https://orcid.org/0000-0003-4578-6214
Figures
Abstract
Background
Lower socioeconomic status (SES) may be related to inactivity lifestyle; however, the association between SES and physical inactivity has not been sufficiently investigated in Japan.
Methods
The study population is the participants of NIPPON DATA2010, which is a prospective cohort study of the National Health and Nutrition Survey 2010 in Japan. They were residents in 300 randomly selected areas across Japan. This study included 2,609 adults. Physical activity was assessed by physical activity index (PAI) calculated from activity intensity and time. The lowest tertile of PAI for each 10-year age class and sex was defined as physical inactivity. Multivariable logistic regression analyses were conducted to examine the association of SES (employment status, educational attainment, living status, and equivalent household expenditure (EHE)) with physical inactivity.
Results
In the distribution of PAI by age classes and sex, the highest median PAI was aged 30–39 years among men (median 38.6), aged 40–49 years among women (38.0), and median PAI was decreased with increasing age. Multivariable-adjusted model shows that not working was significantly associated with physical inactivity after adjustment for age in all age groups and sexes. Not living with spouse for adult women and elderly men was significantly associated with physical inactivity compared to those who living with spouse. However, neither educational attainment nor EHE had any significant associations with physical inactivity.
Citation: Sumimoto Y, Yanagita M, Miyamatsu N, Okuda N, Nishi N, Nakamura Y, et al. (2021) Association between socioeconomic status and physical inactivity in a general Japanese population: NIPPON DATA2010. PLoS ONE 16(7): e0254706. https://doi.org/10.1371/journal.pone.0254706
Editor: Kiyoshi Sanada, Ritsumeikan University, JAPAN
Received: March 24, 2021; Accepted: July 2, 2021; Published: July 15, 2021
Copyright: © 2021 Sumimoto et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the manuscript.
Funding: This study was supported by Health and Labour Sciences Research Grants of the Ministry of Health, Labour and Welfare, Japan (Comprehensive Research on Life-Style Related Diseases including Cardiovascular Diseases and Diabetes Mellitus [H22-Junkankitou-Seishuu-Sitei-017, H25-Junkankitou-Seishuu-Sitei-022, H30-Junkankitou-Sitei-002, 21FA2002]).
Competing interests: The authors have declared that no competing interests exist.
Introduction
Physical inactivity increases the risk of major non-communicable diseases (NCD), such as coronary heart disease, type 2 diabetes, and cancer (breast cancer and colon cancer), and shortened life expectancy [1]. The World Health Organization reported that physical inactivity is one of the primary four major risk factors leading for non-communicable diseases [2], and people who are insufficiently active have a 20% to 30% increased risk of death compared to people who are sufficiently active [3]. It is indicated that physical inactivity is related to low socioeconomic status (SES) [4].
In these last few decades, there is growing concern with the influence of SES; employment status, educational attainment, income level, etc., on health outcome. Previous studies have investigated the association between SES and physical inactivity, most of them from Western countries [5–8], and several studies from Japan [9–16], but the results have been inconsistent. There were some reasons for the inconsistent results of socioeconomic inequalities in physical activity. First, it might be caused by the contrasting for occupational activity and leisure time activity due to socioeconomic status [17]. Second, previous studies before 2010, occupation, the area of residence and age of the participants were limited [9–11], which may have caused selection bias in the participants, and there are concerns about the accuracy of the data because the data collection methods used were the Internet and mail questionnaires [12,13]. Since 2010, there have been several reports on the association between physical activity and mortality and/or disease risk factors [14,15], but only one study on the association between physical activity and socioeconomic status [16]. In recently, there are growing concerns that social inequalities may grow wider in Japan and generate a harmful effect on health [18].
Therefore, we examined to the association between SES and physical inactivity to identify subgroup with physical inactivity using the baseline data of NIPPON DATA2010. This cohort study is unique because the participants were general Japanese adult population from 300 randomly selected districts throughout Japan and focus on the impact of socioeconomic status on health [19]. Analysis of the causes of physical inactivity, specifically the association between SES and physical inactivity using the baseline data of NIPPON DATA2010 can provide insights into opportunities and priorities for prevention, intervention and policy to physical inactivity.
