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Abstract
As older adults in an early stage (prefrailty) of frailty may return to a healthy state, it is necessary to examine the prevention of prefrailty. In this context, the number and types of social participation activities associated with physical prefrailty in community-dwelling older adults have remained relatively unexplored. This cross-sectional study investigates this issue by analyzing 616 participants living in Okinoshima, Shimane, a rural area of Japan, in 2019. Frailty was assessed using the 5-item frailty phenotype (unintentional weight loss, self-reported exhaustion, weakness, slow walking speed, and low physical activity). Data on social participation were obtained using a questionnaire based on participants’ level of involvement with volunteer groups, sports clubs/groups, neighborhood associations, religious organizations/groups, and community elderly salons; their answers were categorized as “yes” if they answered “several times per year or more” and “no” if they answered “never.” Binominal logistic regression was used to estimate odds ratios (OR) and 95% confidence intervals (CI) of prefrailty by the number or types of social participation activities, adjusted for gender, age, body mass index, smoking, medication-taking, educational attainment, working status, and living arrangement. Of the 616 participants, 273 (44.3%) and 28 (4.5%) had prefrailty and frailty, respectively. The analysis showed that the number of social participation activities was significantly associated with lower odds of prefrailty (OR = 0.83; 95% CI, 0.74–0.94). Regarding the types of social participation, sports clubs/groups were associated with lower odds of prefrailty (OR = 0.47; 95% CI, 0.31–0.73). Participation in neighborhood associations was associated with prefrailty/frailty (OR = 0.57; 95% CI, 0.37–0.86). These results suggest that increasing the number of social participation activities or involvement in sports clubs/groups and neighborhood associations may be important to prevent physical prefrailty in the older population.
Citation: Abe T, Okuyama K, Kamada M, Yano S, Toyama Y, Isomura M, et al. (2020) Social participation and physical prefrailty in older Japanese adults: The Shimane CoHRE study. PLoS ONE 15(12): e0243548. https://doi.org/10.1371/journal.pone.0243548
Editor: Masaki Mogi, Ehime University Graduate School of Medicine, JAPAN
Received: September 11, 2020; Accepted: November 24, 2020; Published: December 16, 2020
Copyright: © 2020 Abe 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 paper and its Supporting information files.
Funding: This study was supported by JSPS KAKENHI Grant Number 19H03996(MK) and 19K11667 (RM)and the Kieikai Research Foundation (RM). JSPS KAKENHI: https://kaken.nii.ac.jp/ja/index/ Kiekai Research Foundation: https://www.nakashima-foundation.org/kieikai/research/index19.html The funders did not play any role in the study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Frailty is a major symptom of age-related decline in late life. It is defined as a state of heightened vulnerability to stressors as a result of reduced physiological reserve due to a cumulative decline in the ability to maintain homeostasis and impairments in multiple systems [1]. Physical frailty is a risk factor for a poor quality of life, physical disability, and mortality [2–4]. Previous reviews have reported a global prevalence of frailty ranging from 4.9% to 27.3% [5–7]. A study reported that the prevalence rates of prefrailty and frailty in older Japanese adults aged 65 years or older were 48.1% and 7.4%, respectively [8]. Therefore, the prevention of frailty is an important public health concern [9].
Recently, the concept of frailty has been expanded beyond its physical aspect to include psychological and social aspects. In a scoping review of social frailty, social participation was suggested as a component of social behavior or activities [10]. Moreover, Duppen et al.’s systematic review proposed that social participation, one of the elements of the social environment, be modified to include the frailty concept [11]. The studies included in these reviews [10, 11] also reported that social participation is a predictor of frailty. The SHARE study, which included 11 European countries, reported a significant association between the deterioration of frailty and the lack of social participation, which included engaging in voluntary work, caring for sick persons, or participating in sports clubs [12]. Recently, a longitudinal study found that improvements in the frailty status of older Japanese adults were affected by regular participation in any of the eight included organization types [13]. Meanwhile, Woo et al.’s cross-sectional study reported that participation in community or religious activities was associated with lower frailty scores in older women [14]. On the contrary, some studies reported that the number of social participation activities was negatively associated with frailty among older adults [15, 16]. However, these studies did not investigate the association between both the number and types of social participation activities and physical frailty [10–16]. Social participation may depend on social resources in a residential area, such as differences between urban and rural areas [17]. Clarifying the relationship between the status of social participation and physical frailty in the rural region is important to promote frailty prevention measures among older adults. In particular, interventional action is recommended for community-dwelling older adults with prefrailty status for the prevention of transition to frailty. We hypothesized that social participation affects the transition to prefrailty among older adults. The present study aimed to investigate the number and types of social participation activities negatively associated with physical prefrailty among community-dwelling older Japanese adults.
