1. Introduction
As correlations between pollutants and health are increasingly drawing social attention, efforts to evaluate the relationship between environmental pollution and diseases have been undertaken worldwide, such as the 2007 World Health Organization (WHO) report on environmental burden of diseases. The 2000 WHO report listed 13 environmental risk factors: outdoor air pollution, indoor air pollution, water, sanitation, hygiene, climate change, occupation, noise, other housing risks, recreational environment, land use and built environment, other community risks, and radiation [
1,
2]. These reports indicated that South Korea ranked 50 among 191 countries, with a score of 26 for disability-adjusted life years (DALY) per 1,000 persons. This was a much higher value compared to other WHO Western Pacific Regions such as Japan (15/1000), Singapore (14/1000), and Australia (16/1000). Thus, the present study addresses concerns regarding data-relevance.
Several studies on measuring the environmental burden of disease have been conducted; some evaluated the utility of research methodologies and their results [
3] others gauged air pollution in urban areas [
4] using Population Attributable Fraction (PAF) and PM
2.5 concentration levels [
5]. In addition, various studies have investigated the burden of disease according to environmental risk factors, such as water pollution [
6] or climate change [
7,
8], while others investigated specific subjects such as regional residents, individuals in developing countries stratified by age [
9,
10,
11], or comparisons between children and adults [
12].
In Korea, Lee and colleagues have reported on pollution exposure and its effects [
13], Jung and colleagues investigated the health condition of residents in mining areas [
14], and Back examined the correlation between outdoor and indoor air pollution and asthma [
15]. However, all Korean studies have only investigated the correlation between pollutants and health conditions or focused on patterns of diseases with prevalence or incidence rates as dependant variables. In other words, no study has measured the burden of disease by quantitatively analyzing risk factors.
In this study, we calculated DALY for diseases with environmental risk factors-based on measured Korean public health data (as opposed to estimates), and assessed the impact of environmental pollution on health conditions by quantifying the burden of disease.
2. Methods
2.1. Data Collection
Our study considered all ages of the Korean population in 2007. To investigate incidence as a measure of the burden of disease, we included first-time inpatients at hospitals in 2007. We assumed that individuals struggling with illnesses were likely to seek hospital treatment. We therefore excluded patients who visited hospitals in 2004–2006 for the same diagnosis as per the International Classification of Disease (ICD)-10 [
17]. We also used Health Insurance Evaluation Review and Assessment Service (HIRA) insurance and claim data.
Some diseases (e.g., asthma, chronic obstructive pulmonary disease (COPD), and diarrhea), would have often required primary treatment at outpatient clinics and may have been managed without hospitalization; we therefore included incidence from outpatient records. Typically, chronic asthma and COPD patients have longer hospital stays. Thus, we defined incidence cases as patients who had no record of outpatient visits in 2004–2006 but had visited outpatient clinics at least thrice in 2007. For acute diarrhea, individuals with three or more hospital visits in 2007 were included.
To collect data on mortality, the number of deaths was divided by causes of death based on ICD-10 codes according to age and gender from national statistics of death causes in 2007. For data on injuries, number of deaths and incidence were classified according to age and gender based on raw data from a 2005 study on damage performed by Korea Centers for Disease Control and Prevention (KCDC). Despite the time gap, we used data obtained in 2005, as research on trauma was not conducted in 2007.
2.2. Environmental Burden of Disease
Data were analyzed in three steps to measure the environmental burden of disease in Korea. Diseases occurring due to environmental risk factors were first classified, and the 13 WHO risk factors were defined as potential causes of diseases. In the second step, attributable risks were determined to evaluate the degree to which these factors affected each disease. DALY was then calculated based on epidemiological indices related to each disease (e.g., incidence, mortality, and survival rates).
To estimate the environmental burden of disease, we used DALY and PAF. The model structure for the environmental burden of disease is presented in
Figure 1. To identify environmental diseases, those linked to the 13 WHO environmental risk factors and disease categories [
1,
2], were classified as per the ICD-10 code.