Material and methods
Study population
A prospective cohort study on cardiovascular disease, the National Integrated Project for Prospective Observation of Non-communicable Disease And its Trends in the Aged 2010 (NIPPON DATA2010) was established in 2010 [19]. This study was performed using data from the National Health and Nutrition Survey in November 2010 (NHNS2010) and the Comprehensive Survey of Living Conditions in June 2010 (CSLS2010), which were conducted by the Ministry of Health, Labour and Welfare of Japan.
In November 2010, 8,815 residents aged 1 year and older from 300 randomly selected districts throughout Japan participated in the dietary survey for NHNS2010. Among 7,229 participants age 20 years and older, 3,873 participants (1,598 men and 2,275 women) had a blood test of NHNS2010 and were invited to enroll in NIPPON DATA2010. A total of 2,898 participants (1,239 men and 1,659 women; participant rate, 74.6%) agreed to participate in the baseline survey for NIPPON DATA2010. Trained interviewers obtained written informed consent from all participants before enrollment. Data obtained from NHNS2010 and CSLC2010 were merged with data from NIPPON DATA2010. The Institutional Review Board of Shiga University of Medical Science (No. 22–29, 2010) approved this study.
For this study, of the 2,898 participants, 91 were excluded because it was not possible to merge data from NHNS2010 or CSLC2010 with NIPPON DATA2010 baseline data. Additionally, seven who were over 90 years old, 150 who could not exercise due to health reasons, and 41 who were lacking main variables were excluded. The remaining 2,609 participants (1,132 men and 1,477 women) were included in the present study.
Physical activity index
To evaluate physical activity, questions were posed about number of hours per day spent in the baseline survey of NIPPON DATA2010; the interviewer ensured that the total time added up to 24h. Physical activity by intensity was defined as follows; (1) heavy activity (construction work, agriculture, sports such as jogging, etc); (2) moderate activity (light work done standing, housework, gardening and walking, etc); (3) slight activity (light work done sitting, office work, driving a car, eating and taking a bath, etc); (4) watching television (TV) and other sedentary (sitting such as reading); (5) no activity (sleeping and lying down).
Physical activity index (PAI) was calculated by multiplying the time spent in different activities by corresponding weighting factors that parallel the increased rate of oxygen consumption associated with increasingly more intense physical activity (weighting factors; heavy activity for 5.0, moderate activity for 2.4, slight activity for 1.5, watching TV and other sedentary for 1.1 and no activity for 1.0); the procedure used in the Framingham Offspring study was followed [20].
Total physical activity index = 5.0×hours of heavy activity + 2.4×hours of moderate activity + 1.5×hours of slight activity + 1.1×hours of watching TV and other sedentary + 1.0× hours of no activity.
It was not possible to determine a cutoff value that defines a state in which the amount of moderate-vigorous intensity physical activity performed per week is less than the recommended amount, as in the WHO guidelines, because PAI was calculated from daily physical activity. Therefore, we referred to that previous studies which divided PAI into tertiles and classified the lowest tertile as insufficient physical activity in the Framingham Study [21,22]. In this study, we confirmed the distribution of the physical activity index and found that it differed greatly by sex and age. To account for these differences, we divided the PAI by sex and age class and defined the lowest tertile for each as physically inactive.
Socioeconomic status
Information on SES was collected using self-administered questionnaires for NHNS2010 (employment status), CSLC2010 (living status, monthly household expenditure of May 2010, number of family member, house ownership) and NIPPON DATA2010 (educational attainment). Equivalent household expenditure (EHE) were calculated as monthly household expenditure divided by the square root of the number of family member and categorized into tertile. House ownership was used to adjust the EHE, because in the CSLC questionnaire, rent in non-house owners was taken into account as a part of expenditure, but mortgate payments in home owner was not.
SES was defined as follow: (1) employment status (working [including self-employed] or not working [including students and homemakers]); (2) educational attainment (junior high school, high school, college or higher); (3) living status (living with spouse or not living with spouse); (4) EHE (first tertile [less than 106,000 yen], second tertile [106,000 yen or more but less than 162,000 yen], third tertile [162,000 yen or more]).
