Jeong, Joo, Hahn, Kim, and Kim: Gender-Specific Association between Alcohol Consumption and Stress Perception, Depressed Mood, and Suicidal Ideation: The 2010–2015 KNHANES

Abstract

Objective

Alcohol drinking can cause various psychiatric and medical diseases. Although women generally consume less alcohol than men, they may be at a greater risk for alcohol-related psychological distress. The aim of the current study is to evaluate whether the association between alcohol consumption and psychological distress, including stress, depressed mood, and suicidal ideation and the risks of psychological distress differ based on gender.

Methods

The cross-sectional study included 31,657 participants (17,915 women and 13,742 men) from the 2010–2013 and 2015 Korea National Health and Nutrition Examination Survey. Alcohol drinking and Alcohol Use Disorders Identification Test (AUDIT) levels were assessed for evaluating the amount of alcohol intake and alcohol-related problems. Self-perception of stress, depressed mood, and suicidal ideation were assessed for evaluating psychological distress. Odds ratio and 95% confidence intervals for psychological distress were calculated using multiple logistic regression models.

Results

The risks of psychological distress were not significantly associated with drinking level in both sexes. However, the risks of psychological distress were associated with an increase in AUDIT levels, and there were gender differences in the psychological consequences of alcohol-related problems. The association was more drastic in women, and women showed a significant association even though the severity of drinking problem was low with the exception of stress perception.

Conclusion

The risks of psychological distress were associated with the severity of alcohol-related problems and women were more likely to be susceptible. Therefore, it is recommended that women even at low-risk for problematic drinking should be screened for psychological distress.

INTRODUCTION

Alcohol is consumed worldwide, and drinking alcohol is a common part of many cultures. The World Health Organization (WHO) 2014 global status report on alcohol and health revealed that individuals above the age of 15 drink 6.2 liters of pure alcohol per year on average, which translates into 13.5 grams of pure alcohol per day [1]. In South Korea, the rate of current drinkers has been steadily increasing from 72.6% in 2005 to 75.3% in 2016 among men and from 36.9% in 2005 to 48.9% in 2016 among women [2]. In particular, the rate of high-risk drinking (more than 5 drinks for women and more than 7 drinks for men on single drinking occasions and drinking more than twice a week) has risen twice as much in women, from 3.4% in 2005 to 6.3% in 2016 [2].
Alcohol consumption is associated with not only medical diseases, but also mental health [1]. The data from the National Epidemiologic Survey on Alcohol and Related Conditions on alcohol consumption and medical conditions reveal that approximately 25% to 30% of alcohol users have health problems, independent of the quantity consumed [3].
In addition, alcohol is a psychotropic central nervous system (CNS) depressant that interferes with the brain’s communication pathways implicated in psychological symptoms [4]. Previous studies have indicated that increased exposure to alcohol increases risk of depression [5,6] and alcohol can serve as a stressor itself [7]. Moreover, alcohol drinking acts as an important risk factor for attempted or completed suicide, even among individuals who are not alcoholics [8].
Alcohol-related harm may be determined by the volume of alcohol consumed, but is also influenced by the pattern of drinking or the quality of alcohol consumed [9,10]. Previous studies have revealed that irregular heavy drinking plays a crucial role in determining the outcome in the case of cardiovascular disorders [3].
Furthermore, previous studies have showed gender differences in the effects of drinking alcohol and alcohol-related problems [11-14]. Several studies have indicated that females experience an earlier onset of adverse somatic consequences of alcohol use (“telescoping effect”). The telescoping effect indicated that women are more vulnerable to alcohol consumption [15]. Women also appear to be more vulnerable to the neurotoxic effects of alcohol than men although women generally consume less alcohol than men [11]. Similarly, there are some differences in the influence on psychological distress between males and females [12]. Compared with men, alcohol-dependent women more often have comorbid mood and anxiety disorders and increased intensity of depressive symptoms [13]. Women who are alcoholics are known to have a five-fold higher suicide rate than those without alcoholism, which is higher than the rate in men with alcoholism [13].
However, the majority of clinical and experimental approaches about the effects of alcohol and its consequences have been focused on male participants, and comparative studies of men and women have mainly focused on the physical effect of alcohol and patients with alcohol use disorders (AUD) rather than the general population.
Therefore, the present study assesses how the association between alcohol consumption and psychological distress differs across gender in a large sample of a Korea population using standard and nationally representative data from the Korea National Health and Nutrition Examination Survey (KNHANES). Based on previous findings, we hypothesized the following: 1) psychological distress is more likely to occur when there is more alcohol consumption and problematic drinking; and 2) in women, the influence of alcohol consumption and problematic drinking on psychological distress is more severe than in men.

