Abstract
Lifestyle factors, including smoking habit, diet, and physical activity, affect the prognosis of various diseases. We elucidated the effect of lifestyle factors and health status on deaths from respiratory diseases in the general Japanese population using data from a community health examination database. Data of the nationwide screening program of the Specific Health Check-up and Guidance System (Tokutei-Kenshin), targeting the general population in Japan, from 2008 to 2010 were analyzed. The underlying causes of death were coded according to the International Classification of Diseases (ICD)-10. The hazard ratios of the incidence of mortality associated with respiratory disease were estimated using the Cox regression model. This study included 664,926 participants aged 40–74 years, who were followed up for 7 years. There were 8051 deaths, including 1263 (15.69%) deaths from respiratory diseases. The independent risk factors of mortality associated with respiratory diseases were male sex, older age, low body mass index, no exercise habit, slow walking speed, no drinking habit, smoking history, history of cerebrovascular diseases, high hemoglobin A1c and uric acid levels, low low-density lipoprotein cholesterol level, and proteinuria. Aging and decline of physical activity are significant risk factors for mortality associated with respiratory diseases, regardless of the smoking status.
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Introduction
Japanese people are known to have the longest average life expectancy worldwide1. As a result, the number of elderly people in Japan is increasing, and the etiology of disease is changing. Currently, approximately 30% of the Japanese population reportedly dies from malignant neoplasm, followed by heart disease, senility, cerebrovascular disease, and pneumonia2. Regarding the causes of death by organ, approximately 20% of deaths from malignant neoplasm are due to lung cancer, which is the most common cause of malignant neoplasm-related deaths. Deaths due to pneumonia and aspiration pneumonia are the fifth and sixth leading causes of deaths in Japan. We previously conducted a follow-up study of > 3000 residents of Takahata town, Yamagata Prefecture, Japan, who had undergone health checkups. The analysis of the causes of death after 7 years revealed that deaths due to respiratory diseases, including lung cancer, were the most common, accounting for approximately 30% of all deaths3. Elderly admitted to hospitals due to a disease condition require high treatment cost and long hospitalization4. Even if the disease causing hospitalization improves as a result of treatment, the patient may not be able to leave the hospital or may require long-term rehabilitation due to the decline in the activity of daily living (ADL). Furthermore, it may also cause a decline in cognitive function5,6,7. In Japan, the concept of “healthy life expectancy” exists. Despite the fact that the life expectancy of both men and women has been extended, approximately 10 years of their lives will require nursing care. Thus, the loss of a healthy life expectancy is a serious problem8.
Lifestyle is well known to influence the onset and prognosis of various diseases. Chronic obstructive pulmonary disease (COPD) is among the lifestyle-related diseases of the respiratory system, with smoking habits playing a major role in its pathogenesis. Physical activity plays a more significant role in the prognosis of patients with COPD than the decline of pulmonary function9. A previous study on individuals who had undergone a physical examination showed that regularly walking reduced the risk of death from pneumonia10,11,12,13,14.
Habitual exercise influences the progression and prognosis of heart disease, diabetes, and dyslipidemia15. However, there have been few reports on the impact of lifestyle on the prognosis of various respiratory diseases in the general population who had undergone health checkups.
Therefore, we aimed to clarify the effects of lifestyle and medical conditions on the health status of the general population using data obtained from the Community Health Examination System.
Results
Profiles of participants
Table 1 shows the demographic profiles of the part included in this study. Among the 664,926 participants, 42.76% were men and the mean age was 62.3 years (39–75 years). Moreover, 31.70% of the studied individuals exercised for ≥ 30 min, and 38.17% regularly walked or engaged in physical activity. Furthermore, 38.26% of the participants reported walking faster as compared to the other participants of the same sex and age. Altogether, 15.56% and 46.50% of the participants had a smoking history and drinking habits, respectively. The history of cerebrovascular disease, cardiovascular disease, chronic renal failure, or anemia was present in 3.49%, 5.40%, 0.77%, and 8.65% of the participants, respectively.
Classification of causes of death
All participants were followed up for 7 years; 8051 of them died. The causes of their deaths are summarized in Table 2. Malignant neoplasm was the most common cause of death, accounting for 4159 deaths (62.78% were men) and more than half of all deaths in both sexes. The second most common cause of death was circulatory system disease with 1616 deaths (64.60% were men), accounting for approximately 20% of all deaths in both sexes. The third and fourth most common causes of death was injury, poisoning, or other external causes (920 deaths, 64.46% were men) and respiratory disease (437, 73.23% were men), respectively. Since deaths from malignant neoplasms include deaths related to respiratory disease, we extracted data of 826 deaths from malignant neoplasms of the bronchus and lungs [71.67% (n = 592) were men]. As a result, the total number of deaths from malignant and non-malignant neoplasms of the respiratory system was 1263 (72.21% [n = 912] were men), accounting for 15.69% of all deaths (17.71% and 12.10% of all deaths in men and women, respectively).
