Skip to main content
Advertisement
  • Loading metrics

Impact of the COVID-19 pandemic on exercise habits and overweight status in Japan: A nation-wide panel survey

  • Sae Ochi ,

    Roles Conceptualization, Data curation, Formal analysis, Investigation, Methodology, Software, Validation, Visualization, Writing – original draft

    ochisae1024@jikei.ac.jp

    Affiliation Department of Laboratory Medicine, The Jikei University School of Medicine, Tokyo, Japan

  • So Mirai,

    Roles Conceptualization, Data curation, Formal analysis, Supervision, Writing – review & editing

    Affiliation Department of Psychiatry, Tokyo Dental College, Tokyo, Japan

  • Sora Hashimoto,

    Roles Conceptualization, Formal analysis, Methodology, Validation, Writing – review & editing

    Affiliation United Health Communication Co. Ltd., Tokyo, Japan

  • Yuki Hashimoto,

    Roles Conceptualization, Data curation, Methodology, Project administration, Supervision, Validation, Visualization, Writing – review & editing

    Affiliation Research Department, Research Institute of Economy, Trade and Industry, Tokyo, Japan

  • Yoichi Sekizawa

    Roles Conceptualization, Data curation, Funding acquisition, Methodology, Project administration, Resources, Software, Validation, Writing – review & editing

    Affiliation Research Department, Research Institute of Economy, Trade and Industry, Tokyo, Japan

Correction

15 Nov 2023: Ochi S, So M, Hashimoto S, Hashimoto Y, Sekizawa Y (2023) Correction: Impact of the COVID-19 pandemic on exercise habits and overweight status in Japan: a nation-wide panel survey. PLOS Global Public Health 3(11): e0002653. https://doi.org/10.1371/journal.pgph.0002653 View correction

Abstract

A catastrophic disaster may cause distant health impacts like immobility and obesity. The aim of this research was to analyse the association of the COVID-19 pandemic and lifestyle factors -exercise habit and overweight status in the Japanese population. Nation-wide online questionnaires were conducted five times from October 2020 to October 2021. The changes in exercise habit, body mass index (BMI) and overweight status (BMI >25kg/m2) were compared between the first questionnaire and a questionnaire conducted a year later. Risk factors for losing exercise habit or becoming overweight were analysed using multiple regression. Data were obtained from 16,642 participants. In the early phase of the pandemic, people with high income and elderly females showed a higher risk for decreased exercise days. The proportion of overweight status increased from 22.2% to 26.6% in males and from 9.3% to 10.8% in females. Middle-aged males, elderly females, and males who experienced SARS-CoV-2 infection were at higher risk of becoming overweight. Our findings suggest that risks for immobility and overweight are homogeneous. Continuous intervention for elderly females and long-term intervention for males infected with SARS-CoV-2 might be especially needed. As most disasters can cause similar social transformation, research and evaluation of immobility and obesity should address future disaster preparation/mitigation plans.

Introduction

During and after a catastrophic disaster population health may deteriorate in many ways. This impact on health is not limited to direct acute conditions such as injuries, but also includes indirect and chronic effects caused by lifestyle changes, mental stress, job losses, and social disruption. In particular, after chemical, biological, radiological, nuclear, or explosive (CBRNE) disasters, fear about invisible hazards may cause social panic that often leads to a deterioration in the health of the population. For example, after the Fukushima Daiichi nuclear power plant accident in 2011, the limitation of outdoor activities from fear of radiation exposure and other lifestyle changes led to an increase in metabolic syndromes such as hyperlipidaemia [1] and diabetes mellitus [2]. Some researchers estimated that this increase may have even shortened life expectancies to a greater extent than the small amount of radiation exposure caused by the accident [3]. Other health impacts among the evacuees included a decline in physical performance [4], increased obesity [5, 6], and a deterioration in mental status [7]. As the size of an indirect health impact surpasses that of a direct impact, preventing the indirect impacts is a key to retaining health in disaster areas.

Another type of CBRNE disaster, biological disaster, is a disaster caused by the rapid spread of disease caused by microorganisms. As fear of invisible microorganisms can cause social panic, the situation similar to nuclear disaster may happen. However, there is a paucity of research on these indirect health impacts and therefore more research is needed to address chronic conditions after a disaster and how communities can prepare and respond to disasters and public health emergencies.

The SARS-CoV-2 pandemic that started in late 2019 is one of the largest biological disasters of this decade. The virus had killed more than six million people by the end of June 2022 [8]. In addition, nationwide lockdowns, policies to encourage social distancing, travel restrictions, and voluntary bans of many activities in many countries may have caused severe social disruption and led to lifestyle changes such as alterations in eating habits [9, 10] and a decline in physical activities [11].

