A Trend Analysis of the Prevalence, Awareness, Treatment, and Control of Hypertension by Age Group

Article information

J Prev Med Public Health. 2013;46(6):353-359
Publication date (electronic) : 2013 November 28
doi : https://doi.org/10.3961/jpmph.2013.46.6.353
Department of Preventive Medicine, Soonchunhyang University College of Medicine, Cheonan, Korea.
Corresponding author: Yoon Hyung Park, MD, PhD. 31 Suncheonhyang 6-gil, Dongnam-gu, Cheonan 330-930, Korea. Tel: +82-41-570-2483, Fax: +82-41-575-2406, parky@sch.ac.kr
Received 2013 September 27; Accepted 2013 October 21.

Abstract

Objectives

We examined the trends in prevalence, awareness, treatment, and control of hypertension in Korea as a basis for improving hypertension control programs.

Methods

12 598 participants of the Korean National Health and Nutrition Examination Survey were included in this study. Weighted linear regression to test time trends from 2007 to 2011 was performed.

Results

The prevalence of hypertension was 20.7% in 2007, 29.4% in 2009, and 26.2% in 2011. Awareness of hypertension was 64.8% in 2007 and 61.1% in 2011. Awareness in those aged 65 and over was greater than in younger groups (age 19 to 44 and 45 to 64; p<0.001). The treatment rates were 58.4% in 2007 and 56.8% in 2011. The treatment rate was greater for those 65 and over than for younger age groups (p<0.001). The percentage of controlled hypertension was 37.6% in 2011. The percentage of controlled hypertension in those 65 and over was higher than in younger age groups (p<0.001). The treatment-control rates were 65.9% in 2007 and 67.7% in 2011. The prevalence of hypertension was higher in the males (p<0.001), while the awareness (p<0.001), treatment (p<0.001), and control (p<0.001) rates were higher in the females.

Conclusions

The prevalence of hypertension was increasing and the hypertension awareness, treatment, and control rates were low in younger age groups and males.

INTRODUCTION

The prevalence of cardiovascular disease (CVD) has been continuously increasing due to population aging, and changes in consumption and lifestyle patterns [1]. This global trend is also apparent in the Republic of Korea, reflected in the increasing mortality and personal cost to treat and manage CVD [2]. As the prevalence of chronic conditions is increasing, the risk of mortality due to chronic conditions, especially hypertension, and associated complications are rising in numbers along with them [3-5]. Cerebrovascular disease caused 50.7 deaths per 100 000 members of the population in 2011, followed by 49.8 deaths by CVD and 21.5 deaths caused by diabetes [6].

Furthermore, the leading global risks for mortality are high blood pressure (BP, responsible for 13% of deaths globally), tobacco use (9%), high blood glucose (6%), physical inactivity (6%), and overweight and obesity (5%) [7]. In 2011, the Political Declaration on Noncommunicable Diseases was adopted by the UN General Assembly [8]. The declaration focused on the risk factors and national systems response to 4 noncommunicable diseases (NCDs): CVD, diabetes, cancer, and chronic respiratory disease. The UN target is 25% reduction in relative mortality from NCDs by 2025 [9]. To control those burdens, strict control of BP is required. According to the Joint National Committee 7 guideline, for every 20 mmHg increase in systolic or 10 mmHg in diastolic BP, there is a doubling of mortality from both ischemic heart disease and stroke [10]. Other studies on the elderly have also noted that improving control of hypertension is important to reduce the risk for CVDs [11,12]. Thus many programs to control hypertension, such as screening and education to reduce its complications, have been implemented [13-15].

Our study examined changes in the prevalence, awareness, treatment, and control of hypertension for all adults combined and for subsets by age and sex across Korean National Health and Nutrition Examination Survey (KNHANES) 2007 to 2011 data with the aim of gathering information for improving hypertension control programs.

METHODS

Data from the 2007 to 2011 KNHANES, conducted by the Korea Centers for Disease Control and Prevention (KCDC), was used in this study. The KNHANES participants were selected using stratified, multistage probability sampling of the non-institutionalized population. All adults provided written informed consent. In data analysis method and presenting results, 'US trends in prevalence, awareness, treatment, and control of hypertension, 1988-2008' [16] were used.