Risk of deaths due to respiratory diseases
The causes of deaths from respiratory diseases, including malignant neoplasms, are shown in Table 3. Of the 1263 deaths, the most common cause was malignant neoplasm (592 were men, 64.91%; 234 were women, 66.67%), followed by respiratory infections caused by viruses and bacteria (151 were men, 16.56%; 51 were women, 14.53%). Interstitial pulmonary disease was the third most common cause, followed by obstructive pulmonary disease.
Table 4 shows the results of the analysis for the risk of death from respiratory disease with or without malignant neoplasm in the respiratory tract. Death from respiratory disease, including malignant neoplasm, was significantly associated with sex, older age, lower body mass index (BMI), increased systolic blood pressure, no walking habit or physical activity, slow walking speed, smoking history, drinking habit, adequate sleep, history of cerebrovascular or cardiovascular disease, receiving treatment for hypertension or diabetes, increased levels of fasting blood glucose, hemoglobin A1c (HbA1c), aspartate aminotransferase (AST), UA, and creatinine (Cre), decreased level of high-density lipoprotein cholesterol (HDL-C), low-density lipoprotein cholesterol (LDL-C), and alanine aminotransferase (ALT), and proteinuria.
Deaths from respiratory disease excluding malignant neoplasms were significantly associated with sex, older age, lower BMI, decreased waist circumference, lower diastolic blood pressure, no weight gain of > 10 kg compared to the weight at 20 years of age, no exercise habit of > 30 min, no walking habit or physical activity, slow walking speed, history of cerebrovascular disease, cardiovascular disease, or chronic renal failure, receiving treatment for hypertension or diabetes, increased fasting blood glucose, HbA1c, AST, UA, and Cre levels, increased estimated glomerular filtration rate (eGFR), lower triglyceride (TG), HDL-C, and LDL-C levels, and proteinuria.
Deaths from malignant neoplasms in the respiratory tract were significantly associated with sex, aging, increased waist circumference, higher systolic blood pressure, slow walking speed, smoking history, drinking habits, adequate sleep, history of cerebrovascular or cardiovascular disease, treatment for hypertension or diabetes, increased fasting blood glucose, HbA1c, TG, AST, hemoglobin, hematocrit, UA, and creatinine levels, lower HDL-C and LDL-C levels, and proteinuria.
The independent risk factors of death from respiratory disease with or without a malignant neoplasm in the respiratory tract was examined through a Cox proportional hazards analysis (Table 5). For deaths from respiratory disease, including malignant neoplasm, the independent risk factors were male sex, older age, lower BMI, no walking habit or physical activity, slow walking speed, smoking history, no drinking habit, history of cerebrovascular disease, increased HbA1c and UA levels, decreased LDL-C level, and proteinuria. For deaths from respiratory disease, excluding malignant neoplasm, we excluded the factor “Waist circumference” from the Cox proportional hazards analysis even though it was significant in the univariate analysis. Because waist circumference was considered to be strongly correlated with BMI. Additionally, we did not include the factor “Habit of walking and/or physical activity” in this analysis. In univariate analyses, “Exercise habit for more than 30 min” and “Habit of walking and/or physical activity” were significant risk factors for death from respiratory disease excluding malignant neoplasm, but as these factors were similar, we included only “Exercise habit for more than 30 min” in the Cox proportional hazards analysis. The independent risk factors were male sex, older age, lower BMI, exercise habit for less than 30 min, slow walking speed, history of cerebrovascular disease, increased HbA1c and UA levels, increased eGFR, decreased LDL-C level, and proteinuria. For deaths from malignant neoplasm in the respiratory tract, the independent risk factors were male sex, older age, slow walking speed, smoking history, increased HbA1c level, and decreased hemoglobin level.
Discussion
In this study, we determined the impact of lifestyle factors and health status on deaths from respiratory diseases in the general Japanese population using data obtained from a community health examination database. We followed > 600,000 individuals for 7 years; of these, > 8000 participants died. The analysis of the causes of deaths showed that respiratory diseases, including malignant neoplasms, accounted for 15.69% of all deaths, next to cardiovascular diseases. The significant risk factors of death from respiratory disease including malignant neoplasm were male sex, older age, lower BMI, no walking habit or physical activity, slow walking speed, history of smoking, no drinking habits, history of cerebrovascular disease, increased HbA1c and UA levels, decreased LDL-C level, and proteinuria. Particularly, in this study, we showed for the first time that exercise habits, such as walking and physical activity, as well as a fast walking speed reduced the risk of mortality from all respiratory diseases.