Lifestyle and other variables
Public health nurses collected information on alcohol drinking habit, smoking habit and past histories of myocardial infarction and stroke using a standardized questionnaire in NHNS. Alcohol drinking habit, smoking habit and past histories were obtained from NHNS2010. Participants had past histories of myocardial infarction and/or stroke were defined as having past histories. These were classified as follow: (1) alcohol drinking habit (current drinker, ex-drinker or non-drinker); (2) smoking habit (current smoker, ex-smoker or non-smoker); (3) Past histories (yes or no).
Statistical analysis
Statistical analyses were performed for men/women and for adult (aged 20–59 years)/elderly (aged 60–89 years), separately, because basic living practice, e.g., working or not working, would differ substantially by sex and by age groups. In addition, the age of retirement was usually set at 60 years of age for indefinite-term employees at most workplaces in Japan.
To evaluate physical inactivity in each age class, PAI was divided into tertiles in seven age classes (20–29, 30–39, 40–49, 50–59, 60–69, 70–79, and 80–89) for men and women separately.
To evaluate association of SES and physical inactivity, the odds ratios (ORs) and 95% confidence intervals (95% CIs) for physical inactivity were calculated by multiple logistic regression analyses, using explanatory variable (employment status, educational attainment, living status and EHE) and possible confounding factors (alcohol drinking habit, smoking habit and past histories). We used three models. Model l was adjusted for age. Model 2 was further adjusted with alcohol drinking habit, smoking habit and past histories. For Model 3, we put all the SES factors and confounding factors simultaneously. For analyses on EHE, we additionally adjusted for house ownership (owned or rented). P<0.05 was considered statically significant. All statistical analyses were performed using SPSS version 24 for Windows.
Results
Characteristics of participants
Table 1 shows the distribution of age, employment status, educational attainment, EHE, and other variable by sex and age groups. For employment status, adult participants who were not working were 6.1% for men and 35.3% for women. Elderly participants who were not working were 55.0% for men and 76.6% for women. For educational attainment, approximately half of adult participants graduated from college or higher (48.1% for men and 51.7% for women), whereas most elderly participants of both sexes graduated from high school or junior high school. For living status, most adult women lived with spouse (84.6%), whereas the rate in elderly women was lower (65.5%).
The distribution of physical activity index
Table 2 shows median and interquartile range of PAI for men and women in seven age classes. Among the seven age classes, median of total PAI, interquartile range was highest in aged 30–39 years among men (median 38.6), while it was highest in aged 40–49 years among women (38.0). The median of total PAI decreased with increasing age, and aged 80–89 years was the lowest in both men (30.8) and women (32.9). Regarding median PAI by each intensity of activities in sex and age classes, PAI of moderate activity included housework was higher score than PAI of other activity in women (S1 Table).
Association between socioeconomic status and physical inactivity
Tables 3 and 4 shows results from multiple logistic regression analysis using physical inactivity as an objective variable and socioeconomic factors as explanatory variables. Results were almost similar in three models. In Model 3, significantly increased ORs for physical inactivity were observed for not working participants compared with working participants after adjustment age in all strata (OR 3.38 in adult men, 1.46 in adult women, 2.17 in elderly men, 1.72 in elderly women). For living status, there was no significant association with physical inactivity in adult men. However, elderly men not living with spouse had higher OR for physical inactivity than those who were living with spouse (OR 2.01). On the other hand, adult women not living with spouse had higher OR for physical inactivity than those who were living with spouse (OR 1.63), although there was no significant association in elderly women. Regarding educational attainment and EHE, neither of them showed any significant associations with physical inactivity in all strata. Results were similar even after adjusting for body mass index and living with others (S2 Table).
Discussion
In the present analysis of a nationwide cross-sectional study of a randomly selected sample of adults in a Japanese population, it was indicated that the detailed distribution of PAI by age classes and sex, and the association between SES and physical inactivity in a general Japanese population. A main finding was that not working was related to physical inactivity in all strata. In addition, not living with spouse for adult women and elderly men was related to physical inactivity compared with living with spouse.