METHODS

Data source and study sample

This study was based on data obtained from the fifth and sixth KNHANES conducted by the Korea Centers for Disease Control and Prevention in 2010–2012 (5th KNHANES) and 2013–2015 (6th KNHANES), respectively. We used the data from 2013 and 2015 except 2014 from the 6th KNHANES because some of the items in the alcohol use disorders identification test (AUDIT) were not investigated in 2014.
The KNHANES is a nationwide population-based survey of the health and nutritional status of Korean people. Annually approximately 8,000–10,000 individuals from about 4,000 households are selected to represent noninstitutionalized Koreans using a stratified and multi-stage probability sampling design with a rolling survey-sampling model. The sampling frames were based on the 2009 resident registration population and the 2008 data of the apartment market for the 5th KNHANES and 2010 population and housing consensus for the 6th KNHANES. The survey was composed of three parts: a health interview, a health examination, and a nutrition survey. Trained interviewers and medical technicians conducted interviews using a structured questionnaire. Physical examination, blood sampling, and urine sampling were performed at a mobile examination center. We used only health-related data, and all items of health-related data were obtained using face-to-face interviews.
The response rates were 80.8% (n=25,534) in the 5th and 78.3% (n=22,948) in the 6th KNHANES. Data from a total of 31,657 participants (17,915 women and 13,742 men) who were 19 years of age or older were analyzed for this study (Figure 1).

Sociodemographic and health-related data

Sex, age, years of education, marital status, employment status, household income, smoking status, physical activity status, sleep duration, and presence of medical or psychiatric conditions were used.
The years of education were categorized as ≤6 years (elementary), 7–9 years (middle school), 10–12 years (high school), and ≥13 years (college). Marital status was classified as single, married, or others (divorced, separated, or widowed). Employment status was divided into working and not working. Household income was categorized according to quartiles of total income for each member in the household. Smoking status was defined as current smoker, ex-smoker, or never smoker. Regular exercise was defined as physical activity performed for a minimum of 20 minutes thrice a week. All the participants were asked to assess sleep duration: “How long do you usually sleep every night?” The presence of medical or psychiatric conditions was diagnosed by a doctor, which was dichotomized into present (at least one) and none (Table 1). In women, the menstruation condition was also assessed whether they were menstruating or were amenorrheic due to pregnancy, lactation, or menopause.

Measurement of alcohol-related variables

Alcohol drinking and AUDIT levels were assessed for evaluating the participants’ amount of alcohol intake and alcohol-related problems.
To assess the drinking level, the amount of pure alcohol consumed (in grams per day) was calculated using the average number of alcoholic beverages consumed and the frequency of alcohol consumption. Additionally, the participants were classified into three groups according to the amount of alcohol consumption per day: non-drinker (<1 g/day), mild to moderate drinker (1–30 g/day), and a heavy drinker (>30 g/day) [16].
In addition, participants were also divided into four groups depending on the AUDIT scores: 0–7, 8–15, 16–19, ≥20. AUDIT is a widely used 10-item screening instrument developed by the WHO for assessing AUD. This test comprehensively evaluates the multidimensional aspects of alcohol consumption over the last year such as risky or harmful drinking pattern including alcohol dependence and problems related to alcohol consumption, not limited to the volume and frequency of alcohol intake [17]. The total scores range from 0 to 40, with the higher scores indicating a greater tendency towards problematic drinking or AUD and the need for an intensive intervention. According to WHO guidelines for AUDIT use, the scores of 0–7 are classified as Zone 1 (low-risk drinking, intervention includes alcohol education), 8–15 as Zone 2 (hazardous drinking, intervention with simple advice), 16–19 as Zone 3 (harmful drinking, with simple advice plus brief counseling and continued monitoring), and more than 20 as Zone 4 (possible alcohol dependence, with referral to a specialist setting for diagnostic evaluation and treatment) [18,19]. High-risk drinking was defined as drinking >60 g pure alcohol per drinking day for men and >40 g per drinking day for women for two or more times a week [20].