In previous studies using health checkup data, various backgrounds, underlying diseases, and biomarkers were found to be the risk factors for future mortality. In our previous cohort study involving a general population, male sex, older age, high d-dimer and fibrinogen levels, lower BMI and total cholesterol levels, and history of stroke and gastric ulcer were independent risk factors for respiratory death16. The other analyses showed that impaired pulmonary function was an independent risk factor of death from cardiac and respiratory diseases3. Several studies have reported that physical activity, such as walking, has been shown to reduce the risk of respiratory disease9,10,14,17. A higher frequency of running and walking was reported to reduce the risk of death from respiratory disease, pneumonia, and aspiration pneumonia in a dose-dependent manner14. Furthermore, studies on patients with COPD or lung cancer have reported beneficial effects of exercise or physical activity on the clinical course of the disease9,17. These results are consistent with our findings showing that physical activity is beneficial to the prognosis of respiratory diseases; however, our results also differed, as the previous studies recruited walkers or patients with specific diseases were targeted. In our previous study, our health checkup data showed that daily walking habits reduced the risk of death from pneumonia10. We considered that the present study is valuable, as our health checkup data showed that walking habit and physical activity or fast walking speed can reduce the risk of mortality from all respiratory diseases, including malignant neoplasm, as well as pneumonia in the future. In the present study, malignant neoplasm was the leading cause of death from respiratory disease. The risk factors of death from respiratory disease without and without malignant neoplasms in the respiratory tract were different (Table 5). The risk factors common to both respiratory diseases with and without malignant neoplasms were male sex, older age, fast walking speed, and higher HbA1c level. Some underlying diseases, such as cerebrovascular or chronic renal disease, and some laboratory data, such as LDL-C, UA, and urinary protein were significant risk factors of death from respiratory disease not including those with malignant neoplasms. The risk factors for death from malignant neoplasm in the respiratory tract were fewer than those from respiratory diseases as a whole or from respiratory diseases without malignant neoplasms. Only an increase in HbA1c level, a marker of diabetes mellitus, and a decrease in hemoglobin level were significantly associated with death from malignant neoplasm. Previous reports have shown that the presence of diabetes or anemia is associated with a poor prognosis of lung cancer18,19, consistent with the results of this study. Thus, estimating the risk of death from malignant neoplasm in the respiratory tract differed from that caused by other respiratory diseases.
Our study showed that, in addition to walking habits or physical activity, individuals with faster walking speed as compared to other individuals of same age and sex have decreased risk for mortality from respiratory disease. Another study investigated that the group with a reduced erector spinae muscle area measured by computed tomography showed a worse life prognosis in patients with COPD20. The erector spinae muscle, one of the antigravity muscles, is involved in the maintenance of normal posture. These muscles tend to show atrophy in patients with reduced activity. A previous study on patients with pneumonia reported that the erector spinae of these patients who died or required rehabilitation were significantly smaller than those who discharged7. Furthermore, a study on nontuberculous mycobacteria also reported that patients with reduced erector spinae muscle area had a poorer prognosis21. The serum level of irisin, one of the myokines secreted by the skeletal muscle cells, was associated with physical activity in patients with COPD. A lower serum irisin level was shown in patients with COPD than in controls. Moreover, all participants with a lower physical activity level had lower serum irisin levels22. Decreased muscle mass is associated with decreased physical activity. These results indicate that decreased muscle and muscle strength, as well as lower physical activity are strongly correlated with the prognosis of various respiratory diseases. These findings seem to support the findings of the present study, demonstrating that faster walking speed and walking habit/physical activity can reduce the risk of mortality from respiratory diseases. Pre-existing medical conditions and lifestyle habits that contribute to a decline in ADL are also risk factors, and behavioral changes and interventions that promote exercise may reduce the risk of deaths from respiratory disease.
However, the present study has some limitations. First, the studied patients were from several prefectures, which may lead to a regional bias. Second, the distribution of deaths from respiratory disease is not consistent with the Japanese mortality statistics. Third, answers to questionnaires such as smoking and drinking habits as well as walking habit or physical activity are not as objective as laboratory data. In addition, no previous information on smoking, alcohol consumption or physical activity was obtained, only current conditions were obtained. Despite these limitations, the analysis of very large scale data from > 600,000 participants in Japan can be considered a strong point of this study.
In conclusion, older age and a decline in physical activity are significant risk factors for mortality associated with respiratory diseases, regardless of smoking status. Exercise is important to reduce the risk of mortality from respiratory disease, including malignant neoplasms in the respiratory tract.
