, Fernandes RA, Christofaro DG, Monteiro HL. Physical inactivity of adults and 1-year health care expenditures in Brazil. Int J Public Health 2015; 60:309-16.

[31] ³¹
Kelly P, Kahlmeier S, Götschi T, Orsini N, Richards J, Roberts N, et al. Systematic review and meta-analysis of reduction in all-cause mortality from walking and cycling and shape of dose response relationship. Int J Behav Nutr Phys Act 2014; 11:132.

[32] ³²
Oja P, Titze S, Bauman A, Geus B, Krenn P, Reger-Nash B, et al. Health benefits of cycling: a systematic review. Scand J Med Sci Sports 2011; 21:496-509.

[33] ³³
Sener IN, Lee RJ, Elgart Z. Potential health implications and health cost reductions of transit-induced physical activity. J Transp Health 2016; 3:133-40.

[34] ³⁴
Jarrett J, Woodcock J, Griffiths UK, Chalabi Z, Edwards P, Roberts I, et al Effect of increasing active travel in urban England and Wales on costs to the National Health Service. Lancet 2012; 379:2198-205.

[35] ³⁵
Gu J, Mohit B, Muennig PA. The cost-effectiveness of bike lanes in New York City. Inj Prev 2017; 23:239-43.

[36] ³⁶
Katzmarzyk PT, Gledhill N, Shephard RJ. The economic burden of physical inactivity in Canada. CMAJ 2000; 163:1435-40.

[37] ³⁷
Araujo MYC, Sarti FM, Fernandes RA, Monteiro HL, Turi BC, Anokye N, et al. Association between costs related to productivity loss and modified risk factors among users of the Brazilian National Health System. J Occup Environ Med 2017; 59:313-9.

Parameter	Cycling-no (n = 171)	Cycling-yes (n = 27)	Walking-no (n = 35)	Walking-yes (n = 163)
Parameter	Mean (SD)	Mean (SD)	Mean (SD)	Mean (SD)
Age (years) baseline	61.8 (8.7)	60.1 (8.7)	63.9 (9.8)	61.1 (8.4)
Body weight (kg) baseline	73.1 (15.2)	71.8 (9.4)	71.7 (14.4)	73.2 (14.6)
BMI (kg/m²)	29.8 (5.6)	27.2 (2.5) *	29.9 (5.5)	29.4 (5.3)
%BF-BIA baseline	40.1 (8.1)	33.2 (4.8) *	40.3 (8.9)	38.8 (7.8)
WC (cm) baseline	92.9 (13.8)	92.8 (7.8)	90.9 (10.9)	93.3 (13.6)
SBP (mmHg) baseline	130.6 (20.1)	126.3 (15.7)	132.6 (19.4)	129.4 (19.5)
DBP (mmHg) baseline	76.3 (11.4)	78.1 (8.1)	76.9 (8.8)	76.5 (11.5)
Economic condition score baseline	19.2 (4.7)	21.2 (4.7) *	19.2 (4.6)	19.5 (4.8)
Healthcare costs (USD) 24 months	369.19 (224.42)	274.36 (177.04) *	347.67 (177.50)	358.11 (229.23)
Arterial hypertension (yes) baseline [%]	67.3	37.1 *	68.6	62.1
Dyslipidemia (yes) baseline [%]	37.4	33.3	37.1	36.8
Diabetes mellitus (yes) baseline [%]	24.6	22.2	20.1	25.2

Frequency	Baseline	6-month	12-month	18-month	Spearman correlation (rho)
Frequency	n (%)	n (%)	n (%)	n (%)	Spearman correlation (rho)
Cycling
Never	180 (90.9)	185 (93.4)	183 (92.4)	183 (92.4)	Baseline × 6-month = 0.561 *
Seldom	5 (2.5)	3 (1.5)	7 (3.5)	6 (3.0)	Baseline × 12-month = 0.568 *
Sometimes	9 (4.5)	6 (3.0)	6 (3.0)	4 (2.0)	Baseline × 18-month = 0.586 *
Often	2 (1.0)	0 (0.0)	0 (0.0)	4 (2.0)	6-month × 12-month = 0.641 /6-month × 18-month = 0.630
Always	2 (1.0)	4 (2.0)	2 (1.0)	1 (0.5)	12-month × 18-month = 0.583 *
Walking
Never	106 (53.5)	108 (54.5)	104 (52.5)	117 (59.1)	Baseline × 6-month = 0.349 *
Seldom	27 (13.6)	17 (8.6)	24 (12.1)	19 (9.6)	Baseline × 12-month = 0.225 *
Sometimes	25 (12.6)	26 (13.1)	21 (10.6)	24 (12.1)	Baseline × 18-month = 0.274 *
Often	13 (6.6)	19 (9.6)	28 (14.1)	19 (9.6)	6-month × 12-month = 0.342 /6-month × 18-month = 0.252
Always	27 (13.6)	28 (14.1)	21 (10.6)	19 (9.6)	12-month × 18-month = 0.288 *