Regarding employment status, numerous previous studies reported that not working persons were physically inactive compared to those who were working [8,23–25]. This study in Japan supports the result of previous studies, and significant association was found not only in adult but also in elderly. The reason why not working elderly had a significantly associated with physical inactivity, it is possible that lifestyle habits changed. According to previous studies, the elderly had prolonged television viewing time and sedentary time after retirement [26–28]. These phenomena may be partly explained that not working elderly was likely to be physically inactive in this study.
Regarding living status, the results of previous studies were not consistent [23,29–31]. In this study, adult women and elderly men not living with spouse had a significantly higher risk of physical inactivity. The reason for physical inactivity in adult women not living with spouse may be related to the gender difference in housework time due to marital status. In this study, 71.3% of adult women not living with spouse were unmarried. According to a survey by the Cabinet Office of Japan, between unmarried and married women, there was a slight difference in working time, but there was 4-hour difference in housework time; on the other hand, in men, there was little difference in working time and housework time due to marital status [32]. As mentioned above, the gender role difference due to marital status may account for physical inactivity in adult women in Japan.
The reason for physical inactivity in elderly men not living with spouse may be related to the gender difference due to effects from being widowed or divorced. In fact, previous study reported that 80% of married men recognized their spouse as a person who controlled for their health [33]. Some studies reported that elderly men after widow or divorce decreased vegetable intake, increased smoking and alcohol consumption, and had higher stress and depression [34–37]. On the other hand, no association was found in elderly women. According to a survey by the Cabinet Office of Japan, approximately 80% of elderly men responded that their spouses give “mental support,” whereas only a half of women responded so [38]. The gender difference in support by spouse may account for the difference in the relationship of spouse to physical inactivity.
From the reason above, widowed or divorced men may be particularly physically inactive. A previous study showed that loneliness was an independent risk factor for physical inactivity in the elderly [39]. Loneliness caused by loss of occupation, social status due to retirement, and loss of mental support due to widow or divorce may be related to physical inactivity. Therefore, avoiding loneliness would be useful to prevent physical inactivity. Several studies reported that there was a positive association between neighborhood relationship and moderate to vigorous physical activity [40,41].
In this study, education attainment and EHE were not any significantly associated with physical inactivity. The results were somewhat inconsistent with most previous studies in which educational attainment and income were one of determinants of physical inactivity [5,6,31]. Compared to other countries, our results suggest that the impact of socioeconomic disparities according to educational attainment and income to physical inactivity may be small. Therefore, to identify subgroup which need intervention to prevent physical inactivity in Japan, we should be focus on employment status and living status.
This study has several limitations. First, because of the cross-sectional nature of this study, we were unable to determine whether there was a casual association between SES and physical inactivity. The second, we investigated total physical activity hours which were classified by intensity; thus, the type of physical activity could not be assessed.
Finally, physical activity was assessed using self-administered questionnaires, recall bias may have occurred, and physical activity may have been overestimated or underestimated.
Conclusion
The present study from a nationwide survey of the general Japanese population demonstrated that in the distribution of PAI, the highest median PAI was differed by age and sex, however PAI decreased with increasing age in both sexes. In the association between SES and physical inactivity, not working was associated with physical inactivity regardless of age and sex, whereas not living with spouse was differently associated by age and sex. These results will contribute to public health interventions which prevent socioeconomic inequalities in physical inactivity.
Supporting information
S1 Table. Distribution of physical activity index by each intensity of activities.
https://doi.org/10.1371/journal.pone.0254706.s001
(PDF)
S2 Table. Association between socioeconomic status and physical inactivity.
https://doi.org/10.1371/journal.pone.0254706.s002
(PDF)
Acknowledgments
We deeply appreciate the Japanese Association of Public Health Center Directors and the Japan Medical Association for their support with NIPPON DATA2010’s baseline and follow-up survey. We also thank the staffs of the Japanese public health centers and medical examination institutions listed in the Appendix of the reference [15].
