DOI: https://doi.org/10.21203/rs.3.rs-34132/v1
Background: Cardiovascular health (CVH) metrics among Chinese older adults are poorly understood. We investigated gender disparities in CVH metrics and their management among rural-dwelling older adults in China.
Methods: This community-based study included 5026 participants (age ≥65 years; 57.2% women) in the baseline survey of a multimodal intervention study in rural China. Data were collected through face-to-face interviews, clinical examinations, and laboratory tests in March-September 2018. We defined six CVH metrics (three behavioral factors—smoking, body mass index, and physical activity; three biological factors—blood pressure, total cholesterol, and blood glucose) following the modified American Heart Association’s recommendations. We performed descriptive analysis separately for men and women.
Results: Of all participants, only 0.8% achieved ideal levels in all six CVH metrics. Men were more likely than women to have ideal levels in all CVH metrics but smoking. Women had higher prevalence of ideal global CVH metrics (9.7% in women vs. 7.8% in men) and behavioral CVH metrics (18.3% vs. 9.5%) (p<0.001), whereas men had higher prevalence of ideal biological CVH metrics (5.4% in men vs. 3.5% in women, p<0.001). The prevalence of ideal global and behavioral CVH metrics increased with age in both women and men (p for trend<0.001). Women were more likely to be aware of their hypertension and diabetes, and to receive antihypertensive treatment, while men were more likely to achieve the goal of high cholesterol treatment (p<0.05).
Conclusions: The CVH metrics among older adults living in the rural communities in China are characterized by an extremely low proportion of optimal global CVH metrics and distinct gender differences, alongside poor management of major biological risk factors.
Trial registration: ChiCTR1800017758.
Cardiovascular disease (CVD) is the leading cause of death in China, and the burden of CVD is projected to steadily increase in the coming decades, driven primarily by population aging as well as rapid economic development and urbanization.[1, 2] Adoption of healthy lifestyles or behaviors (e.g., no smoking and physical activity) and optimal controls of major biological or cardiometabolic risk factors (e.g., high blood pressure, high cholesterol, and high blood glucose) are well-established strategies to prevent CVD.[3, 4]
In 2010, the American Heart Association (AHA) proposed composite cardiovascular health (CVH) metrics that integrated seven lifestyle-related factors (Life’s Simple 7), i.e., smoking, body mass index (BMI), diet, physical activity, blood pressure, blood glucose, and total cholesterol.[5] Systematic reviews suggested that ideal CVH metrics were associated with a reduced risk of cardiovascular events and mortality.[6-8] However, the prevalence of ideal CVH metrics was extremely low in middle-aged and elderly people in many countries, including China.[9-13] In addition, the gender differences in CVH metrics have been previously reported in studies from Europe, whereby ideal CVH metrics were more common in women than in men.[14, 15] However, data from community-based studies that focus on gender disparities in CVH metrics are limited in China, especially among rural-dwelling Chinese older adults.
In the past five decades, the management and control of biological or cardiometabolic components of CVH metrics such as high blood pressure, high cholesterol, and high blood glucose in high-income countries have been steadily improved,[16] which significantly contributes to the declining trends in incidence and mortality of CVD.[6] However, the age-standardized prevalence of CVD had increased from 1990 to 2016 in China.[2] Several studies have reported medical treatment and effective control rates of hypertension, diabetes, and high cholesterol among Chinese adults.[17-19] However, gender differences in the management of major biological CVH metrics in rural-dwelling older adults remain unclear.
Thus, in the current study, we sought to investigate the gender-specific distribution of CVH metrics and management of biological CVH components among Chinese older adults living in the rural communities in western Shandong province.
Study Participants
This is a population-based cross-sectional study. The study sample was derived from participants in the baseline survey of the ongoing Multimodal Interventions to delay Dementia and disability in rural China (MIND-CHINA), which targets people who were aged ≥65 years and living in the rural communities of Yanlou Town, Yanggu County, western Shandong Province, China. In March-September 2018, 5246 participants were examined as part of the baseline survey for MIND-CHINA. Of these, 220 (4.19%) were excluded due to missing data on CVH measurements, leaving 5026 persons for the current analysis.
The Ethics Committee of Shandong Provincial Hospital affiliated to Shandong University in Jinan, China reviewed and approved the protocol for MIND-CHINA. Written informed consent was obtained from all the participants, or in the case of cognitively impaired persons, from a proxy (usually a family member). MIND-CHINA was registered in the Chinese Clinical Trial Registry (registration no.: ChiCTR1800017758).