Definitions

In the KNHANES 2007 to 2011, BP was measured by physicians trained in the method using a mercury sphygmomanometer (Baumanometer; WA Baum Co., New York, NY, USA) and appropriately sized arm cuffs after the study participants rested 5 minutes seated. Individuals without a recorded BP were excluded. In determining the mean BP for individuals, the first BP was used if only 1 measurement was obtained. The second BP was used if 2 readings were taken; the second and third values were averaged when available. Hypertension was defined as a mean systolic BP of at least 140 mmHg, mean diastolic BP of at least 90 mmHg, or both, and/or confirming that a participant was currently taking prescription medication to lower BP. Awareness of hypertension was determined by patients with hypertension responding affirmatively to the question, "Have you ever been diagnosed with hypertension by a doctor?" Treatment of hypertension was established by participants responding yes to the question, "Are you currently using antihypertensive drugs?" Control of hypertension was defined as BP under 120/80 mmHg with or without treatment. Treatment-control of hypertension was defined as BP under 120/80 mmHg with treatment. For calculating awareness, treatment, and control, the participants were stratified into the following age groups: 19 to 44 years, 45 to 64 years, and 65 years and above.

Data Analysis

The KNHANES Analytic and Reporting Guidelines were followed. SAS version 9.3 (SAS Inc., Cary, NC, USA) was used to account for the KNHANES complex sampling design, to estimate mean values and percentages, and to calculate 95% confidence intervals (CIs). To calculate prevalence, survey commands were used and for calculating awareness, treatment, and control, additional weights were calculated because hypertension prevalence varies by age group. Weighted linear regression to test time trends from 2007 to 2011 was performed using estimated mean values or percentages as dependent variables. Reciprocals of variances were used as weights. Time was an independent and continuous variable in the regression models for all of the patients with hypertension combined and each subgroup. Statistical significance was defined by p<0.05. Data are presented as means and 95% CIs.

RESULTS

All Adults

The mean age increased over time between 2007 and 2011 (p for trend=0.008) (Table 1). The mean systolic BP (p<0.001) and mean diastolic BP (p=0.005) both increased over time.

Characteristics of all adult participants in the Korean National Health and Nutrition Examination Survey 2007 to 20111

The proportion of stage 1 and 2 hypertension (stage 1: systolic/diastolic BP, 140-159/90-99 mmHg; stage 2: systolic/diastolic BP, over 160/over 100 mmHg) increased from 9.9% (95% CI, 8.3% to 11.5%) to 12.5% (95% CI, 11.3 to 13.6) from 2007 to 2011 (p for trend<0.001) and 3.1% (95% CI, 2.2 to 3.9) to 3.9% (95% CI, 3.3 to 4.5) from 2007 to 2011 (p for trend=0.002) (Table 1). The mean body mass index (BMI, kg/m2) increased from 2007 to 2011 (p for trend <0.001). The proportions of normal body weight (18.5≤ BMI <25.0, p=0.88) and obesity (BMI ≥25.0, p=0.94) did not change. The prevalence of hypertension increased from 20.7% (95% CI, 18.5% to 23.0%) in 2007 to 26.2% (95% CI, 24.6% to 27.7%) in 2011 (p<0.001) (Table 2).

Characteristics of adult participants with hypertension in the Korean National Health and Nutrition Examination Survey 2007 to 20111

All Patients With Hypertension

Among the participants with hypertension, the mean age (p=0.69) did not change (Table 3). The proportion of men increased from 51.3% (95% CI, 46.4% to 56.2%) in 2007 to 55.8% (95% CI, 53.3% to 58.2%) in 2011 (p=0.01). The mean systolic BP did not change (p=0.42), but the mean diastolic pressure decreased from 86 mmHg (95% CI, 84.8 to 87.1 mmHg) to 84.1 mmHg (95% CI, 83.3 to 84.8 mmHg) from 2007 to 2011 (p=0.05). The proportion of stage I (p=0.24) and stage II (p=0.37) hypertension, prehypertension (p=0.14), and normal BP (p=0.35) did not change over the 5 years. The mean BMI decreased from 25.3 (95% CI, 25.1 to 25.6) to 24.9 (95% CI, 24.7 to 25.1) from 2007 to 2011 (p=0.02). The proportion of participants with normal body weight increased (p=0.03), while the proportion of obese participants decreased (p=0.01).