The NIPPON DATA2010 Research Group
Chairpersons: Katsuyuki Miura (NCD Epidemiology Research Center, Shiga University of Medical Science, Otsu, Shiga, Japan) and Akira Okayama (Research Institute of Strategy for Prevention, Chuo, Tokyo, Japan) Research members: Hirotsugu Ueshima (NCD Epidemiology Research Center, Shiga University of Medical Science, Otsu, Shiga, Japan), Shigeyuki Saitoh (School of Health Sciences, Sapporo Medical University, Sapporo, Hokkaido, Japan), Kiyomi Sakata (Department of Hygiene and Preventive Medicine, Iwate Medical University, Yahaba, Iwate, Japan), Atsushi Hozawa (Department of Preventive Medicine and Epidemiology, Tohoku Medical Megabank Organization, Tohoku University, Sendai, Miyagi, Japan), Hiroshi Yanagawa (Jichi Medical University, Shimotsuke, Tochigi, Japan), Yosikazu Nakamura (Department of Public Health, Jichi Medical University, Shimotsuke, Tochigi, Japan), Tomonori Okamura (Department of Preventive Medicine and Public Health, Keio University School of Medicine, Shinjuku, Tokyo, Japan), Nobuo Nishi (International Center for Nutrition and Information, National Institute of Health and Nutrition, National Institutes of Biomedical Innovation, Health and Nutrition, Shinjuku, Tokyo, Japan), Takayoshi Ohkubo (Department of Hygiene and Public Health, Teikyo University School of Medicine, Itabashi, Tokyo, Japan), Fumiyoshi Kasagi (Institute of Radiation Epidemiology, Radiation Effects Association, Chiyoda, Tokyo, Japan), Yoshitaka Murakami (Department of Medical Statistics, School of Medicine, Toho University, Ota, Tokyo, Japan), Tohru Izumi (Kitasato University, Sagamihara, Kanagawa, Japan), Yasuhiro Matsumura (Faculty of Health and Nutrition, Bunkyo University, Chigasaki, Kanagawa, Japan), Toshiyuki Ojima (Department of Community Health and Preventive Medicine, Hamamatsu University School of Medicine, Hamamatsu, Shizuoka, Japan), Shinkan Tokudome (Nagoya City University Graduate School of Medical Sciences, Nagoya, Aichi, Japan), Hideaki Toyoshima (Nagoya University, Nagoya, Aichi, Japan), Hideaki Nakagawa (Medical Research Institute, Kanazawa Medical University, Uchinada, Ishikawa, Japan), Yoshikuni Kita (Faculty of Nursing Science, Tsuruga Nursing University, Tsuruga, Fukui, Japan), Aya Kadota (NCD Epidemiology Research Center, Shiga University of Medical Science, Otsu, Shiga, Japan), Naomi Miyamatsu (Department of Clinical Nursing, Shiga University of Medical Science, Otsu, Shiga, Japan), Yasuyuki Nakamura (Department of Public Health, Shiga University of Medical Science, Otsu, Shiga, Japan), Takehito Hayakawa (Research Center for Social Studies of Health and Community, Ritsumeikan University, Kyoto, Kyoto, Japan), Nagako Okuda (Department of Health Science, Kyoto Prefectural University, Kyoto, Kyoto, Japan), Katsushi Yoshita (Department of Food and Human Health Science, Osaka City University Graduate School of Human Life Science, Osaka, Osaka, Japan), Yoshihiro Miyamoto (Department of Preventive Cardiology, National Cerebral and Cardiovascular Center, Suita, Osaka, Japan), Naoyuki Takashima (Department of Public Health, Kindai University Faculty of Medicine, OSsaka-Sayama, Osaka, Japan), Akira Fujiyoshi (Department of Hygiene, Wakayama Medical University, Wakayama, Wakayama, Japan), Kazunori Kodama (Radiation Effects Research Foundation, Hiroshima, Hiroshima, Japan), Yutaka Kiyohara (Hisayama Research Institute for Lifestyle Diseases, Hisayama, Fukuoka, Japan), Hisatomi Arima (Department of Preventive Medicine and Public Health, Faculty of Medicine, Fukuoka University, Fukuoka, Fukuoka, Japan), Toshiharu Ninomiya (Department of Epidemiology and Public Health, Graduate School of Medical Sciences, Kyushu University, Fukuoka, Fukuoka, Japan) and Kazuo Ueda (Murakami Memorial Hospital, Nakatsu, Oita, Japan).
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