Materials and methods
Study design
This cross-sectional study was part of the Shimane CoHRE Study conducted by the Center for Community-Based Healthcare Research and Education, Shimane University. Japanese people with national health insurance are eligible for a health examination in their municipality of residence. The data for this study were collected from a health examination conducted in Okinoshima town (population: 14608; aging rate: 38.4%; area: 242.8 km2 (based on data from Japan’s census in 2015)), Shimane, rural Japan, in June 2019. Overall, 666 older adults participated in health examinations. The present study invited residents to voluntarily participate in the survey and did not provide any incentive. Participant inclusion criteria were: participated in a health examination, agreed to respond to our survey, and availability of data about frailty. After excluding participants with non-responses to the survey (n = 6) and missing data about frailty (n = 44), we analyzed data from 616 participants (response rate, 99.1%). The study protocol was approved by the Ethics Committee at Shimane University (#2888), and written informed consent was obtained from all participants before enrollment.
Physical frailty
We considered the physical frailty phenotype as being characterized by the presence of three or more of the following five conditions, based on Fried et al. and modified for the Japanese population according to the Japanese version of the Cardiovascular Health Study (J-CHS) criteria [5, 18]: slowness, weakness, exhaustion, low activity levels, and weight loss. Participants who did not have any of these conditions were considered non-frail, whereas those reporting one or two of these conditions were considered prefrail.
Slowness and weakness were assessed by objectively measuring gait speed and grip strength. Gait speed was measured using a sheet-type pressure sensor (45.5 × 183 cm plate sensor; Healthwalk; Kao Corporation, Japan) placed in the center of a 5-meter walkway [19]. Participants were asked to walk freely along a 7-meter course and return to the starting point. The average walking speed to complete the distance for both right and left feet was used for the analysis. Slow gait speed was determined based on a cutoff speed of < 1.0 m/s [20]. Grip strength was measured using a Smedley-type handheld dynamometer (GRIPD; Takei, Niigata, Japan). Weakness was identified using maximum grip strength, and sex-specific cutoffs were applied (< 26 kg for men and < 18 kg for women) [21]. Exhaustion was identified based on a “yes” response to the following question: “In the last two weeks, have you felt tired for no reason?” Participation in physical activity was measured by the following items: (1) “Do you engage in regular physical exercise or sports to improve your health (including agricultural activities)?” and (2) “Do you engage in light-intensity levels of physical exercise to improve your health?” If participants answered “no” to both questions, we categorized them into the low-physical activity group in accordance with a previous study [18]. Weight loss was determined by a “yes” response to the question, “Have you lost 2–3 kg or more in the past six months?”: A supporting information, “This does not include a medical doctor’s guidance or intentional diet for health” was provided based on the Kihon Checklist questionnaire [22].
Social participation
Social participation was assessed using a self-administered questionnaire and classified into five types: volunteer groups, sports groups/clubs, neighborhood associations, religious organizations/groups, and community elderly salons [23]. Participants reported their frequency of participation in each type of organization by choosing one of the following response options: four times or more per week, two to three times per week, once a week, one to three times per month, several times per year, and never. The response was categorized as “yes” if the participants answered “several times per year or more” and “no” if they answered “never” [24]. Involvement in various types of social activities was counted and classified from 5 (participation in all) to 0 (no participation). The number of social participation activities was used as a continuous variable [15]. In addition, we used each type of social participation as a binary variable (yes or no) in order to assess the association between physical prefrailty and types of social participation.
Covariates
Data on gender (men or women), age (≥75 or <75 years), current smoking habit (yes or no), medication-taking, educational attainment, working status, and living arrangement were obtained using a questionnaire. Medication-taking for the treatment of hypertension, high cholesterol level, or diabetes was categorized into three groups (no medication, 1 medicine, and 2–3 medicines). Educational attainment was defined as the highest education completed and was classified into three categories (< 10 years:–junior high school; 10–12 years:–high school; ≥ 13 years:–junior college/college of technology; and higher education). Working status was categorized based on a yes or no answer. Living arrangement was classified as single household (living alone) or non-single household (living with others); single household was defined as living alone based on marital status (no spouse or children). From the obtained data, body mass index (BMI) was calculated by dividing the body weight by the squared height (kg/m2).