As a consequence of these changes, experts have raised concerns about an increase in the prevalence of obesity during and after the pandemic [12, 13]. Furthermore, previous research has suggested that COVID-19 itself may increase the risk of obesity [14]. However, the effect of such social disruption may be heterogeneous. A previous study targeting the population with obesity showed that only a limited number of people were vulnerable to lifestyle changes [15]. Other online surveys have even reported an improvement in body mass index (BMI) and eating habits among some groups of people [16, 17]. However, as these studies targeted the relatively younger population, there is a limitation in the generalizability of the findings. Therefore, a nation-wide survey is needed to understand the size and nature of the indirect impacts of the pandemic on risk factors associated with adverse health outcomes.

The “Continuing survey on mental and physical health during the COVID-19 pandemic” is a nationwide, longitudinal, online survey carried out by the Research Institute of Economy, Trade and Industry, Japan (RIETI), Japan. The current study used this data to analyse time trends and risk factors for exercise habit and obesity in addition to attitudes regarding vaccination [18] and infection avoidance behaviour in Japan [19]. The results will provide additional insight on the health impact of the pandemic and therefore will provide clues for developing effective disaster mitigation plans for future CBRNE disasters.

Materials and methods

The detailed method for data collection is described in our previous reports [18, 19]. In short, nation-wide online questionnaires were conducted five times: October 2020, and January, April, July, and October 2021. The questionnaire was conducted only for a year mainly due to limited finance. The online survey was called “the 2020 Continuing survey on mental and physical health during the COVID-19 pandemic” (hereinafter named the RIETI questionnaire survey), with the NTTCom Online Marketing Solutions Corporation commissioned to conduct and anonymize the survey. The researchers were provided with only de-identified data.

Target population

The participants were Japanese people aged 18–74 years living in Japan who were randomly selected from the database of registered monitors of the NTTCom. The participants were selected so that the demographic composition ratios of sex, age, and distribution of residential prefectures matched the population estimates of the Statistics Bureau of Japan (final estimates, May 2020). The aim was to enrol 20000 participants according to the eligibility of our study fund.

Data collected

The following data were collected

  • Background information: sex, age group, pre-existing conditions, marital status, yearly income, height, weight, and exercise habit before the COVID-19 pandemic
  • Infection status of SARS-CoV-2: past diagnosis, current infection, or no infection
  • Activities to avoid the virus: avoid poorly ventilated places, avoid crowded places, wear a mask, wash hands, disinfect belongings, gargle, change clothes frequently, keep a distance from others, refrain from seeing a doctor, and refrain from going out as much as possible
  • Exercise habit: days of exercise per week
  • Health status: patient health questionnaire 9 (PHQ-9) for depression status [20], GAD-7 for anxiety [21], and subjective health status on a six-point scale
  • Change in economic status compared to the previous questionnaire

Exclusion criteria

As the online survey was written in Japanese, people who could not read Japanese were excluded. After collection, the data were excluded for individuals who provided seemingly inappropriate answers, including non-existent zip codes, extreme outlying values for height and weight, and controversial answers throughout the five questionnaires such as a difference in age of two years or more. The respondents who took a very short time (less than five minutes) or a very long time (ten hours or longer) to answer the survey questions were also excluded.

Definition of changes in the early and late phases

We defined the period of the first and second questionnaire as the ‘early phase’ and that of the fifth questionnaire as the ‘late phase’ of the pandemic. Changes in habits in the early phase were evaluated by comparing the answers in the first and second questionnaires, while changes in the late phase were evaluated by comparing the answers in the first and fifth questionnaires.

Definition of exercise habit, obesity, and overweight

People who answered that they did not exercise (i.e., 0 per week) were categorised as ‘no exercise habit’. Changes in exercise habit were estimated by calculating the difference in exercise days at the time of each questionnaire, compared to that stated in the first questionnaire.

Obesity and overweight were defined as a BMI >30 kg/m2 and >25 kg/m2, respectively. As the proportion of obesity is not high in the Japanese population, the proportion of overweight status was used as an outcome for further analysis. Newly developed overweight status was defined as those who were not overweight at the time of the first questionnaire but became overweight in the following periods.

Statistical analysis

A change in exercise habit during the early phase was calculated by subtracting the exercise days per week in the second questionnaire from the days in the first questionnaire. A change during the late phase was calculated by subtracting the exercise days per week at the time of the fifth questionnaire from the days in the first questionnaire. The difference between exercise days in the first questionnaire and the following questionnaires were analysed using the paired t-test.

The social and psychological impact of the pandemic in Japan has been reported to be different according to sex [22, 23]. Therefore, the statistical analyses were separately conducted by sex. Differences between males and females were compared using the chi-square test.

Factors associated with changes in exercise days per week and risk factors for developing overweight status were analysed using a multiple linear regression model. For the sensitivity analysis, the analysis was conducted using factors in the early and later phases.

The statistical analyses were carried out using Stata/SE 16.0 (StataCorp LLC, College Station, TX, USA). P-values of < 0.05 were considered to be statistically significant.

Ethical consideration

Written consent for participation was obtained online from all individuals who participated in the study. The present study was conducted with the approval of the ethics committee of Hiramatsu Memorial Hospital (No: 20200925).