Data Collection and Assessments
The trained staff collected data via face-to-face interviews, clinical examinations, and laboratory tests following a structured questionnaire, which was developed and adapted from questionnaires used in the Study on Global Ageing and Adult Health (SAGE) and a local survey of aging and health.[20, 21] Data included demographic features (e.g., age, gender, and education), lifestyles (e.g., smoking, BMI, and physical activity), health history (e.g., hypertension, diabetes, and CVD), and use of medications in the last two weeks before the survey. Weight and height were measured with participants wearing light clothes and without shoes. BMI was calculated as weight (kg) divided by height squared (m2). After a 5-min rest, arterial blood pressure was measured on the right upper arm in a seated position using an electronic blood pressure monitor (HEM-7127J, Omron Corporation, Kyoto, Japan). We assessed physical activity via questions of frequency (e.g., daily, weekly, and monthly) and time (minutes) of walking, sports activities, and recreational activities. The frequency of physical activity was coded as 7, 1, and 1/4 for daily, weekly, and monthly activity, respectively, and physical activity was quantified as minutes spent per week by multiplying participation frequency with average minutes spent per time. Then we calculated the metabolic-equivalent of each activity according to the 2011 compendium of physical activities.[22] Peripheral blood samples were taken after an overnight fast, and blood samples were analyzed at the certified clinical laboratory of the local town health center. Fasting blood glucose (FBG) and total cholesterol (TC) were measured using an automatic biochemical analyzer (DIRUI CS-600B; DIRUI Corporation, Changchun, China).
Hypertension was defined as systolic pressure ≥140 mm Hg or diastolic pressure ≥90 mm Hg or current use of antihypertensive medication,[17] and high cholesterol as TC ≥6.22 mmol/L or having received treatment for high cholesterol,[18] diabetes as self-reported history of diabetes diagnosed by a physician or FBG ≥7.0 mmol/L or current use of blood glucose-lowering medication.[19] “Awareness” of a disease was referred to a self-reported physician diagnosis of the disease before the examination.[17] “Treatment” was referred to self-reported use of medications for a certain disease, and the treatment rate as the proportion of persons who were taking medications among people with the disease.[19] The control rate of hypertension, diabetes, and high cholesterol was defined as the proportion of achieving the goal of blood pressure <140/90 mm Hg,[17] TC <6.22 mmol/L,[18] and FBG <7.0 mmol/L,[19] respectively, among people who took the corresponding medications (control A) or among people who had the corresponding disease (control B).
Definition of Cardiovascular Health Metrics
We defined CVH metrics following the AHA’s recommendations,[5] with some modifications (Supplemental Table 1): (1) we did not include diet due to a lack of dietary data; (2) we defined ideal BMI as <24 kg/m2, as recommended for Chinese adults;[23] and (3) we defined ideal smoking level as never or quitting smoking >5 years.[24] Thus, we included six factors in the CVH metrics: smoking, BMI, physical activity, blood pressure, total cholesterol, and FBG. We considered smoking, BMI, and physical activity as behavioral CVH metrics, and blood pressure, total cholesterol, and FBG as biological CVH metrics. We categorized each of the six factors into three levels of poor, intermediate, and ideal. Participants with 0-2, 3-4, and 5-6 metrics at the ideal levels were defined as having poor, intermediate, and ideal global CVH metrics, respectively. [5] Furthermore, people with 0-1, 2, and 3 behavioral or biological CVH metrics at the ideal level were defined as having poor, intermediate, and ideal behavioral or biological CVH metrics, respectively.[14]
Statistical Analysis
Descriptive analysis was performed to report mean (standard deviation, SD) for continuous variables with normal distribution, and frequency (proportion) for categorical variables. Characteristics of the study participants by gender were compared using the chi-square test for categorical and t-test for normal distributed continuous variables. We reported the prevalence rate of individual and composite CVH metrics and the rates of awareness, treatment, and control of biological CVH components. IBM SPSS Statistics for Windows 22.0 (IBM Corp, Armonk, NY, USA) was used for all analyses. Two-tailed p<0.05 was considered to be statistically significant.
The mean age of the 5026 participants was 71.5 years (SD, 5.3), and 57.2% were women. Compared with men, women were slightly older, less educated (p<0.001), and had a higher level of BMI, systolic pressure, FBG, and TC, but a lower level of diastolic pressure (p<0.001) (Table 1). In addition, only 0.8% of all participants achieved the ideal level in all six CVH metric components.