Measurement of psychological distress

Stress perception, depressed mood, and suicidal ideation were assessed for evaluating the participants’ psychological distress.
Stress perception was assessed using the following question: “How stressed are you on a daily basis?” “Extremely stressed” or “quite stressed” responses were classified as stress perception, and “a little bit stressed” and “hardly stressed” were classified as no stress perception.
To assess depressed mood, participants answered “yes” or “no” in response to whether they had experienced a depressed mood for two or more continuous weeks during the previous year. “During the past year, have you felt feelings of sadness or hopelessness that persisted for at least two weeks and that disrupted your social life?” This question is included in the WHO Composite International Diagnostic Interview-Short Form, which was validated as a cost-effective screening method for a general public survey [21]. A “yes” or “no” response was used to determine whether the participants had experienced depressed mood.
Suicidal ideation was assessed by participants’ positive answer to the following question: “During the past year, have you ever felt that you were willing to die?” A “yes” or “no” response was also used to determine whether the participants have suicidal thoughts. This item is a well-documented predictor of suicidal attempt that has been previously used in other surveys [22].

Ethical issues

The Institutional Review Board (IRB) at the Korea Centers for Disease Control and Prevention approved the study protocol (IRB number: 2010-02CON-21-C, 2011-02CON-06-C, 2012-01EXP-01-2C, 2013-07CON-03-4C, and 2015-01-02-6C), and written informed consent was provided by all the participants. In addition, this study was approved by the IRB of Seoul St. Mary’s Hospital (IRB number: KC18ZESI0573) to analyze KNHANES data.

Statistical analysis

Statistical analyses were performed using SPSS version 24.0 (IBM Corp., Armonk, NY, USA) to reflect the complex sampling design. All sampling and weight variables were stratified, and survey sample weights were used for all the analyses to produce non-biased estimates for the descriptive and analytic data analyses. The weighted value was created for a five-year-period. Estimates were not provided for the category of missing values. For all analyses, we used a list-wise deletion method to handle the missing values.
Differences in sociodemographic and health-related data including psychological distress between males and females were tested using the chi-square test or independent t-test. All categorical variables are presented as numbers with percentages, and all continuous variables as means with standard errors (SEs).
Multiple logistic regression analyses were used to assess the associations between the drinking or AUDIT levels and psychological distress. The odds ratios (ORs) and 95% confidence intervals (95% CIs) were also estimated after adjusting for potential confounders. For analyzing the associations of drinking levels with psychological distress, sex, age, education level, marital status, employment status, household income, smoking status, physical activity status, sleep duration, presence of medical or psychiatric conditions, high-risk drinking, and AUDIT levels were adjusted, and the drinking levels instead of AUDIT levels with above factors were adjusted in the analysis of the associations of AUDIT levels with psychological distress.
To evaluate the gender differences in the associations between the drinking or AUDIT levels and psychological distress, all the above variables except sex were adjusted, and menstrual condition (presence or absence of menstruation) was additionally adjusted for women. The p-values were two-tailed and those less than 0.05 were considered statistically significant.