Results

Of the 19,340 participants, 2,698 were excluded due to providing inappropriate or controversial answers. The remaining 16,642 (8022 males and 8,620 females) were included in the final analysis. The background of the participants grouped by sex is shown in Table 1.

thumbnail
Table 1. Background of the participants.

Differences between males and females were calculated by the chi-squared test for categorical variables and the t-test for numerical variables.

https://doi.org/10.1371/journal.pgph.0001732.t001

According to the National Health and Nutrition Survey in Japan 2019 [24], about 33% of males and 29% of females had exercise habit of ≥ 2 days per week. Our data showed slightly higher percentage (36% in male and 34% in female) answered they had ≥ 2 days per week of exercise habit.

There was a significant difference between sexes in all the variables except for the prevalence of cancer. Female participants were more likely to take any infection avoidance behaviour. Male participants had a higher prevalence of exercise habit than females. During the survey, 5,117 (30.7%) of the participants provided at least one missing data or controversial response in the late phase.

Proportion of missing data in each questionnaire by sex and age category is shown in Table 2. The proportions increase with time and were higher among female participants and participants at younger age (≤30 years old).

thumbnail
Table 2. Dropout rate of participants in the following questionnaires by sex and age group.

https://doi.org/10.1371/journal.pgph.0001732.t002

The comparison of the background of those with missing data and those with complete data are compared in the S1 Table. Younger people, those with lower income levels, and those who had never married were more likely to provide essential data.

Changes in exercise habit

The changes in exercise habits at the time of each questionnaire are shown in Fig 1. The proportion of people who reported less exercise days per week than that at baseline (October 2020) increased gradually with time, while those who reported more exercise days at baseline did not change throughout the study period. There was no apparent difference in this trend between males and females. Of the people who reported that they did not exercise at baseline (4,624), 806 (17.4%) reported they had begun to exercise after a year (at the fifth questionnaire). In contrast, 862 (12.6%) of those who reported exercising at baseline (6,841) stopped exercising over the same period. The standard deviations in both males and females increased slightly with time.

thumbnail
Fig 1. Change in exercise habit (days per week) compared with the first questionnaire (October 2020).

Only those who changed the habit are included. * p-values of a paired-t test comparing exercise days in each phase with those in October 2020.

https://doi.org/10.1371/journal.pgph.0001732.g001

To analyse the factors associated with changes in exercise habit, linear regression was conducted using the change in exercise days as the outcome variable. In the early phase of the pandemic (Table 3, left column), a decreased exercise habit was associated with a high income (> 10 million yen per year, equivalent to about 100,000 US dollars per year) in both sexes (males, -0.25 days [95% confidence interval -0.44, -0.07]; females, -0.32 days, [-0.51, -0.13]). Elderly females were also associated with decreased exercise days. Having a regular exercise habit at baseline was associated with an increased exercise habit in both sexes (males, 1.08 days [0.97, 1.19]; females, 1.28 days [1.17, 1.39]). An increased exercise habit in women was associated positively with PHQ-9 (0.02 (0.01 to 0.04) and negatively with GAD-7 (-0.03 [-0.05, -0.01]), although the size of this correlation was small.

thumbnail
Table 3. Factors in the early phase that associated with a change in exercise habit in the early and late phase.

https://doi.org/10.1371/journal.pgph.0001732.t003

In the later phase (Table 3, right column), the diagnosis of a SARS-CoV-2 infection was associated with significantly fewer exercise days in males (-0.89 [-1.36, -0.43]). In both sexes, a regular exercise habit at baseline remained associated with increased exercise days (males, 0.13 [0.02, 0.25]; females, 0.20 [0.08, 0.31]). Mental and physical status had no significant association with the changes in exercise habit in the later phase.

Change in BMI and proportion of obesity/overweight

Another impact caused by the pandemic might be an increase in body weight. The changes in BMI between October 2020 and October 2021 are plotted in S1 Fig. As some people showed a decrease in BMI, just calculating mean BMI may not accurately reflect overweight status. Therefore, the proportion of obesity/overweight and newly developed overweight status as well as mean BMI at each time period are shown in Table 4.

thumbnail
Table 4. Fluctuations in body mass index (BMI), proportion of obesity/overweight, and proportion of newly-developed obesity/overweight.

For BMI, the values at each time point were compared with those at baseline (October 2020) using the paired t-test.

https://doi.org/10.1371/journal.pgph.0001732.t004

Interestingly, the proportion of obesity appeared to decrease slightly over time, while the proportion of overweight status and mean BMI increased in both sexes. The standard deviation for BMI also increased over time in females. In addition, the proportion of newly developed obesity in males also increased during the first four questionnaires. The increase in BMI and proportion of overweight status was marked in the early phase (mean BMI from 23.22 to 23.41 in males and from 21.13 to 21.20 in females; proportion of overweight status from 22.2% to 26.6% in males and from 9.3% to 10.8% in females). In the later phase, the change became less marked, but remained statistically significant in females.