Prevalence, awareness, treatment, and control of hypertension in the Korean National Health and Nutrition Examination Survey 2007 to 2011

The prevalence of hypertension increased from 20.7% (95% CI, 18.5% to 23.0%) to 26.2% (95% CI, 24.6% to 27.7%) from 2007 to 2011 (p<0.001) (Table 2). The proportion of participants who were diagnosed with hypertension by a doctor (awareness rate) decreased over the 5 years (p=0.02). The proportion of patients who were treated for hypertension (treatment rate) initially decreased from 58.4% (2007) to 47.4% (2009). However, it then increased to 56.8% in 2011, but the trend remained unchanged over the entire 5 years (p=0.20). The proportions of patients being treated or whose BP was already normal (treatment-control rate) were 65.9% (2007), 70.1% (2008), 54.0% (2009), 56.2% (2010), and 67.7% (2011), but the trend was unchanged (p=0.08). The proportions of all of the patients (treated or not) whose BP was normal (control rate) were 37.6% (2007), 41.1% (2008), 25.5% (2009), 28.9% (2010), and 37.6% (2011), but the trend was unchanged (p=0.28).

Epidemiology of Hypertension by Age Group

The prevalence of hypertension increased during 2007 to 2011 in individuals aged 19 to 44 years (p<0.001), 45 to 64 years (p=0.002), and 65 years and over (p<0.01) (Figure 1A). However, while the awareness rate increased in those aged 65 years and over (p<0.01), it decreased in those aged 19 to 44 years (p<0.01) and 45 to 64 years (p<0.01) over the course of the 5 years (Figure 1B). The treatment rate of hypertension increased in those 65 years and over (p<0.01), but it decreased in those aged 19 to 44 years (p<0.01), and was unchanged in those aged 45 to 64 during the 5 years (Figure 1C). The treatment-control rate did not change over time in any of the age groups. In addition, there were no differences between those 65 years and above and those 19 to 44 years (p=0.07) and 45 to 64 years (p=0.07) (Figure 1D). The control rate decreased in those aged 19 to 44 (p<0.01) and 45 to 64 (p=0.03), but it did not change in those aged 65 years and above during the 5 years (p=0.15) (Figure 1E).

Figure 1

Characteristics of hypertension by age groups. Data are presented as means with 95% confidence intervals. (A) Prevalence of hypertension by age group, (B) awareness rates of hypertension patients by age group, (C) treatment rates of hypertension patients by age group, (D) control rates of hypertension patients with treatment by age group, and (E) control rates of hypertension patients by age group.

Epidemiology of Hypertension by Sex

The prevalence of hypertension increased from 2007 to 2011 in both the males (p<0.01) and the females (p<0.01) (Table 4). Furthermore, the prevalence was higher in the males (p<0.01). The awareness rate decreased with time in the men (p<0.01) but not the women (p=0.58) and was greater in the women than the men (p<0.01). The treatment rate did not change in the women (p=0.91) or men (p=0.22) and was higher in the women than the men (p<0.01). The treatment-control rate did not change in the women (p=0.10) or men (p=0.98). The control rate in the women (p=0.91) and men (p=0.22) did not change over time, and there was no difference between the two groups.

Prevalence, awareness, treatment, and control of hypertension by sex in the Korean National Health and Nutrition Examination Survey 2007 to 2011

DISCUSSION

In the representative sample of Korean adults who participated in the KNHANES in 2007 to 2011, the mean BMI and diastolic BP increased over time. However, in the hypertensive patients, the BMI and diastolic BP decreased, but the prevalence of hypertension was 20.7% in 2007, 29.4% in 2009, and 26.2% in 2011. In a similar study in the US, the prevalence of hypertension was 29.5% in 2009 to 2010 [17]. In another study in Korea in 2004, the prevalence of hypertension was 28.3% [18], and in yet another study in a rural area of Korea in 2000, the prevalences of hypertension in males and females were 18.1% and 15.5%, respectively [19]. Therefore, it is not safe to conclude that the prevalence of hypertension changed as rapidly in one year as the present study found, but it does seem that there is a trend of increasing prevalence of hypertension. The prevalence of hypertension increased in all age groups. However, the awareness and control rate decreased all age groups except those aged 65 and over. The treatment rate decreased in the 19 to 44 age group. The prevalence of hypertension in the younger age group increased but the awareness, treatment, and control rates were lower than in the older age groups. Therefore, policies targeting younger people, such as education in schools and workplaces, are needed. One systematic review has addressed which educational and organizational interventions are effective in reaching BP goals and reducing mortality [20].