RESULTS

The demographic characteristics of the genders are summarized in Table 1. The mean age was 46.8±0.2 and 44.8±0.2 years in females and males respectively, and women were older than men. Females were less likely than males to have a college degree, occupation, higher household income, and absence of medical or psychiatric conditions. In addition, more men than women were married, current smokers, and engaging in regular exercise. Sleep duration was longer in women. The percentage of heavy drinkers (1.7% vs. 13.9%) and possible alcohol dependence (Zone 4) (1.6% vs. 9.6%) was lower in females than males.
Table 2 presents gender differences in psychological distress. The numbers of individuals with moderate to severe stress perception (28.0% vs. 23.1%), experience of depressive mood (16.3% vs. 9.0%), and having suicidal ideation (13.5% vs. 7.9%) were significantly higher in females than males.
Figure 2 shows adjusted ORs and their 95% CIs of psychological distress from multiple logistic regression analyses in whole participants for drinking and AUDIT levels, respectively. The risks of psychological distress were not significantly associated with drinking levels after adjusting for confounding variables. According to AUDIT levels, however, the risk of psychological distress increased as the score increased based on Zone 1 (AUDIT scores: 0–7) after adjustment. The risks of stress perception in Zones 2, 3, and 4 were 1.16, 1.68, and 2.30 times higher than Zone 1, respectively. The risks of depressed mood were 1.23, 1.92, and 3.03 times higher, and suicidal ideation were 1.26, 1.59, and 3.17 times higher, respectively.
Figure 3 presents the gender differences in the risks of psychological distress according to the drinking and AUDIT levels. The risks of stress perception, depressed mood, and suicidal ideation were not significantly associated with drinking levels after adjusting for confounding variables in both females and males. By contrast, the risks for psychological distress according to AUDIT levels showed a difference between men and women. With regard to stress perception, the risks were significantly high in Zone 3 (adjusted ORs 1.49 in females and 1.67 in males) and 4 (adjusted ORs 2.46 in females and 2.25 in males) and not Zone 2 in both men and women. The risk in Zone 3 was higher in males than in females, whereas in Zone 4, the risk was higher in females than in males. The risks of depressed mood were high under conditions of Zones 3 and 4 (adjusted ORs 1.72 and 2.80, respectively) in males, while the risks were high even under condition of Zone 2 (adjusted OR 1.42) as well as Zones 3 and 4 (adjusted ORs 2.31 and 3.45, respectively) in females. In addition, the risks for depressed mood in Zones 3 and 4 were higher in women than in men. In terms of suicidal ideation, the risks were high even in Zone 2 (adjusted OR 1.53) as well as Zones 3 and 4 (adjusted ORs 1.90 and 3.48, respectively) in women, whereas the risk was 2.88 times higher only in Zone 4 in men.