Risk factors for developing overweight status

As the proportion of obesity was too small to conduct further analysis, factors associated with the development of overweight status were determined by multiple logistic regression. In the early phase (January 2021) of the pandemic, the risk of developing overweight status was significantly higher in middle-aged males (31–70 years old) and elderly females (71–80 years old) (Table 5, left column). Males who were married were more likely to become overweight (odds ratio [OR] 1.61 [1.20, 2.16]), although this change was not observed in married females. On the other hand, females who frequently changed their clothes to prevent a COVID-19 infection (OR 1.68 [1.69, 2.60]) or those with a very bad subjective health condition were more likely to develop overweight status. An increase in income was also associated with the development of overweight status in females (OR 1.54 [1.08, 2.20]), but not in males (OR 0.78 [0.60, 1.01]).

thumbnail
Table 5. Odds ratios for newly developed overweight status in the early and late phases of the pandemic, grouped by sex.

Controlled for pre-existing conditions.

https://doi.org/10.1371/journal.pgph.0001732.t005

In the late phase (October 2021) (Table 5, right column), males in the age group of 41–50 yr constantly showed a higher risk of becoming overweight (OR 2.35 [1.16, 4.73]). Interestingly, males who were diagnosed with a SARS-CoV-2 infection were also more likely to develop overweight status (OR 2.57 [1.18, 5.60]). Avoiding talking at close distances (OR 0.62 [0.41, 0.94]) and keeping distance from others (OR 0.64 [0.44, 0.94]) were also associated significantly with a lower risk of developing overweight status in males. In females, avoiding poorly ventilated place was associated with a lower risk of becoming overweight (OR 0.34 [0.15, 0.78]).

Long-term impact of the conditions in the early phase of the pandemic on the onset of overweight status

Assuming that overweight status in the late phase (October 2021) was affected by factors in the early phase (October 2020), further analysis was carried out on the association between being overweight in the late phase and lifestyle factors in the early phase as a sensitivity analysis (S2 Table).

In males, infection with the SARS-CoV-2 in the early phase correlated significantly with the development of overweight status in the late phase (OR 3.01 [1.27, 7.13]), while those who experienced a decrease in income showed a lower risk (OR 0.73 [0.54, 0.97]). On the other hand, females whose income decreased in the early phase were more likely to become overweight in the late phase (OR 1.75 [1.18, 2.61]). Although not statistically significant, there was a trend that females who had a worse subjective health score in the early phase were more likely to have a higher risk of prolonged overweight status. Exercise habit was not associated with the risk of developing overweight status in any of the analyses.

Discussion

This study included novel, nationwide, longitudinal research on exercise habits and overweight risks in Japan during the COVID-19 pandemic. The study showed a trend of a decrease in exercise habit and increase in overweight status among a group of the population. This suggested the COVID-19 pandemic had a strong negative impact associated with a restriction of social activities. However, our research also showed that the proportion of obesity status actually decreased during the pandemic period, suggesting the impact was heterogeneous. This finding is consistent with those of previous studies [16, 17]. This may mean that targeted intervention, but not general intervention, may be required to prevent the impact of the disaster on obesity-related health outcomes. In addition, our research showed that the factors that associate with immobility and overweight status were different. Therefore intervention to prevent these two health problems might be considered independently.

Previous reports suggest that prolonged evacuation may increase the risk of chronic conditions including obesity, presumably due to increased mental stress and poor access to healthcare services [25, 26]. Our research suggests that depression and anxiety had limited impact on the health problems, suggesting there might be other cause of health deterioration during the pandemic.

Older females as a vulnerable population in the COVID-19 pandemic

Importantly, elderly females appeared to be at higher risk for both immobility and overweight status in the early phase of the pandemic. These risks also correlated with worse subjective health in females. These results suggest that this trend might be due partly to fear of COVID-19, which has been reported to be higher in females than in males [27]. In addition, the elderly population were more vulnerable to biased reports by mass media [28] and the current infodemic. Therefore, it is possible that the infodemic and other biased information exacerbated the fear elderly females had of COVID-19. This fear may be decreased by fact-checking information [27]. Indeed, in other disasters such as the Fukushima nuclear accident, public communication through the Fukushima health management surveys was effective for reducing anxiety among the residents [29]. Therefore, in future disasters, appropriate intervention in the acute phase may need to include providing the population with scientific-based information as well as information about self-management and psychological first aid targeting the elderly population.

Bipolarization of the exercise habit

Our study also showed that people who already had an exercise habit were more likely to increase their exercise. Therefore, improving this pre-condition by installing exercise habits before the pandemic in high-risk groups might be another strategy for disaster preparation.

Interestingly, our study showed that a high income (>10 million yen per year) was associated significantly with decreased exercise habits. This may mean that people engaged in administrative work or work with greater responsibility were overwhelmed by their duty during the pandemic, leading to a decrease in their exercise habit. This may also explain why males who experienced decreased income were more likely to increase their exercise habit. In other words, workload and exercise times were a trade-off in males.

On the other hand, females who experienced decreased income were more likely to also decrease their exercise, possibly because those who left their jobs did so due to increased housework [30] or those who started part-time jobs got less salary with longer worktime. Another possible reason is that female whose income decreased were more likely to become depressive. Further research is required to elucidate the reasons why exercise times in females were not a trade-off for a reduction in income.