	Baseline	6-month	12-month	18-month	ANOVA repeated measures (p-value) *
	Mean (95%CI)	Mean (95%CI)	Mean (95%CI)	Mean (95%CI)	Time	Cycling	Time × Cycling
Costs (USD)					0.601	0.507	0.178
Cycling-no (n = 171)	83.97 (75.71-92.32)	87.63 (78.91-97.70)	92.98 (83.32-102.27)	95.42 (85.10-105.08)
Cycling-yes (n = 27)	94.48 (72.62-116.34)	70.93 (47.94-93.82)	80.78 (55.45-105.08)	85.47 (58.26-112.59)
WC (cm)					0.602	0.293	0.725
Cycling-no (n = 171)	93.1 (91.2-95.1)	96.8 (95.1-98.5)	96.2 (94.4-97.9)	96.7 (94.9-98.5)
Cycling-yes (n = 27)	91.7 (86.6-96.7)	94.4 (89.7-99.1)	92.8 (88.3-97.4)	93.9 (89.3-98.6)
%BF-BIA					0.304	0.028	0.973
Cycling-no (n = 171)	39.4 (38.3-40.4)	39.4 (38.4-40.5)	39.1 (37.9-40.1)	39.1 (37.9-40.1)
Cycling-yes (n = 27)	36.1 (33.2-38.8)	36.3 (33.6-39.1)	35.8 (33.1-38.6)	35.7 (32.8-38.6)

	Baseline	6-month	12-month	18-month	ANOVA repeated measures (p-value) *
	Mean (95%CI)	Mean (95%CI)	Mean (95%CI)	Mean (95%CI)	Time	Cycling	Time × Cycling
Costs (USD)					0.452	0.562	0.608
Walking-no (n = 35)	86.04 (67.65-104.15)	84.53 (65.02-104.15)	81.25 (59.86-102.27)	86.51 (63.61-108.84)
Walking-yes (n = 163)	85.29 (76.84-93.82)	85.57 (76.56-93.82)	93.35 (83.60-102.27)	95.79 (85.19-106.02)
WC (cm)					0.395	0.799	0.202
Walking-no (n = 35)	91.5 (87.1-95.8)	97.4 (93.4-101)	95.7 (91.8-99.6)	95.1 (90.9-99.1)
Walking-yes (n = 163)	93.2 (91.2-95.2)	96.2 (94.4-98.1)	95.7 (93.9-97.5)	96.6 (94.7-98.4)
%BF-BIA					0.335	0.815	0.506
Walking-no (n = 35)	39.4 (37.1-41.8)	38.8 (36.5-41.1)	38.9 (36.6-41.3)	38.8 (36.3-41.3)
Walking-yes (n = 163)	38.8 (37.2-39.9)	39.1 (37.9-40.1)	38.4 (37.3-39.5)	38.5 (37.3-39.7)

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Impact of cycling and walking on adiposity and healthcare costs among adults: longitudinal study

Impacto do ciclismo e da caminhada na adiposidade e nos custos de saúde em adultos: estudo longitudinal

Impacto de andar en bicicleta y caminar sobre la adiposidad y los costos de salud en adultos: estudio longitudinal

Abstract:

Resumo:

Resumen:

Introduction

Methods

Sample and sampling

Dependent variable: healthcare costs

Dependent variable: anthropometry and bioelectrical impedance analysis

Independent variable: walking and cycling

Covariates

Statistical analysis

Results

Discussion

Conclusion

Acknowledgments

References

Publication Dates

History