Table 2 shows the overall and gender-specific prevalence of individual CVH metrics and composite measures of global, behavioral, and biological CVH metrics. Overall, the prevalence of ideal level in individual CVH metrics ranged from 42.4% to 72.1%, except blood pressure, where only 7.9% achieved an optimal level. The prevalence of ideal level in the composite CVH metrics ranged from 8.9% in global CVH metrics and 4.3% in biological CVH metrics to 14.5% in behavioral CVH metrics. There were significant gender differences in all individual and composite CVH metrics (Table 2). Compared to women, men were more likely to have an ideal level for behavioral CVH metric components, except smoking, where women had an extremely low smoking rate (1.4% in women vs. 46.8% in men, p<0.001). In addition, men had a higher proportion of ideal biological CVH metric components (i.e., TC, FBG, and blood pressure) than women (p<0.05). Furthermore, men had a higher proportion of ideal composite biological CVH metrics (p<0.001), whereas women were more likely to have an ideal level for the composite behavioral CVH metrics (p<0.001).
The prevalence of ideal individual CVH metrics increased with age for BMI (p for trend<0.001), but was stable with age for blood pressure at a very low rate (<10%) (Figure 1). The prevalence of ideal FBG and physical activity slightly increased initially until age 75-79, then dropped significantly with age, whereas the prevalence of ideal TC decreased with age until age 75-79, then increased significantly with age (Figure 1). Moreover, the prevalence of ideal composite global and behavioral CVH metrics increased with age in both women and men (p for trend<0.001), whereas the prevalence of ideal composite biological CVH metrics was stable with age at a low rate (<10%) (Figure 2).
We examined the awareness, medical treatment, and control rates of three biological CVH components overall and by gender (Table 3). The overall prevalence of hypertension, diabetes, and high cholesterol was 67.1%, 14.4%, and 15.1%, respectively. Women had a higher prevalence of hypertension (p=0.001), diabetes (p<0.001), and high cholesterol (p<0.001) than men. Among people with hypertension, 59.4% were aware of their hypertension, and 33.0% were treated with antihypertensive drugs, but only 20.3% of those treated achieved the goal of blood pressure control. Of those with diabetes, 80.7% were aware of their diagnosis, and 33.2% received pharmacological treatment; among those who were treated with blood glucose drugs, only 37.1% achieved the goal of their blood glucose. Among people with high cholesterol, 25.4% were aware of their high cholesterol condition, 34.4% were treated with cholesterol-lowering drugs, and 94.7% of those treated people achieved good control of high total cholesterol. Moreover, the overall control rates among people with the disease were 6.7% for hypertension, 39.5% for diabetes, and 32.6% for high cholesterol. Furthermore, women had higher rates of awareness (p<0.001) and treatment (p=0.016) for hypertension, and higher rates of awareness (p<0.001) and effective control (p=0.003) for diabetes, while men had higher rates of treatment (p<0.001) and effective control (p<0.001) for high cholesterol (Table 3).
This large-scale community-based study revealed an overall very low prevalence of ideal global composite CVH metrics as well as substantial gender differences in CVH metrics, such that men were more likely than women to have all ideal individual CVH metrics except smoking and ideal composite biological CVH metrics, whereas women were more likely to have ideal composite behavioral and global CVH metrics than men. Furthermore, women had higher awareness rates of hypertension and diabetes, whereas men had higher rates of treatment and effective control in high cholesterol. These findings may have significant implications for precision management of cardiovascular health risks among rural-dwelling older adults.
The extremely low proportion (<1%) of older adults that could achieve the ideal level in all the examined six components of CVH metrics in our study is consistent with several reports from other countries.[6, 25-28] However, the distribution of individual CVH metrics in our study population appears to differ from that of studies from the western societies. The prevalence rates of ideal BMI, FBG, TC, and physical activity (ranging from 42.4% to 68.4%) were slightly higher than reports from western countries,[14, 29] probably because of the favorable traditional lifestyles (except smoking in men) in the local rural areas, such as the diet of high grain, high vegetable, and low meat consumptions.[30] Unfortunately, we did not have detailed dietary data to compare with the literature. However, the ideal level of blood pressure in our study was very low (<10%), which could be partially due to the fact that salt intake in northern China (e.g., Shandong Province) is among the highest in the world.[31] Moreover, the overall prevalence of current smoking (20.8%) in our study participants was higher than that in western countries (ranging from 10.5% to 16.3%),[14, 29, 32] but the gender differences in smoking habits in our population (46.8% vs. 1.4%) is much more substantial compared with reports from western societies.