Concern about the impact of overweight status on long-term health conditions

In addition to immobility, obesity is one of the major concerns after a huge disaster, especially among evacuees [6, 31]. Lock-down and keeping social distance may have caused the similar effects to evacuation on the public. Indeed, the present research study revealed that about 6% of non-obese males and 3% of non-obese females became overweight during the period of the pandemic. As there was a group of people whose BMI decreased, the net increase in the proportion of overweight was about 4% in males and 1% in females. Above all, middle-aged males were at higher risk of becoming overweight in both the early and late phase of the pandemic. Considering that an increased BMI in middle-age causes loss of life expectancy by 5–13 years [32], this indirect impact of the pandemic should not be ignored. Intervention in the high-risk population is therefore essential to prevent the impact of a disaster on overweight status.

Risk of overweight among males.

For males, the diagnosis of COVID-19 was associated significantly with the development of overweight status. This association can be interpreted in several ways. One scenario is that COVID-19 infection may have led to overweight status. As the diagnosis also correlated with a decrease in exercise habits, this increase in overweight status may have been due to a lack of exercise. However, there was no significant difference in exercise days between those who were diagnosed with a SARS-CoV-2 infection and those who were not (Average days of exercise per week in those who were infected and those who were not were 2.30 days and 2.00 days in the early phase (p = 0.16 by t-test) and 2.43 days and 2.13 days in the late phase(p = 0.13)). Another possible reason is that post-COVID syndromes such as post-traumatic disorders, depression, and chronic fatigue may lead to inactivity, thereby increasing the risk of becoming overweight [14]. Some experts consider rehabilitation in the recovery phase of COVID-19 should include not only respiratory and cardiovascular rehabilitation but also muscle training and psychological support [33]. Such interventions may need to be applied for those whose symptoms were less severe. However, to date there are no guidelines regarding interventions for patients who were not hospitalised. An effort to reduce the indirect and prolonged health impacts caused by the SARS-CoV-2 pandemic may need to target this population.

Another scenario is that the development of overweight status has led to increase in the risk of symptomatic SARS-CoV-2 infection. As overweight status and obesity is a risk factor of developing severer symptoms, people in overweight status may have been at higher risks of being diagnosed as SARS-CoV-2 infection. To clarify the causal relationships, further research is required such as long-term follow-up of the infected people.

Risk of overweight status among females.

Our research also revealed elderly females were at higher risk of developing overweight status in the early phase compared with the other age groups. A previous study reported homemakers were more likely to gain body weight [15], which was consistent with our findings. The factors causing overweight status in elderly people include a decrease in time spent for outings due to the geographically isolated conditions of temporary housing [34] and prolonged post-traumatic stress disorders (PTSD) [35]. During the COVID-19 pandemic, people stayed at home for a longer time, which might have caused similar conditions to long-term evacuation, such as less outings and higher mental stress. Another possible reason is change in eating habit. If people try to go out as seldom as possible, they may buy more preserved food and less fresh fruits and vegetables, which may affect body weight. However, older age confounds with a variety of socio-economic and mental status. For example, elderly people living on pensions or those with dementia may be more likely to be at poorer mental status. Further surveys on the impact of such factors on health status are required.

Overweight status in elderly women may have a marked health impact on society because being overweight in this population group is a significant risk factor for immobility and frailty, which may lead to bone fracture or a bed-ridden state [36, 37]. Therefore, immediate intervention might have been needed to target this group of people in the early phase of the pandemic. For females, the development of overweight status was associated with seemingly excessive reactions against SARS-CoV-2, such as changing clothes frequently. As bad subjective health status was associated with the risk of developing overweight status, anxiety might also have been a risk factor.

To prevent lifestyle diseases, interventions by health professionals are not sufficient. In addition, the health system is often severely compromised in the affected areas due to overwhelming demand, evacuation of healthcare workers [38], diversion of resources, and closure of health facilities [39]. Therefore, self-management such as regular exercise and weight control is a key to disaster mitigation.