The treatment-control rate was 54% to 70.1% and it did not change over time. This shows that over 30% of the hypertension patients were not controlled even if they were using antihypertensive drugs. The first explanation could be that resistant hypertension, in which the BP remains above the goal in spite of the concurrent use of 3 antihypertensive agents of different classes, is highly prevalent in older age [21]. Second, compliance with treatment might be low even if the participants answered that they were taking antihypertensive medicine. Third, physicians differ in the goals they set for controlling hypertension.

The limitations of our study are as follows: first, a short period during which to examine the trends of hypertension. The KNHANES has been conducted since 1998. However, the survey questions and physical examination methods were different at first. The circulating survey has been used only since 2007. Because we wanted to examine the trends of hypertension, consistency of data was important. Therefore, data before 2007 were not used in our analysis. Second, people who were under age 19 and in hospitals and nursing homes were omitted. Third, the misclassification of participants could have occurred during the survey.

In conclusion, this was the first study using KNHANES data to examine trends in hypertension awareness, treatment, and control rates by age group and sex. The prevalence of hypertension was found to be increasing and the hypertension awareness, treatment, and control rates were low in the younger age group and male group. Therefore, efforts to detect people with high BP and policies focusing on the hypertension of younger age groups is needed to prevent the complications of hypertension.

Notes

The authors have no conflicts of interest with the material presented in this paper.

References

1. World Health Organization. The global burden of disease Geneva: World Health Organization; 2008. p. 25–26.
2. Chung HG, Kang YK. 2009 National health insurance statistical yearbook Seoul: National Health Insurance Corporation; 2010. p. 351–598.
3. Vasan RS, Larson MG, Leip EP, Evans JC, O'Donnell CJ, Kannel WB, et al. Impact of high-normal blood pressure on the risk of cardiovascular disease. N Engl J Med 2001;345(18):1291–1297. 11794147.
4. Khosla N, Kalaitzidis R, Bakris GL. The kidney, hypertension, and remaining challenges. Med Clin North Am 2009;93(3):697–715. 19427500.
5. Wong ND, Thakral G, Franklin SS, L'Italien GJ, Jacobs MJ, Whyte JL, et al. Preventing heart disease by controlling hypertension: impact of hypertensive subtype, stage, age, and sex. Am Heart J 2003;145(5):888–895. 12766749.
6. Statistics Korea. Mortality statistics 2011 cited 2013 Sep 23. Available from: http://kostat.go.kr/portal/korea/kor_nw/2/6/2/index.board?bmode=read&aSeq=260046.
7. Epping-Jordan J. Innovate care for chronic conditions: building blocks for action global report Geneva: World Health Organization; 2002. p. 12–13.
8. Alleyne G, Binagwaho A, Haines A, Jahan S, Nugent R, Rojhani A, et al. Embedding non-communicable diseases in the post-2015 development agenda. Lancet 2013;381(9866):566–574. 23410606.
9. World Health Organization. NCD global monitoring framework cited 2013 Sep 23. Available from: http://www.who.int/nmh/global_monitoring_framework/en/.
10. Chobanian AV. The seventh report of the Joint National Committee on Prevention, Detection, Evaluation, and Treatment of High Blood Pressure Bethesda: National Institutes of Health; National Heart, Lung, and Blood Institute; 2004. p. 9–10.
11. Wolf-Maier K, Cooper RS, Kramer H, Banegas JR, Giampaoli S, Joffres MR, et al. Hypertension treatment and control in five European countries, Canada, and the United States. Hypertension 2004;43(1):10–17. 14638619.
12. Rashid P, Leonardi-Bee J, Bath P. Blood pressure reduction and secondary prevention of stroke and other vascular events: a systematic review. Stroke 2003;34(11):2741–2748. 14576382.
13. Fortmann SP, Winkleby MA, Flora JA, Haskell WL, Taylor CB. Effect of long-term community health education on blood pressure and hypertension control. The Stanford Five-City Project. Am J Epidemiol 1990;132(4):629–646. 2403104.
14. Kotchen JM, McKean HE, Jackson-Thayer S, Moore RW, Straus R, Kotchen TA. Impact of a rural high blood pressure control program on hypertension control and cardiovascular disease mortality. JAMA 1986;255(16):2177–2182. 3959301.
15. Iso H, Shimamoto T, Naito Y, Sato S, Kitamura A, Iida M, et al. Effects of a long-term hypertension control program on stroke incidence and prevalence in a rural community in northeastern Japan. Stroke 1998;29(8):1510–1518. 9707185.
16. Egan BM, Zhao Y, Axon RN. US trends in prevalence, awareness, treatment, and control of hypertension, 1988-2008. JAMA 2010;303(20):2043–2050. 20501926.
17. Guo F, He D, Zhang W, Walton RG. Trends in prevalence, awareness, management, and control of hypertension among United States adults, 1999 to 2010. J Am Coll Cardiol 2012;60(7):599–606. 22796254.
18. Lee WY, Park JS, Noh SY, Rhee EJ, Kim SW, Zimmet PZ. Prevalence of the metabolic syndrome among 40,698 Korean metropolitan subjects. Diabetes Res Clin Pract 2004;65(2):143–149. 15223226.
19. Ha YC, Chun HJ, Hwang HK, Kim BS, Kim JR. The prevalence, awareness, treatment, and control of hypertension, and related factors in rural Korea. Korean J Prev Med 2000;33(4):513–520. (Korean).
20. Gu D, Reynolds K, Wu X, Chen J, Duan X, Muntner P, et al. The International Collaborative Study of Cardiovascular Disease in ASIA. Prevalence, awareness, treatment, and control of hypertension in china. Hypertension 2002;40(6):920–927. 12468580.
21. Calhoun DA, Jones D, Textor S, Goff DC, Murphy TP, Toto RD, et al. Resistant hypertension: diagnosis, evaluation, and treatment. A scientific statement from the American Heart Association Professional Education Committee of the Council for High Blood Pressure Research. Hypertension 2008;51(6):1403–1419. 18391085.