Given that unhealthy lifestyles and behaviors may result in an unfavorable state of biological or metabolic CVH metrics, it could be expected that the prevalence of ideal composite biological CVH was also very low in our study population (<5%). Furthermore, the frequency of ideal composite biological CVH metrics was lower than that of composite behavioral CVH metrics (4.3% vs. 14.5%), which is consistent with previous studies.[14] This suggests that biological or metabolic risk factors might contribute even more heavily than unhealthy lifestyles or behavioral factors to poor cardiovascular health, which highlights the need to promote healthy behaviors and improve the management of cardiometabolic risk factors in rural China.
The gender differences in composite measurements of CVH metrics have been rarely explored in the literature. We found that women were more likely to have ideal composite global and behavioral CVH metrics, which is in accordance with the previous cross-sectional studies of middle-aged and elderly people in France.[6, 14] Of note, the gender differences in global and behavioral CVH metrics in our study might be driven primarily by smoking habits, where the prevalence of smoking was very high in men (46.8%) but very low in women (1.4%) owing to socio-cultural tradition and social environment in Asia and China, especially in rural regions.[33] Besides, men were more likely to have ideal biological CVH metrics in our study of older adults, which is in contrast to a previous study of middle-aged and older people in France.[14] This discrepancy is likely due to the facts that premenopausal women are relatively protected against cardiovascular and metabolic risks and that the gender differences diminish with advancing age, particularly after menopause.[34]
Previous studies have shown that major lifestyles and cardiometabolic risk factors are poorly controlled in low- and middle-income countries, especially among residents living in remote rural areas.[20, 32, 35] Findings from our community-based study are in line with those previous studies and further showed the distinct profiles for these risk factors between men and women. Despite of highly prevalent cardiometabolic risk factors, only around one-third of people with these metabolic risk factors were treated, and even lower proportions of those who were treated achieved the goals of treatment. Notably, some people with diabetes were able to achieve the goal of blood glucose control without taking antidiabetic medications, which may partially reflect the fact that adaptation of healthy lifestyles and behaviors (e.g., diet and physical activity) could play a part in achieving the goal of blood glucose control. [36] Moreover, we found that women were more likely than men to be aware of their hypertension and diabetes. As a result, in spite of a higher prevalence of hypertension in women than in men, the rates of achieving the goal of blood pressure control were comparable between men and women. As for high total cholesterol, men had higher rates of treatment and effective control than women, which were consistent with the reports from a previous study of rural-dwelling older adults in China.[20] Of note, women had a higher prevalence of hypertension, diabetes, and high cholesterol than men, which is consistent with gender difference in biological CVH metrics in our study. Taken together, the biological risk profiles of the rural-dwelling older adults were characterized by highly prevalent and poorly controlled biological or cardiometabolic risk factors. Thus, additional efforts are needed to promote cardiovascular health by improving medical treatment and effective control of these risk factors.
The strengths of this study include the community-based design, the relatively large sample of the rural residents in China, and comprehensive assessments of major CVH metrics. However, our study also has limitations. Firstly, physical activity and smoking status were self-reported, which may be subject to recall bias. Secondly, we were not able to follow the AHA’s original recommendations in defining CVH metrics due to a lack of dietary data. Finally, the study participants from only one rural area may not be representative of the rural population in China, which should be kept in mind when generalizing the study findings to other rural population.
This community-based study reveals that the overall prevalence of ideal CVH metrics was very low, along with distinct gender differences in individual and composite CVH metrics, and that the biological or metabolic CVH components were poorly controlled among Chinese rural-dwelling older adults. These results call for more efforts to improve cardiovascular health among rural residents in China. Furthermore, characterizing the gender differences in CVH metrics may help achieve precision preventive interventions to reduce CVD burden among older Chinese people.
Acknowledgments
We would like to thank all the participants in the Multidomain Interventions to Delay Dementia and Disability in Rural China (MIND-CHINA) as well as the MIND-CHINA Research Group for their collaboration in data collection and management.
Competing interests
The authors declare no financial or other conflicts of interest.
Funding
This study was supported in part by grants from the National Key R&D Program of China Ministry of Sciences and Technology (grant no.: 2017YFC1310100), the National Natural Science Foundation of China (grants no.: 81861138008 and 8191101618), the Academic Promotion Program of Shandong First Medical University, China, and the Taishan Scholar Program of Shandong Province, China. C Qiu received grants from the Swedish Research Council (grants no.: 2017-00740 and 2017-05819) for the Sino-Sweden Network and Joint Research Projects, the Swedish Foundation for International Cooperation in Research and Higher Education (STINT, grant no.: CH2019-8320) for the Joint China-Sweden Mobility program, and Karolinska Institutet, Stockholm, Sweden.