Limitations

This study had several limitations. First, the study relied solely on participant responses and therefore we could not avoid false answers even after excluding those that were apparently controversial. In addition, several important questions that may affect body weight, such as eating habits, specific cause of mental stresses such as increase in housework, are not included in the questionnaire mainly due to lack of finance. The number of questionnaires was also limited to five times from the same reason. Second, although the participants were matched to the national demographic background, dropout rate was different between sexes and age groups. There also remains selection bias of the participants. For example, individuals who could not read Japanese and those who could not use the internet were excluded. In addition, individuals with a history of infection could have more actively sought to participate in our study because of their increased interest in the significance and content of this online survey, causing an upward bias in participation of this type of subject. Indeed, our data showed the proportion of those who had exercise habit of ≥ 2 days per week was higher than the that of The National Health and Nutrition Survey in Japan 2019, which may reflect these selection bias. Third, about one-third of the participants missed some of the data during the survey period. As there were some significant differences between those with missing data and those with complete data (S1 Table), these numbers may have affected the generalizability of our results. Forth, causal relationships cannot be proved by this survey. For example, it is not clear whether newly developed overweight status increased the risk of COVID-19 infection or vice-versa. By using the factors in the early phase as explanatory variables and newly developed overweight status as an outcome variable, this limitation could be partially overcome. Fifth, there are many potential confounders that were not asked in the questionnaire. For example, decrease in exercise day does not always mean decline in activity -before the pandemic the average commuting hours of Japanese businesspeople was about 50 minutes, which could be substitute for exercise time [40]. Therefore, it is possible that increase in working at home may have decreased overall activities even when the exercise day increased. Finally, the survey did not include that of genetic factors, which may account for 40 to 50% of variability in body weight status [41]. In addition, there might be difference in genetic backgrounds between Japan and other countries, which may limit the generalizability of our findings. To elucidate more detailed causal relationships, further research such as prospective study of physical performance tests and surveys including blood testing is required. However, despite these limitations, our research provided sufficient generalizability compared to other studies because of the broadness of the participants’ background.

Conclusion

This study analysed the impact of the COVID-19 pandemic on exercise habit and the development of overweight status in the Japanese population. Risk factors for these conditions were shown to be different between the sexes. Our results suggest that early intervention for elderly women such as provision of information and mental care, and long-term intervention including physical and mental rehabilitation for people who were infected might have been needed during the pandemic. As most CBRNE disasters cause similar social transformation, intervention to prevent immobility and obesity among the high-risk population should be addressed in future disaster preparation/mitigation plans so that we can prevent distant health impacts associated with a disaster. Further research is still needed to clarify the detailed factors that affect exercise habits and overweight status, such as eating habits, change in the volume of housework, other causes of mental stress and genetic factors that may impact body weight status.

Supporting information

S1 Table. Background of the participants who dropped out during the surveillance period.

https://doi.org/10.1371/journal.pgph.0001732.s001

(DOCX)

S2 Table. Impact of the factors on prolonged overweight in the early phase of the pandemic.

https://doi.org/10.1371/journal.pgph.0001732.s002

(DOCX)

S1 Fig. Plot of the body mass index of each participant in October 2020 (horizontal) and October 2021 (vertical).

https://doi.org/10.1371/journal.pgph.0001732.s003

(TIF)

Acknowledgments

We would like to thank Dr Kenzo Denda, Hiramatsu Memorial Hospital for his support in ethical considerations of the study.