Regarding risk factors, we examined four major environmental risk factors identified by Valent and colleagues: indoor and outdoor air pollution, water pollution, and occupation [
12]. We also considered the effects of climate change as they have increased considerably. Other risk factors including noise, other housing risks, chemicals, recreational environment, land use and built environment, other community risks, and radiation were also investigated to explore correlations between diseases and each risk factor.
To assess exposure to these 13 risk factors, attributable risk based on specific risk factors (
i.e., PAF) was measured. Korean data for air pollution using the PM10 standard [
19] and water-pollution exposure based on water supply rates were used in this study. However, because of the lack of local data we used PAF reported by WHO for indoor air pollution, occupational factors, climate change, noise, other housing risk, chemicals, recreational environment, land use and built environment, other community risks, and radiation [
18].
Figure 1.
Research model for environmental burden of disease. DALY: disability-adjusted life year; PAF: population attributable fraction; YLL: years of life lost; YLD: years lived with disability.
Figure 1.
Research model for environmental burden of disease. DALY: disability-adjusted life year; PAF: population attributable fraction; YLL: years of life lost; YLD: years lived with disability.
The burden of disease due to a specific risk factor—based on incidence and mortality rates—could be calculated by considering population exposure levels, its prevalence, age of onset, duration, and disability weight [
16]. From these data, DALY could be obtained by adding years of life lost (YLL) and years lived with disability (YLD). We ensured comparability by applying a discount rate according to time value and age weights, as per WHO protocols. Therefore, by multiplying DALY with PAF of each risk factor according to disease, the environmental burden of disease—termed Korea-Environmental Burden of Disease (K-EBoD)—was calculated.
2.3. Statistical Analysis
The data used to measure burden of disease were processed with SAS 9.2 (SAS Institute, Cary, NC, USA). Basic data were derived for frequency analysis. In addition, DISMOD-II was used to calculate morbidity and average age of onset. The WHO has recently developed a newer version of DISMOD program (DISMOD-MR) for estimating the burden of diseases as a prevalence-based measure when population data is unavailable. However, since our study examines incidence-based burden of disease, we used DISMOD-II instead of DISMOD-MR.
3. Results
The database yielded by the three-step analysis was used to obtain DALY values. The burden of disease was calculated by multiplying DALY with PAF of environmental risk factors. For attributable risk of air pollution, regional PM
10 levels based on the National Institute of Environmental Research (Ministry of Environment) data were used to determine the exposed population [
19], and PAF was calculated using relative risks that were applicable to Korea based on a literature review [
20,
21,
22,
23,
24]. PAF, derived from attributable risk, is presented in
Table 1.
Table 1.
Attributable risk of diseases related to PM10 exposure.
Table 1.
Attributable risk of diseases related to PM10 exposure.
Diseases | PAF |
---|
Preterm [20] | 0.0679 |
Lung Cancer [21] | male 0.6837/female 0.2057 |
Chronic Obstructive Pulmonary Disease [22] | 0.3024 |
Asthma [23] | 0.1319 |
Ischemic Heart Disease [22] | 0.3265 |
Pneumonia [24] | 0.1340 |
To evaluate attributable risk of water pollution, exposure level was determined from water supply rates in Korea, which was 92.1% in December 2007 [
19]. This study observed WHO guidelines for defining PAF [
25], according to which, quality of water and hygiene could be divided into three categories: water supply, sanitation and hygiene, and water management and safety. The 11 diseases linked to these factors are presented in
Table 2. In the present study, a scenario-based approach was used to calculate PAF of diarrhea; the Korean water supply rate was examined in relation to the relative risk measure proscribed by the WHO. The risk of diarrhea attributable to water pollution was 86%. For other diseases, attributable risks from WHO Western Pacific Regions were used. PAF levels [
18] are presented in
Table 3.
Table 2.
Diseases related to water pollution and attributable risk.
Table 2.
Diseases related to water pollution and attributable risk.