DISCUSSION

The present study demonstrated that the risks of psychological distress were associated with an increase in AUDIT levels and there were gender differences in the psychological consequences of alcohol-related problems in the nationally representative sample.
In Zone 4 of AUDIT, the risk of stress perception was 2.30 times higher, the risk for depressed mood was 3.03 times higher, and the risk for suicidal ideation was 3.17 times higher than that of Zone 1. In addition, the risks for psychological distress were also higher in Zones 2 and 3 than in Zone 1. The present findings about the association between psychological distress and AUDIT levels broadly support the work of previous other studies in the area linking AUD and psychiatric symptoms. In humans and rodents, chronic alcohol consumption results in a general elevation in blood corticosteroid levels and also alters corticotropin-releasing factor activity independent from the hypothalamic-pituitary-adrenal (HPA) axis [23-29]. In addition, several prospective and longitudinal studies have shown that problematic alcohol drinking is significantly associated with depressive symptoms and that the causal role of problematic alcohol consumption was stronger than the causal role of greater levels of depressed mood [30-32]. However, the relationship between alcohol consumption and depressed mood is inconclusive regarding the direction of effects. Furthermore, individuals with alcoholism have a 60–120 times greater suicide risk than the non-psychiatrically ill population [8].
Remarkably, the association between problematic drinking and psychological distress is more drastic in women than men. In addition, women showed a significant association even though the severity of drinking problem was low with the exception of stress perception. These findings support the presence of gender differences in alcohol-related psychological problems and the higher susceptibility of women to the negative effects of alcohol on psychological health. According to previous findings, these gender differences in alcohol’s detrimental effects may be driven by gender differences in alcohol pharmacokinetics and neurotransmitter systems and the influence of gonadal steroid hormones on them. Regarding pharmacokinetics, evidence suggests that women have a higher blood alcohol concentration after consuming equivalent amounts of alcohol than men because women have a lower proportion of body water than men of similar body weight [33-35]. In addition, the sex disparity in gastric mucosa alcohol dehydrogenase (ADH) activity, which is involved in the first-pass ethanol metabolism, may likely contribute to the blood level of alcohol and alcoholic complications following alcohol intake [36-38]. Some reports suggested that total ADH activities including in stomach and liver were significantly higher in males than females [12,39], while others did not [40]. Therefore, these results imply that longer persistence of high ethanol blood level exists in women compared to men after alcohol intake, and thus, women tend to be exposed to higher degrees of alcohol in organs such as the brain that can affect mood and suicidal ideation. Regarding neurotransmitter system and the influence of gonadal hormones, males and females show differential patterns of neurotransmitter release and receptor availability in response to alcohol consumption [12]. Alcohol is known to alter γ-aminobutyric acid (GABA) system through the GABAA receptor [41,42] and other neurotransmitter systems such as the serotonergic system [11], and sex is an important factor for neurotransmitters’ receptor subunit expression [43-45]. In addition, female gonadal hormones affect many neurobiological responses [11], and specifically, changes in estrogen levels have been shown to influence concentrations of serotonin and serotonin-receptor subtype [46]. This interaction may contribute to an increased vulnerability to depression or suicidal ideation in women.
However, gender differences in the association between problematic drinking and stress perception showed a different pattern from depressed mood or suicidal ideation. In both men and women, Zones 3 and 4 showed higher stress perception than Zone 1, and in Zone 3, the risk for stress perception was higher in men than in women. So far, the complex relationship between alcohol and stress is poorly understood. Alcohol is known to be an effective anxiolytic [47-49], whereas alcohol can serve as a stressor that stimulates the HPA axis, with the magnitude and response degree being influenced by gender or alcohol drinking level [50]. Alcohol also alters stress reactivity differentially among men and women [51]. Previous studies have indicated that men show greater stress-related brain response in the fronto-limbic area [52] and higher cortisol response [53-55], whereas women show blunted adrenal responsivity [56] and greater tendencies to negative cognitions such as rumination under stress [57]. On the other hand, some studies have reported that alcohol consumption predicted decreased stress the day following alcohol intake in both sexes [51]. In addition, several factors such as individual differences in stress appraisal, coping strategies to stress, and response to alcohol intoxication play a role in modulating alcohol–stress interaction [58-60]. As such, the alcohol, stress, and gender interaction is complex and dynamic, and future studies with valid animal models are needed to understand mechanisms that underlie the complexity of alcohol and stress in males and females.
It is interesting that the present study did not find a significant association between drinking level and psychological distress in both males and females contrary to our expectation. Investigators found that a direct correlation between daily amounts of alcohol intake and increased risk for cancer or a curvilinear effect for coronary heart disease [3]. However, the findings of the current study do not support the previous research. This discrepancy suggests that the association between alcohol and psychological distress is not simply explained by the amount of alcohol consumed and can be influenced by other factors. In this context, epidemiological researchers have suggested beyond measures of “quantity consumed” to examine the importance of drinking patterns or type in explaining the consequences of alcohol on health. Previous studies have shown that specific beverage type (liquor, not beer) consumption was associated with poorer mental health, even in individuals who consume a light to moderate volume of alcohol [61]. Therefore, comprehensively assessing the drinking pattern and their related behaviors using structured questionnaires such as AUDIT—that are not limited only to the amount of alcohol intake—is required to predict the psychological consequences of alcohol consumption.
The findings of the present study need to be interpreted in light of the following limitations. First, psychological distress was assessed using simple self-report measures on the nature of data on national population study and only in the last one year regarding depressed mood and suicidal ideation. Questionnaires such as Patient Health Questionnaire-9, which is an instrument to screen for the presence and severity of depression and included in the 2014 6th KNHANES are more helpful to obtain a more accurate assessment for psychological distress. Second, we did not control other factors including personality factors, negative life events, family history of psychiatric illnesses, or social support that could affect psychological distress, even though we controlled several factors to identify the association between alcohol drinking or problematic drinking and psychological distress. Third, because this was a cross-sectional study, the establishment of cause-and-effect relationships between alcohol and psychological distress remains limited. Although multiple regression analysis was used to infer the causal relationship, these inferences can be further supported through animal and prospective and longitudinal human studies.
Despite these limitations, the primary strength of the present study is that all the data were obtained from a nationwide population study with a high response rate and sufficient sample size, and they provide representative information regarding the general Korean population. Furthermore, the findings have important implications for clinical practice such as conveying that comprehensive assessment like AUDIT is needed to evaluate the alcohol effect on psychological distress and that individuals–particularly women–who are even at low-risk for problematic drinking should be screened for psychological distress issues.
Approaches to assess psychological distress should take sex disparity into consideration. It is recommended that women with even low-level problematic drinking should be assessed for psychological symptoms including sub-threshold level, while men who have moderate to high-level problematic drinking should be assessed, particularly for the degree of stress level. Furthermore, further investigation focused on the mechanisms of alcohol effect on psychological distress and future studies with consideration for known and emerging gender-specific factors are needed to develop more appropriate evaluation and management strategies for both men and women.