Article information Continued

Figure 1

Characteristics of hypertension by age groups. Data are presented as means with 95% confidence intervals. (A) Prevalence of hypertension by age group, (B) awareness rates of hypertension patients by age group, (C) treatment rates of hypertension patients by age group, (D) control rates of hypertension patients with treatment by age group, and (E) control rates of hypertension patients by age group.

Table 1.

Characteristics of all adult participants in the Korean National Health and Nutrition Examination Survey 2007 to 20111

Characteristics 2007 (n = 3020) 2008 (n = 6772) 2009 (n = 7504) 2010 (n = 6303) 2011 (n = 6150) p for trend2
Mean age (y) 44.1 (43.1, 45.2) 44.4 (43.6, 45.2) 44.8 (44.0, 45.6) 45.1 (44.2, 46.1) 45.7 (44.8, 46.6) 0.008
Sex (%)
 Men 49.5 (47.9, 51.1) 49.5 (48.3, 50.6) 49.5 (48.5, 50.6) 49.1 (47.9, 50.3) 49.5 (48.2, 50.8) 0.98
 Women 50.5 (48.9, 52.1) 50.5 (49.4, 51.7) 50.5 (49.4, 51.5) 50.9 (49.7, 52.1) 50.5 (49.2, 51.8)
Mean BP (mmHg)
 Systolic 115.6 (114.3, 116.9) 114.3 (113.5, 115.1) 119.0 (118.3, 119.7) 119.6 (118.8, 120.4) 117.6 (116.9, 118.4) <0.001
 Diastolic 76.0 (75.3, 76.7) 74.8 (74.3, 75.4) 78.3 (77.8, 78.8) 77.2 (76.7, 77.8) 76.1 (75.7, 76.5) 0.005
BP (mmHg, %)
 ≥160/≥100 3.1 (2.2, 3.9) 2.6 (2.1, 3.1) 5.3 (4.5, 6.0) 4.6 (3.9, 5.3) 3.9 (3.3, 4.5) 0.002
 140-159/90-99 9.9 (8.3, 11.5) 10.8 (9.8, 11.7) 16.6 (15.4, 17.8) 16.2 (14.9, 17.6) 12.5 (11.3, 13.6) <0.001
 120-139/80-89 32.7 (30.2, 35.2) 28.4 (27.0, 29.9) 33.5 (32.1, 34.9) 32.6 (30.9, 34.3) 33.2 (31.6, 34.8) 0.10
 <120/<80 54.4 (51.1, 57.7) 58.2 (56.1, 60.3) 44.6 (42.7, 46.5) 46.6 (44.2, 48.9) 50.5 (48.5, 52.5) <0.001
 Mean BMI 23.6 (23.5, 23.8) 23.6 (23.4, 23.7) 23.6 (23.5, 23.7) 23.6 (23.5, 23.7) 23.7 (23.5, 23.8) <0.001
BMI (%)
 <18.5 4.6 (3.6, 5.7) 5.0 (4.3, 5.7) 4.8 (4.2, 5.4) 4.8 (4.2, 5.5) 5.0 (4.3, 5.8) 0.66
 18.5-24.9 63.3 (61.1, 65.4) 63.9 (62.4, 65.4) 63.3 (61.9, 64.7) 63.9 (62.4, 65.4) 63.1 (61.5, 64.6) 0.88
 ≥30.0 32.1 (29.9, 34.3) 31.1 (29.6, 32.6) 31.9 (30.6, 33.3) 31.3 (29.8, 32.8) 31.9 (30.3, 33.5) 0.94
Diabetes (%) 5.9 (4.8, 7.0) 6.1 (5.5, 6.8) 6.1 (5.4, 6.7) 6.3 (5.6, 7.0) 6.6 (5.8, 7.4) 0.25