Statistical analysis
Missing information about independent variables, which ranged from 3.1% to 26.0% (S1 Table), was processed using multiple imputations under the missing at random assumption [25]. Each imputation was based on regression models of the analyzed variables. The 10 imputed datasets were analyzed independently and combined for inference, accounting for the variability of imputation [25]. Participants’ characteristics were described by frailty status. The number in each frailty status was estimated as all imputed binary variables to ranging between 0 and 1 rather than rounding values [26]. Between-group differences were determined using a χ2 test for categorical variables and the analysis of variance or Kruskal-Wallis test for continuous data. After excluding participants with frailty (n = 28), in the cross-sectional analyses (n = 588), binominal logistic regression analyses were performed to estimate the odds ratios (OR) and 95% confidence intervals (CI) for having prefrailty by the number or types of social participation activities. Independent variables were not adjusted for in Model 1, and Model 2 included gender (reference category: men), age (reference category: < 75 years), BMI (continuous variable), smoking (reference category: no), medication-taking (reference category: no), educational attainment (reference category: < 10 years), working status (reference category: yes), and living arrangement (reference category: living with others). None of the variables had correlations of sufficient strength to indicate multicollinearity (r < 0.39, S2 Table). Statistical analyses were performed using SPSS version 23 (IBM Corp., Armonk, NY, USA). All p-values for statistical tests were two-tailed, and values < 0.05 were regarded as statistically significant.
Results
A total of 616 older adults (232 men and 384 women) participated in this study. Of them, 4.5% had frailty (men: 3.4%; women: 5.2%), and 44.3% had prefrailty (men: 41.8%; women: 45.8%) as shown in S1 Table. Table 1 shows the prevalence of frailty by the number and types of social participation activities. The mean (standard deviation) number of social participation activities by frailty status was 2.3 (1.5) in robust participants, 1.9 (1.4) in prefrail participants, and 1.7 (1.4) in frail participants, respectively. As for the types of social participation activities, prevalence rates for prefrailty (51.2%) and frailty (8.7%) were the highest for those who did not participate in their neighborhood associations.
Table 2 shows the associations between the number of social participation activities and prefrailty. The binominal logistic regression analysis showed that the number of social participation activities was significantly associated with lower odds of prefrailty (OR: 0.83, 95% CI: 0.74–0.94) in Model 2.
Table 3 shows the associations between the types of social participation and prefrailty. The binominal logistic regression analysis showed that participation in sports clubs/groups was significantly associated with prefrailty (OR: 0.47, 95% CI: 0.31–0.73) in Model 2. Participation in neighborhood associations was also significantly associated with prefrailty (OR: 0.57, 95% CI: 0.37–0.86) in Model 2. However, participation in volunteer groups, religious organizations/groups, and community elderly salons was not associated with prefrailty.
Discussion
This study is the first to examine the association between the number or types of social participation activities and physical prefrailty in older Japanese adults. Two major findings were obtained. First, regarding the number of social participation activities, an increase by one was associated with lower odds of prefrailty. Second, older adults participating in sports clubs and neighborhood associations had significantly lower odds of prefrailty. Our findings suggest that focusing on the number and types of social participation activities may contribute to preventing physical prefrailty among older Japanese adults.
Our findings are consistent with some previous studies. A cross-sectional study among older adults in Taiwan reported associations between physical frailty based on the Fried index and the number of social activities including leisure, religious activities, visiting friends and relatives, and chatting with neighbors [15]. The number of social activities, considered a continuous variable, was negatively associated with prefrailty and frailty. Ye et al.’s study used a total score based on the frequency of participation in any of the eight types of activities in Chinese older adults [16]. The increasing score of the frequency of social participation activities was negatively associated with frailty. Abe et al.’s study used the Kaigo-Yobo Checklist to examine whether frailty was associated with social participation activities among community-dwelling older adults in Japan [13]. Their study examined social participation across three levels of frequency (regular, irregular, and non-participation) in any of the eight types of activities. Those who regularly participated in social activities reported improvements in their frailty status. A relationship between social participation and physical health outcomes has also been reported in some previous studies. Kanamori et al.’s four-year follow-up study on older Japanese adults found that the number and types of social participation activities were associated with functional disability [27]. The previously mentioned study showed that participation in three or more organizations was associated with lower incidence of disability. Moreover, as for the type of social participation activity, participation in the local community, including neighborhood associations and sports clubs/groups, was associated with a lower likelihood of disability. Further, a three-year follow-up study examined whether the number and types of social participation activities were associated with instrumental activities of daily living among community-dwelling older men and women [28]. The study found that participation in three or more activities was associated with lower odds of decline in instrumental activities of daily living for both men and women in the age-adjusted model. Moreover, participation in neighborhood community associations was associated with a lower risk of decline in instrumental activities of daily living among older women.