Diseases and Attributable Risk |
---|
Disease | Attributable Risk(%) |
---|
Diarrhea | 86 |
Malnutrition | 50 |
Intestinal nematode infections | 100 |
Schistosomiasis | 100 |
Trachoma | 100 |
Lymphatic filariasis | 82 |
Onchocerciasis | 10 |
Dengue | 95 |
Japanese encephalitis | 95 |
Table 3.
Attributable risk factors according to diseases [
25].
Table 3.
Attributable risk factors according to diseases [25].
Risk Factor | Diseases a | PAF of Developed Countries in Western-Pacific Region |
---|
Indoor air pollution | RI | lower: 0.20/upper: 0.12 |
Perinatal conditions | 0.06 |
Lung cancer | male: 0.30/female: 0.30 |
Cataracts | 0.07 |
COPD | male: 0.27/female: 0.09 |
Asthma | 0.44 |
Climate change | Diarrhea | 0.90 |
Malaria | 0.40 |
Dengue | 0.95 |
Occupational factor | Lung cancer | 0.18 |
COPD | 0.03 |
Asthma | 0.12 |
Cardiovascular disease | 0.12 |
TB | 0.19 |
Cataracts | 0.07 |
Other unintentional injuries | 0.08 |
Neuropsychiatric disorder | 0.01 |
Other cancer | 0.02 |
Musculoskelectal disease | male: 0.17 / female: 0.20 |
STDs | 0.23 |
HIV | 0.08 |
Hepatitis B, C | 0.23 |
Congenital abnormalies | 0.23 |
Falls | 0.12 |
Drowning | 0.12 |
Road traffic injuries | 0.01 |
Other housing risks | Other unintentional injuries | 0.08 |
Falls | 0.12 |
Violence | 0.16 |
Noise | Hearing loss | Male: 0.09 / female: 0.06 |
Chemicals | Congenital abnormalies | 0.23 |
Poisonings | 0.71 |
Suicide | 0.001 |
Recreational environment | Other unintentional injuries | 0.08 |
Drowning | 0.12 |
Land use and built environment | Other unintentional injuries | 0.08 |
Road traffic injuries | 0.16 |
Water resources management | Malaria | 0.40 |
Other community risks | Other unintentional injuries | 0.08 |
Falls | 0.12 |
Radiation | Other unintentional injuries | 0.08 |
Congenital abnormalies | 0.23 |
As shown in
Figure 2, the total K-EBoD was 17.98 per 1000 persons. Air pollution accounted for the largest proportion at 6.89/1000, followed by occupation at 3.29/1000, and indoor air pollution at 2.91/1000. When indoor and outdoor air-pollution values were combined, the burden of disease was more than half of the total K-EBoD, at 9.80/1000. The highest burden of disease was related to respiratory organs; COPD, lung cancer, and asthma were 4.07, 3.16, and 1.96 per 1000 persons, respectively. Considering that outdoor and indoor air pollution occupied the largest proportion of the burden of disease among risk factors, the results are unsurprising. The classification of the environmental burden of disease according to YLD and YLL is shown in
Figure 2.
Figure 2.
A composition of years lost to disability (YLD) and years of life lost (YLL) according to risk factors (unit: DALYs/1,000 persons).
Figure 2.
A composition of years lost to disability (YLD) and years of life lost (YLL) according to risk factors (unit: DALYs/1,000 persons).
Diseases with a large portion of YLL could be considered as diseases with high mortality. YLD and YLL for outdoor air pollution was 4.12 and 2.77, for indoor air pollution was 2.58 and 0.33, and for occupation was 2.66 and 0.63 per 1000 persons.
Although the difference in burden of disease due to indoor air pollution and occupation was not large (indoor air pollution: 2.91 per 1000 persons; occupation: 3.29 per 1000 persons), the latter was considered more critical because of its relatively higher YLL.
This population-based study does not consider assumed values but measures actual values; we were therefore unable to suggest confidence intervals or uncertainty intervals.