Values are presented as mean or % (95% confidence interval) by year.

BP, blood pressure; BMI, body mass index.

1

Data are weighted based on a Korean population.

2

Weighted linear regression was used for calculating p for trends.

Table 2.

Characteristics of adult participants with hypertension in the Korean National Health and Nutrition Examination Survey 2007 to 20111

Characteristics 2007 (n = 764) 2008 (n = 1837) 2009 (n = 2486) 2010 (n = 2138) 2011 (n = 1967) p for trend2
Mean age (y) 57.7 (56.2, 59.3) 56.5 (55.6, 57.5) 55.4 (54.3, 56.5) 56.3 (55.2, 57.4) 57.2 (56.1, 58.3) 0.69
Sex (%)
 Men 51.3 (46.4, 56.2) 52.4 (50.1, 54.7) 57.8 (55.6, 59.9) 55.9 (53.4, 58.5) 55.8 (53.3, 58.2) 0.01
 Women 48.7 (43.8, 53.6) 47.6 (45.3, 49.9) 42.2 (40.1, 44.4) 44.1 (41.5, 46.6) 44.2 (41.8, 46.7)
Mean BP (mmHg)
 Systolic 136.8 (135, 138.6) 133.1 (131.8, 134.3) 136.6 (135.7, 137.6) 137.5 (136.6, 138.5) 135.3 (134.2, 136.3) 0.42
 Diastolic 86.0 (84.8, 87.1) 85.0 (84.2, 85.8) 88.2 (87.5, 88.9) 86.6 (85.9, 87.3) 84.1 (83.3, 84.8) 0.05
BP (mmHg, %)
 ≥160/≥100 14.9 (11.5, 18.2) 11.5 (9.4, 13.7) 18.0 (15.8, 20.2) 15.7 (13.5, 17.8) 14.8 (12.6, 17.1) 0.37
 140-159/90-99 47.5 (43, 52.1) 47.4 (44.6, 50.1) 56.5 (53.9, 59) 55.4 (52.4, 58.4) 47.6 (44.5, 50.7) 0.24
 120-139/80-89 28.9 (24.4, 33.5) 26.4 (24, 28.7) 19.7 (17.7, 21.7) 22.5 (20.1, 24.8) 26.3 (23.9, 28.7) 0.14
 <120/<80 8.6 (6.2, 11.1) 14.7 (12.2, 17.3) 5.9 (4.6, 7.1) 6.4 (5.3, 7.6) 11.2 (9.5, 12.9) 0.35
 Mean BMI 25.3 (25.1, 25.6) 25.0 (24.8, 25.2) 25.0 (24.8, 25.2) 25.0 (24.8, 25.2) 24.9 (24.7, 25.1) 0.02
BMI (%)
 <18.5 1.0 (0.5, 1.6) 2.3 (1.6, 3.1) 1.8 (1.1, 2.4) 1.5 (0.9, 2.2) 2.4 (1.5, 3.2) 0.14
 18.5-24.9 45.8 (42, 49.6) 48.7 (45.8, 51.5) 50.7 (48.2, 53.3) 51.4 (48.5, 54.3) 50.2 (47.5, 52.9) 0.03
 ≥30.0 53.2 (49.3, 57.1) 49.0 (46.1, 51.8) 47.5 (45.0, 50.0) 47.0 (44.0, 50.0) 47.4 (44.7, 50.2) 0.01
Diabetes (%) 14.6 (11.7, 17.5) 15.0 (13.1, 16.8) 13.0 (11.5, 14.5) 12.6 (11.1, 14) 15.6 (13.7, 17.6) 0.97

Values are presented as mean or % (95% confidence interval) by year.