References

  1. 1. Nomura S, Blangiardo M, Tsubokura M, Ozaki A, Morita T, Hodgson S. Postnuclear disaster evacuation and chronic health in adults in Fukushima, Japan: a long-term retrospective analysis. BMJ Open. 2016;6(2):e010080-e. pmid:26846896.
  2. 2. Satoh H, Ohira T, Hosoya M, Sakai A, Watanabe T, Ohtsuru A, et al. Evacuation after the Fukushima Daiichi Nuclear Power Plant Accident Is a Cause of Diabetes: Results from the Fukushima Health Management Survey. J Diabetes Res. 2015;2015:627390. Epub 2015/06/25. pmid:26106625; PubMed Central PMCID: PMC4461763.
  3. 3. Murakami M, Tsubokura M, Ono K, Nomura S, Oikawa T. Additional risk of diabetes exceeds the increased risk of cancer caused by radiation exposure after the Fukushima disaster. PloS one. 2017;12(9):e0185259-e. pmid:28957385.
  4. 4. Ishii T, Ochi S, Tsubokura M, Kato S, Tetsuda T, Kato J, et al. Physical performance deterioration of temporary housing residents after the Great East Japan Earthquake. Prev Med Rep. 2015;2:916–9. pmid:26844168.
  5. 5. Yamamura E. Impact of the Fukushima nuclear accident on obesity of children in Japan (2008–2014). Econ Hum Biol. 2016;21:110–21. Epub 2016/02/06. pmid:26849534.
  6. 6. Kawasaki Y, Nakano H, Hosoya M, Yasumura S, Ohira T, Satoh H, et al. Influence of post-disaster evacuation on childhood obesity and hyperlipidemia. Pediatr Int. 2020;62(6):669–76. Epub 2020/01/22. pmid:31961051.
  7. 7. Tokunaga A, Yoshida K, Orita M, Urata H, Itagaki S, Mashiko H, et al. The mental health status of children who have been evacuated or migrated from rural areas in Fukushima prefecture after the Fukushima daiichi nuclear power station accident:results from the Fukushima health management survey. Fukushima J Med Sci. 2021;67(1):8–16. Epub 2021/02/16. pmid:33583861; PubMed Central PMCID: PMC8075557.
  8. 8. WHO Coronavirus (COVID-19) Dashboard: World Health Organization; 2022 [updated 1 May, 2022; cited 2022 1 May]. Available from: https://covid19.who.int/.
  9. 9. Di Renzo L, Gualtieri P, Pivari F, Soldati L, Attinà A, Cinelli G, et al. Eating habits and lifestyle changes during COVID-19 lockdown: an Italian survey. Journal of translational medicine. 2020;18(1):229. Epub 2020/06/10. pmid:32513197; PubMed Central PMCID: PMC7278251.
  10. 10. Cheikh Ismail L, Osaili TM, Mohamad MN, Al Marzouqi A, Jarrar AH, Abu Jamous DO, et al. Eating Habits and Lifestyle during COVID-19 Lockdown in the United Arab Emirates: A Cross-Sectional Study. Nutrients. 2020;12(11). Epub 2020/11/04. pmid:33137947; PubMed Central PMCID: PMC7693610.
  11. 11. van Bakel BMA, Bakker EA, de Vries F, Thijssen DHJ, Eijsvogels TMH. Impact of COVID-19 lockdown on physical activity and sedentary behaviour in Dutch cardiovascular disease patients. Neth Heart J. 2021;29(5):273–9. Epub 02/25. pmid:33630274.
  12. 12. Yang S, Guo B, Ao L, Yang C, Zhang L, Zhou J, et al. Obesity and activity patterns before and during COVID-19 lockdown among youths in China. Clinical obesity. 2020;10(6):e12416. Epub 2020/10/04. pmid:33009706; PubMed Central PMCID: PMC7646045.
  13. 13. Robinson E, Boyland E, Chisholm A, Harrold J, Maloney NG, Marty L, et al. Obesity, eating behavior and physical activity during COVID-19 lockdown: A study of UK adults. Appetite. 2021;156:104853. Epub 2020/10/11. pmid:33038479; PubMed Central PMCID: PMC7540284.
  14. 14. Stefan N, Birkenfeld AL, Schulze MB. Global pandemics interconnected—obesity, impaired metabolic health and COVID-19. Nat Rev Endocrinol. 2021;17(3):135–49. Epub 2021/01/23. pmid:33479538.
  15. 15. Caretto A, Pintus S, Petroni ML, Osella AR, Bonfiglio C, Morabito S, et al. Determinants of weight, psychological status, food contemplation and lifestyle changes in patients with obesity during the COVID-19 lockdown: a nationwide survey using multiple correspondence analysis. Int J Obes (Lond). 2022. Epub 2022/03/21. pmid:35306529; PubMed Central PMCID: PMC8933751.
  16. 16. Cancello R, Soranna D, Zambra G, Zambon A, Invitti C. Determinants of the Lifestyle Changes during COVID-19 Pandemic in the Residents of Northern Italy. International journal of environmental research and public health. 2020;17(17). Epub 2020/09/03. pmid:32872336; PubMed Central PMCID: PMC7504331.
  17. 17. Górnicka M, Drywień ME, Zielinska MA, Hamułka J. Dietary and Lifestyle Changes During COVID-19 and the Subsequent Lockdowns among Polish Adults: A Cross-Sectional Online Survey PLifeCOVID-19 Study. Nutrients. 2020;12(8). Epub 2020/08/07. pmid:32756458; PubMed Central PMCID: PMC7468840.
  18. 18. Sekizawa Y, Hashimoto S, Denda K, Ochi S, So M. Association between COVID-19 vaccine hesitancy and generalized trust, depression, generalized anxiety, and fear of COVID-19. BMC public health. 2022;22(1):126-. pmid:35042506.
  19. 19. Ochi S, So M, Hashimoto S, Denda K, Sekizawa Y. Behavioral Factors Associated with COVID-19 Risk: A Cross-Sectional Survey in Japan. International journal of environmental research and public health. 2021;18(22):12184. pmid:34831940.