Materials and methods
This study (J-SHC study) was conducted on general population who had undergone the nationwide screening program of the Specific Health Check-up and Guidance System (Tokutei-Kenshin), targeting the general population in Japan from 2008 to 2010. The Specific Health Check-up is an annual health checkup for all Japanese citizens aged 40–74, which has been conducted by the National Health Insurance since 2008. Our study was a prospective cohort study conducted in 82 municipalities in 7 prefectures and enrolled 664,926 people (284,320 men and 380,606 women). In this study, participants answered a self-administered questionnaire that covers their background (age, sex, body weight change), their medical histories (stroke, cardiovascular diseases, hypertension, diabetes mellitus, dyslipidemia, proteinuria, hyperuricemia) and their current lifestyles (smoking status, exercise habits, walking habits, walking speed, drinking habits and sleep condition). Individual records of participants were anonymously provided. The underlying causes of death were coded according to International Classification of Diseases (ICD)-10. Baseline information in this study included age, sex, smoking habits (ex- or non-smoker/current smoker), drinking habits (rarely, sometimes, daily) and dose, daily walking or exercise habits, dietary habits, such as frequency and duration of meals, changing of body weights, medication status for hypertension and diabetes, and dyslipidemia, medical history (previously diagnosed heart disease/stroke, chronic kidney disease, or anemia) were obtained by interviewing the examinees. For smoking habits, participants who currently smoke were defined as smokers. Past smokers were not included as smokers. For drinking habits, participants who drunk daily or sometimes were defined as habitual drinkers. For sleep, participants who had adequate sleep were defined as those who answered in the questionnaire that they were getting adequate sleep. Heights, weights, and blood pressure of participants were measured by trained staffs. Their blood pressure was measured using a standard or automatic sphygmomanometer on the right arm after 5 min of rest in a sitting position.
Habits of exercise other than walking were captured based on "yes" or "no" answers to the following question: "Do you exercise for at least 30 min at a time, twice a week, for at least 1 year, to a light sweat? Habits of daily walking were captured based on "yes" or "no" answers to the question, "In your daily life, do you walk or engage in equivalent physical activity for at least 1 h per day?" Their walking abilities were captured based on "yes" or "no" answers to the question, “Do you walk faster than your same sex of approximately the same age?”.
We took blood samples from the participants and obtained laboratory data such as their blood counts, liver function, renal function, fasting blood glucose, glycated hemoglobin A1c (HbA1c), uric acid (UA), and lipid levels. All blood analyses were performed at a local laboratory. Participants with diabetes (fasting blood glucose level of 126 or higher, glycated hemoglobin A1c level of 6.5% or higher, or use of medication for diabetes) and/or hypertension (systolic blood pressure of 140 mmHg or higher, diastolic blood pressure of 90 mmHg or higher, or use of medication for hypertension) were determined through a medical interview and objective data.
This study was conducted in accordance with the Declaration of Helsinki guidelines. This study was approved by the Ethics Committee of Yamagata University (Approval No. 2008-103). All data were anonymized before analysis; therefore, the ethics committee of Yamagata University waived the need for informed consent from study participants. As a statistical analysis of this study, we estimated hazard ratios for mortality associated with respiratory disease using a Cox regression model. Significance was inferred for p values of < 0.05. Statistical analyses were performed using JMP version 11.0 software (SAS Institute, Cary, NC, USA).
Data availability
The dataset used in this study is not publicly available due to a restriction by agreement among the research group members.
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Acknowledgements
This study was supported by a Health and Labour Sciences Research Grant for “Design of the comprehensive health care system for chronic kidney disease (CKD) based on the individual risk assessment by Specific Health Checkup” from the Ministry of Health, Labour and Welfare of Japan and a Grant-in-Aid for “Research on Advanced Chronic Kidney Disease (REACH-J), Practical Research Project for Renal Disease” from Japan Agency for Medical Research and Development (AMED). The authors would like to thank Enago (www.enago.jp) for English language review.
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H.M., S.I., T.K., M.W.: conception and design. K.S., M.S., A.I., Data analysis. S.F., K.I., T.M., Y.S., M.K., I.N., K.Y., K.T., M.K., K.A., T.W.: conception and design, acquisition of data. All authors: analysis and interpretation of data, drafting the article, critical revision, and approval of the final manuscript.
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Murano, H., Inoue, S., Sato, K. et al. The effect of lifestyle on the mortality associated with respiratory diseases in the general population. Sci Rep 13, 8272 (2023). https://doi.org/10.1038/s41598-023-34929-8
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DOI: https://doi.org/10.1038/s41598-023-34929-8
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