ACKNOWLEDGEMENTS

This research was supported by Research Fund of Seoul St. Mary’s Hospital, The Catholic University of Korea.

The authors have no potential conflicts of interest to disclose.

Author Contributions

Jo-Eun Jeong, Soo-Hyun Joo, Changtae Hahn, and Tae-Suk Kim designed the study. Jo-Eun Jeong led data analysis and the writing of the manuscript. Dai-Jin Kim and Tae-Suk Kim supervised the interpretation of the results.

Figure 1.
Flow diagram of the study participants. KNHANES: Korea National Health and Nutrition Examination Survey, N: numbers, AUDIT: Alcohol Use Disorders Identification Test.
pi-2019-02-28f1.tif
Figure 2.
Adjusted odds ratios of psychological distress (stress perception, depressed mood, and suicidal ideation) in whole participants for drinking and AUDIT levels. Multiple logistic analysis, adjusted by age, education, occupation, household income, marital status, high-risk drinking, AUDIT levels, smoking status, regular exercise, sleep duration, and presence of psychiatric or medical diseases for drinking levels. Multiple logistic analysis, adjusted by age, education, occupation, household income, marital status, high-risk drinking, drinking levels, smoking status, regular exercise, sleep duration, and presence of psychiatric or medical diseases for AUDIT levels. **p<0.01. AUDIT: alcohol use disorders Identification Test, OR: odds ratio, CI: confidence interval.
pi-2019-02-28f2.tif
Figure 3.
Adjusted odds ratios of psychological distress for drinking and AUDIT levels between genders. A: stress perception, B: depressed mood, C: suicidal ideation. Multiple logistic analysis, adjusted by age, education, occupation, household income, marital status, high-risk drinking, AUDIT levels, smoking status, regular exercise, sleep duration, and presence of psychiatric or medical diseases for drinking levels. Multiple logistic analysis, adjusted by age, education, occupation, household income, marital status, high-risk drinking, drinking levels, smoking status, regular exercise, sleep duration, and presence of psychiatric or medical diseases for AUDIT levels. Additionally adjusted menstrual condition (presence or absence of menstruation) in females. *p<0.05, p<0.01 in females, p<0.01 in males. AUDIT: Alcohol use Disorders Identification Test, OR: odds ratio, CI: confidence interval.
pi-2019-02-28f3.tif
Table 1.
Demographic characteristics according to gender
Variables Female Male p value
Age (years) (N=29,995) 46.8±0.2 44.8±0.2 <0.001
Education (N=28,294) 16,283 (100.0) 12,011 (100.0) <0.001
 ≤Elementary 4,994 (30.7) 2,080 (17.3)
 Middle school 1,679 (10.3) 1,367 (11.4)
 High school 5,148 (31.6) 4,372 (36.4)
 ≥College 4,462 (27.4) 4,192 (34.9)
Occupation (N=28,239) 16,287 (100.0) 11,952 (100.0) <0.001
 Yes 7,764 (47.7) 8,785 (73.5)
 No 8,523 (52.3) 3,167 (26.5)
Household income (N=29,649) 16,949 (100.0) 12,700 (100.0) <0.001
 Low 3,620 (21.3) 2,308 (18.2)
 Moderate-low 4,365 (25.8) 3,254 (25.6)
 Moderate-high 4,422 (26.1) 3,510 (27.6)
 High 4,542 (26.8) 3,628 (28.6)
Marital status (N=29,939) 17,121 (100.0) 12,818 (100.0) <0.001
 Single 2,139 (12.5) 2,171 (16.9)
 Married 11,630 (67.9) 9,924 (77.4)
 Others 3,352 (19.6) 723 (5.7)
Drinking levels (N=24,652) 13,094 (100.0) 11,558 (100.0) <0.001
 Non-drinker 2,889 (22.1) 1,442 (12.5)
 Mild to moderate drinker 9,984 (76.2) 8,507 (73.6)
 Heavy drinker 221 (1.7) 1,609 (13.9)
AUDIT (N=24,618) 13,081 (100.0) 11,537 (100.0) <0.001
 0–7 (Zone 1) 11,281 (86.2) 5,653 (49.0)
 8–15 (Zone 2) 1,372 (10.5) 3,617 (31.4)
 16–19 (Zone 3) 222 (1.7) 1,155 (10.0)
 ≥20 (Zone 4) 206 (1.6) 1,112 (9.6)
High-risk drinking (N=29,160) 16,786 (100.0) 12,374 (100.0) <0.001
 Yes 636 (4.8) 2,309 (21.0)
 No 16,150 (95.2) 10,065 (79.0)
Smoking status (N=28,614) 16,437 (100.0) 12,177 (100.0) <0.001
 Never 14,657 (89.2) 2,415 (19.8)
 Ex-former 889 (5.4) 4,949 (40.7)
 Current 891 (5.4) 4,813 (39.5)
Regular exercise (N=28,256) 16,262 (100.0) 11,994 (100.0) <0.001
 Yes 2,731 (16.8) 2,776 (23.1)
 No 13,531 (83.2) 9,218 (76.9)
Sleep duration (N=28,565) 9.2±0.2 8.5±0.2 <0.001
Presence of psychiatric or medical diseases (N=29,158) 16,786 (100.0) 12,372 (100.0) <0.001
 Yes 6,459 (38.5) 4,314 (34.9)
 No 10,327 (61.5) 8,058 (65.1)

Values are presented as number (%) or mean±standard errors. Psychiatric or medical diseases: depression, hypertension, dyslipidemia, stroke, myocardiac infarction, angina, osteoarthritis, rheumatoid arthritis, pulmonary tuberculosis, asthma, chronic renal failure, atopic dermatitis, diabetes, thyroid diseases, hepatitis, liver cirrhosis, and stomach, liver, colon, breast, cervix, lung, thyroid, and other cancers

Table 2.
Psychological distress in female and male samples
Variables Female Male p value
Degree of stress perception (N=28,611) 16,432 (100.0) 12,179 (100.0) <0.001
 Moderate to severe 4,597 (28.0) 2,808 (23.1)
 None to mild 11,835 (72.0) 9,371 (76.9)
Experience of depressive mood for two or more continuous weeks (N=28,615) 16,432 (100.0) 12,180 (100.0) <0.001
 Yes 2,674 (16.3) 1,094 (9.0)
 No 13,761 (83.7) 11,086 (91.0)
Suicidal ideation during the previous year (N=28,614) 16,436 (100.0) 12,178 (100.0) <0.001
 Yes 2,225 (13.5) 964 (7.9)
 No 14,211 (86.5) 11,214 (92.1)

Values are presented as number (%)

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