  20. 20. Kroenke K, Spitzer RL, Williams JB. The PHQ-9: validity of a brief depression severity measure. J Gen Intern Med. 2001;16(9):606–13. pmid:11556941; PubMed Central PMCID: PMC1495268.
  21. 21. Spitzer RL, Kroenke K, Williams JB, Lowe B. A brief measure for assessing generalized anxiety disorder: the GAD-7. Arch Intern Med. 2006;166(10):1092–7. pmid:16717171.
  22. 22. Horita N, Moriguchi S. Trends in Suicide in Japan Following the 2019 Coronavirus Pandemic. JAMA Netw Open. 2022;5(3):e224739-e. pmid:35348713.
  23. 23. Zhou Y. How Women Bear the Brunt of COVID-19’s Damage on Work. Japan Labor. 2021;5(28):7.
  24. 24. MHLW. The National Health and Nutrition Survey in Japan 2019: The Japan Ministry of Health, Labour and Welfare; 2019 [cited 23 1 Jun]. Available from: https://www.mhlw.go.jp/stf/newpage_14156.html.
  25. 25. Kadojic D, Demarin V, Kadojic M, Mihaljevic I, Barac B. Influence of prolonged stress on risk factors for cerebrovascular disease. Coll Antropol. 1999;23(1):213–9. Epub 1999/07/14. pmid:10402725.
  26. 26. Ngaruiya C, Bernstein R, Leff R, Wallace L, Agrawal P, Selvam A, et al. Systematic review on chronic non-communicable disease in disaster settings. BMC public health. 2022;22(1):1234. Epub 2022/06/22. pmid:35729507; PubMed Central PMCID: PMC9210736.
  27. 27. Lai AY, Sit SM, Wu SY, Wang MP, Wong BY, Ho SY, et al. Associations of Delay in Doctor Consultation With COVID-19 Related Fear, Attention to Information, and Fact-Checking. Frontiers in public health. 2021;9:797814. Epub 2021/12/31. pmid:34966717; PubMed Central PMCID: PMC8710678.
  28. 28. Bapaye JA, Bapaye HA. Demographic Factors Influencing the Impact of Coronavirus-Related Misinformation on WhatsApp: Cross-sectional Questionnaire Study. JMIR Public Health Surveill. 2021;7(1):e19858. Epub 30.1.2021. pmid:33444152.
  29. 29. Murakami M, Sato A, Matsui S, Goto A, Kumagai A, Tsubokura M, et al. Communicating With Residents About Risks Following the Fukushima Nuclear Accident. Asia Pacific Journal of Public Health. 2017;29(2_suppl):74S–89S. pmid:28330403
  30. 30. Sakuragi T, Tanaka R, Tsuji M, Tateishi S, Hino A, Ogami A, et al. Gender differences in housework and childcare among Japanese workers during the COVID-19 pandemic. J Occup Health. 2022;64(1):e12339. Epub 2022/07/06. pmid:35781910.
  31. 31. Uemura MY, Ohira T, Yasumura S, Sakai A, Takahashi A, Hosoya M, et al. Association between lifestyle habits and the prevalence of abdominal obesity after the Great East Japan Earthquake: The Fukushima Health Management Survey. J Epidemiol. 2021. Epub 2021/04/06. pmid:33814507.
  32. 32. Peeters A, Barendregt JJ, Willekens F, Mackenbach JP, Al Mamun A, Bonneux L. Obesity in adulthood and its consequences for life expectancy: a life-table analysis. Ann Intern Med. 2003;138(1):24–32. Epub 2003/01/07. pmid:12513041.
  33. 33. Barker-Davies RM, O’Sullivan O, Senaratne KPP, Baker P, Cranley M, Dharm-Datta S, et al. The Stanford Hall consensus statement for post-COVID-19 rehabilitation. Br J Sports Med. 2020;54(16):949–59. Epub 2020/06/02. pmid:32475821; PubMed Central PMCID: PMC7418628.
  34. 34. Hikichi H, Aida J, Kondo K, Tsuboya T, Kawachi I. Residential relocation and obesity after a natural disaster: A natural experiment from the 2011 Japan Earthquake and Tsunami. Sci Rep. 2019;9(1):374. Epub 2019/01/25. pmid:30675013; PubMed Central PMCID: PMC6344590.
  35. 35. Takemoto E, Van Oss KR, Chamany S, Brite J, Brackbill R. Post-traumatic stress disorder and the association with overweight, obesity, and weight change among individuals exposed to the World Trade Center disaster, 2003–2016. Psychological Medicine. 2021;51(15):2647–56. Epub 2020/05/07. pmid:32375911
  36. 36. Schaap LA, Koster A, Visser M. Adiposity, muscle mass, and muscle strength in relation to functional decline in older persons. Epidemiol Rev. 2013;35:51–65. Epub 2012/12/12. pmid:23221972.
  37. 37. Strandberg TE, Sirola J, Pitkala KH, Tilvis RS, Strandberg AY, Stenholm S. Association of midlife obesity and cardiovascular risk with old age frailty: a 26-year follow-up of initially healthy men. Int J Obes (Lond). 2012;36(9):1153–7. Epub 2012/05/23. pmid:22614054.
  38. 38. Ochi S, Tsubokura M, Kato S, Iwamoto S, Ogata S, Morita T, et al. Hospital Staff Shortage after the 2011 Triple Disaster in Fukushima, Japan-An Earthquake, Tsunamis, and Nuclear Power Plant Accident: A Case of the Soso District. PLoS One. 2016;11(10):e0164952. pmid:27788170; PubMed Central PMCID: PMC5082811.
  39. 39. Ochi S, Leppold C, Kato S. Impacts of the 2011 Fukushima nuclear disaster on healthcare facilities: A systematic literature review. International Journal of Disaster Risk Reduction. 2020;42:101350. https://doi.org/10.1016/j.ijdrr.2019.101350.
  40. 40. Morikawa M. Long Commuting Time and the Benefits of Telecommuting.: Research Institute of Economy, Trade, and Industry (RIETI); 2018 [cited 2023 16 April]. Available from: https://www.rieti.go.jp/jp/publications/dp/18e025.pdf.
  41. 41. Bouchard C. Genetics of Obesity: What We Have Learned Over Decades of Research. Obesity (Silver Spring, Md). 2021;29(5):802–20. Epub 2021/04/27. pmid:33899337.