4. Discussion
This study measured the environmental burden of disease in South Korea by evaluating the contribution of diseases with environmental risk factors to overall risk.
We used the PAF of developed countries in WHO Western Pacific Region for environmental risk factors besides air pollution [
18]. Classifying Korea as a developed or developing country was difficult. According to the Organisation for Economic Co-operation and Development (OECD), while South Korea ranked 10th in the economic scale among the 30 member countries, it ranked 17th for income disparity and 20th for average national income [
26]. However, when WHO standards for classifying developing and developed countries are used—mortality rates of adults and of children aged at most 5 years—they were comparable to developed countries; the mortality rate of children in Korea (six deaths per 1000 persons) was not significantly higher than that of Japan (four deaths per 1000 persons), New Zealand (six deaths per 1000 persons), and Singapore (three deaths per 1000 persons). Therefore, attributable risk was calculated by classifying Korea as a developed country in the Western Pacific region.
To evaluate exposure to the risk factors, attributable risk for specific risk factors was measured. Korean data for air pollution (using PM
10 level) [
19] and water pollution exposure levels (using water supply rate) were used. National statistics on exposure levels for indoor air pollution, occupational factors, climate change, noise, housing risks, chemicals, recreational environment, land use and built environment, other community risks, and radiation were either unavailable [
18]. Or were not regarded as serious risk factors. This suggests that the government needs to prepare for the “global warming era” by collecting quantitative data to assess country-specific issues.
For COPD and asthma—with strong links to air pollution—YLD values in relation to DALY were 3.73 (4.07 DALY/1000 persons) and 1.85 (1.96 DALY/1000 persons), respectively. That is, their YLD was considerably higher than YLL. However, since quality of life is regarded as an important index of health, YLD should be treated seriously. Various policies need to consider support to manage illnesses. Moreover, the economic burden should be quantified and addressed. For example, the Korean Academy of Tuberculosis and Respiratory disease reported that medical costs for a patient with stage I COPD was about 1.39 million Won (KRW) per year, while that for stage IV was 3.13 million KRW, based on a nation-wide survey of eight hospitals. The morbidity of mild COPD was 17% in adults aged 45 years or older, and 41.4% in the elderly aged 75 years or older, indicating that the physical and economic burden on elderly individuals is huge [
27].
However, examining economic burden was beyond the scope of this study. Moreover, it varied considerably between studies on the burden of disease. The WHO-CHOICE program that evaluates both the burden of disease and intervention costs could measure cost per DALY. Consequently, it would be possible to determine the efficacy of intervention programs for environmental risk exposure and compare their cost effectiveness.
Although the study attempted to examine actual data on prevalence and mortality to measure DALY, such that it realistically reflects the realities of Korea, patients who did not visit a health facility during the study period were excluded. This may explain why the environmental burden of diseases was the lowest for the lowest economic group [
28]. Some diseases such as vector-borne diseases, trauma, and occupational hazards were difficult to investigate. For trauma, data on discharged trauma patients were used, but for the other two HIRA data was utilized. While it was appropriate to use the following sources to measure DALY comprehensively, it did not meet various requirements. Regarding vector-borne diseases, statistics from the Center for Infectious Disease, KCDC, would have yielded accurate measurements. However, while it showed prevalence, it did not consider incidence for specific periods and therefore would not yield accurate DALY. Further, although specific measures from data on industrial accidents are recommended, Korea Workers’ Compensation and Welfare Service insurance and compensation statistics did not report incidence and disease onset, and was therefore considered inappropriate to measure occupational diseases in this study.
In addition, although the outdoor air pollution risk factor was PM
10 in this study, a more accurate measure of the burden of disease would be PM
2.5, which includes fine particles and gaseous materials (NO
x, SO
x, CO, O
3,
etc.). Considering the possible harmful effects of PM
2.5, the United States, European Union, and WHO have revised their recommended air pollution criteria (for example, the U.S. used ultrafine particles as a criterion of atmospheric environment). Korea has also attempted to include PM
2.5 as a new criterion to improve atmospheric environment [
19].