The mechanisms underlying the association between social participation and frailty among older adults are likely complex [29]. We speculated about the mechanism underpinning the relationship between social participation and physical prefrailty based on a previous finding, according to which social participation provides opportunities for older adults to access various social support networks [30]. For example, it might be easier for older adults to access health information at various social events. Moreover, a high frequency of social participation activities is positively associated with physical activity, which may contribute to improving motor function and mental health [31–33]. Meanwhile, for the association between participation in sports clubs/groups and prefrailty, systematic reviews reported the benefits of physical exercise training for frail older adults [34, 35]. This may explain the inverse association between participation in sports clubs/groups and prefrailty.
Participation in community salons showed a positive trend with frailty, as shown in Table 1 (p = 0.06), although the association was not significant in any adjusted model. In 2017, the Japanese government launched the “community elderly salon” program in neighborhood communities as a national long-term care strategy [36]. Therefore, the positive relationship might be explained by the fact that frail older adults in the community were preferentially encouraged to participate. In the long-term, participation in community salons may reduce the prevalence of frailty [23]. Our results suggest that future longitudinal studies are required to ascertain the details of the positive or negative relationship between participation in community elderly salons and frailty.
Regarding the relationship between demographic characteristics and frailty, only age showed a positive association, as depicted in Table 1. A meta-analysis of studies conducted among Japanese adults showed that the prevalence of frailty was significantly higher among older adults [8]. Our results are in keeping with this finding. Thus, in a super-aging society like Japan, it is important to prevent frailty as early as possible.
This study has several limitations. First, we used a cross-sectional design, which precludes the possibility of a causal inference between social participation and frailty. Older adults with poor physical functioning may not participate in social groups, suggesting that frailty might be a reason for the lack of social participation. Second, the participants were recruited from multiple centers and an annual health examination, which may have resulted in a selection bias. As the small sample caused a low statistical power, our results might underestimate the associations. Third, this study used a modified version of the frailty phenotype with J-CHS criteria to assess frailty in Japanese individuals; a previous review has reported that a modification of the frailty phenotype affects its classification and predictive ability [37]. Fourth, although social participation, physical activity, exhaustion, and weight loss associated with frailty were measured using self-report questionnaires based on the J-CHS [18], the relationship between social participation and frailty may have been over- or under-estimated because of a response bias. Fifth, although the item for measuring social participation was used in a previous study in Japan [27], it did not measure participant activities and the size of the unit in each social participation group. Moreover, type of social participation did not include professional organizations, politics, and cultural activities. Additionally, participants’ involvement and the activity’s content or variety (e.g., recreational walking at sports clubs, group conversations at neighborhood associations, cleaning streets with volunteer groups) may also affect older adults’ mental or physical health. Finally, we could not control for the effects of unmeasured factors, such as musculoskeletal disorders, cognitive status, and depression, on the relationship between social participation and prefrailty [33, 38–41].
Conclusions
This study found that a higher number of social participation activities was associated with lower odds of prefrailty among older adults living in a rural area of Japan. Further, participation in sports clubs/groups or neighborhood associations was associated with lower odds of prefrailty. Our findings suggest that social participation may be important to prevent physical prefrailty. However, further intervention-based longitudinal studies are needed to verify whether social participation has preventative effects on prefrailty.
Supporting information
S1 Table. Participant characteristics.
SD, standard deviation.
https://doi.org/10.1371/journal.pone.0243548.s001
(DOCX)
S2 Table. Correlation coefficient of independent variables.
*p < 0.05, **p < 0.01.
https://doi.org/10.1371/journal.pone.0243548.s002
(DOCX)
Acknowledgments
The authors would like to thank the members of the Okinoshima Town Public Health Division who helped with the community health examinations, all those who participated in this study, and the Shimane CoHRE study members for their skilled assistance. We would also like to thank the Personal Healthcare Institution of Kao Corporation (Tokyo, Japan) for the technical assistance provided.
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