BP, blood pressure; BMI, body mass index.

1

Data are weighted based on a Korean population.

2

Weighted linear regression was used for calculating p for trends.

Table 3.

Prevalence, awareness, treatment, and control of hypertension in the Korean National Health and Nutrition Examination Survey 2007 to 2011

2007 2008 2009 2010 2011 p for trend1
Prevalence %2 20.7 (18.5, 23.0) 22.7 (21.3, 24.1) 29.4 (27.7, 31) 29.3 (27.5, 31.1) 26.2 (24.6, 27.7) <0.001
Awareness %3 64.8 (59.8, 69.8) 65 (62.1, 67.8) 52.4 (49.4, 55.4) 56.6 (53.1, 60.2) 61.1 (58.2, 64.0) 0.02
Treatment %3 58.4 (53.1, 63.6) 58.8 (55.7, 61.9) 47.4 (44.2, 50.5) 52.2 (48.9, 55.6) 56.8 (53.9, 59.8) 0.20
Treatment-control %3 65.9 (58.6, 73.3) 70.1 (66.5, 73.8) 54.0 (50.3, 57.7) 56.2 (52.5, 59.9) 67.7 (64.2, 71.2) 0.28
Control %3 37.6 (32.4, 42.8) 41.1 (37.8, 44.4) 25.5 (22.8, 28.2) 28.9 (26.3, 31.5) 37.6 (34.7, 40.4) 0.08

Values are presented as mean or % (95% confidence interval) by years.

1

Weighted linear regression was used for calculating p for trends.

2

Data are weighted based on a Korean population.

3

Additional weights are calculated because the prevalence of hypertension is different by years.

Table 4.

Prevalence, awareness, treatment, and control of hypertension by sex in the Korean National Health and Nutrition Examination Survey 2007 to 2011

Sex 2007 2008 2009 2010 2011 p for trend1
Prevalence %2 Male 21.5 (18.3, 24.7) 24.0 (22.2, 25.8) 34.2 (32.1, 36.3) 33.4 (30.9, 35.9) 29.5 (27.4, 31.6) <0.001
Female 20.0 (17.3, 22.7) 21.4 (19.8, 23.0) 24.6 (22.6, 26.6) 25.4 (23.3, 27.4) 22.9 (21.1, 24.8) 0.006
Awareness %3 Male 55.6 (48.4, 62.8) 56.1 (52.2, 60.1) 43.9 (40.3, 47.5) 45.3 (40.9, 49.6) 50.8 (46.8, 54.9) 0.02
Female 74.4 (69.4, 79.5) 74.6 (71.1, 78.2) 64.1 (60.5, 67.7) 71.1 (67.4, 74.7) 73.8 (70.1, 77.6) 0.58
Treatment %3 Male 48.7 (41.4, 56.0) 47.6 (43.4, 51.9) 37.8 (34.3, 41.4) 40.1 (36.1, 44.1) 46.1 (42.1, 50.2) 0.22
Female 68.5 (62.7, 74.2) 71 (67.3, 74.6) 60.4 (56.5, 64.2) 67.6 (63.9, 71.4) 70.1 (66.3, 74.0) 0.91
Treatment-control %3 Male 62.0 (52.0, 72.0) 68.2 (62.1, 74.3) 53.0 (47.5, 58.5) 59.3 (54.0, 64.6) 65.6 (60.3, 70.9) 0.98
Female 68.8 (60.6, 77.0) 71.6 (67.9, 75.3) 54.9 (50.9, 58.8) 53.8 (49.2, 58.5) 69.4 (65.4, 73.5) 0.10
Control %3 Male 29.5 (23.1, 35.8) 32.3 (28.0, 36.6) 20.0 (17.1, 22.9) 23.4 (20.3, 26.5) 29.4 (25.8, 32.9) 0.33
Female 46.2 (39.9, 52.4) 50.8 (46.7, 54.8) 33.1 (29.8, 36.3) 35.9 (32.1, 39.6) 47.9 (44.0, 51.8) 0.17

Values are presented as mean or % (95% confidence interval) by year.

1

Weighted linear regression was used for calculating p for trends.

2

Data are weighted based on a Korean population.

3

Additional weights are calculated because the prevalence of hypertension is different by years.