Availability of data and materials
The datasets used and/or analyzed during the current study are available from the corresponding author on reasonable request.
Authors' contributions
Study concept and design: X.H., Y.W., Y.D., and C.Q.; Acquisition of data: Z.J., Y.L., Y.D., and S.T.; Analysis and interpretation of data: X.H., Y.W., and C.Q.; Drafting of the manuscript: X.H. and C.Q.; Supervision: Y.D. and C.Q.; Critical revision of the manuscript for important intellectual content: all authors.
Ethics approval and consent to participate
The study received approval from the Ethics Committee of Shandong Provincial Hospital affiliated to Shandong University in Jinan, China. Written informed consent was obtained from participants.
Consent for publication
The paper contains aggregated data only.
Table 1. Characteristics of study participants by gender
Characteristics |
Total sample |
Men |
Women |
p-valuea |
No. of participants (%) |
5026 (100) |
2150 (42.8) |
2876 (57.2) |
|
Age (years) |
71.5 (5.3) |
71.4 (5.1) |
71.6 (5.4) |
0.108 |
Age (years), n (%) |
|
|
|
0.001 |
65-69 |
2152 (42.8) |
939 (43.7) |
1213 (42.2) |
|
70-74 |
1644 (32.7) |
684 (31.8) |
960 (33.4) |
|
75-79 |
756 (15.0) |
356 (16.6) |
400 (13.9) |
|
≥80 |
474 (9.4) |
171 (8.0) |
303 (10.5) |
|
Education, n (%) |
|
|
|
<0.001 |
Illiterate |
1992 (39.6) |
284 (13.2) |
1708 (59.4) |
|
Primary school |
2215 (44.1) |
1173 (54.6) |
1042 (36.2) |
|
Middle school or above |
819 (16.3) |
693 (32.2) |
126 (4.4) |
|
Systolic pressure (mm Hg) |
144.1 (21.5) |
142.4 (21.2) |
145.3 (21.6) |
<0.001 |
Diastolic pressure (mm Hg) |
85.0 (11.0) |
85.9 (10.9) |
84.3 (10.9) |
<0.001 |
Fasting blood glucose (mmol/l) |
5.6 (1.4) |
5.5 (1.3) |
5.6 (1.5) |
0.001 |
Total cholesterol (mmol/l) |
5.0 (1.0) |
4.7 (0.9) |
5.2 (1.0) |
<0.001 |
Body mass index (kg/m2) |
24.9 (3.8) |
24.4 (3.7) |
25.2 (3.9) |
<0.001 |
No. of ideal CVH metric components, n (%) |
|
|
|
<0.001 |
0 |
44 (0.9) |
43 (2.0) |
1 (0.03) |
|
1 |
356 (7.1) |
194 (9.0) |
162 (5.6) |
|
2 |
1198 (23.8) |
523 (24.3) |
675 (23.5) |
|
3 |
1739 (34.6) |
727 (33.8) |
1012 (35.2) |
|
4 |
1243 (24.7) |
495 (23.0) |
748 (26.0) |
|
5 |
408 (8.1) |
149 (6.9) |
259 (9.0) |
|
6 |
38 (0.8) |
19 (0.9) |
19 (0.7) |
|
Data are mean (standard deviation), unless otherwise specified.
Abbreviation: CVH, cardiovascular health.
ap-value is for the test of differences between men and women.
Table 2. Prevalence of cardiovascular health metrics by gender
CVH metrics |
Total sample (n=5026) |
Men (n=2150) |
Women (n=2876) |
p-valuea |
|
Smoking status, n (%) |
Poor |
1045 (20.8) |
1006 (46.8) |
39 (1.4) |
<0.001 |
Intermediate |
355 (7.1) |
344 (16.0) |
11 (0.4) |
|
|
Ideal |
3626 (72.1) |
800 (37.2) |
2826 (98.3) |
|
|
Physical activity, n (%) |
Poor |
1774 (35.3) |
708 (32.9) |
1066 (37.1) |
<0.001 |
Intermediate |
612 (12.2) |
222 (10.3) |
390 (13.6) |
|
|
Ideal |
2640 (52.5) |
1220 (56.7) |
1420 (49.4) |
|
|
Body mass index, n (%) |
Poor |
974 (19.4) |
341 (15.9) |
633 (22.0) |
<0.001 |
Intermediate |
1920 (38.2) |
792 (36.8) |
1128 (39.2) |
|
|
Ideal |
2132 (42.4) |
1017 (47.3) |
1115 (38.8) |
|
|
Blood pressure, n (%) |
Poor |
3148 (62.6) |
1295 (60.2) |
1853 (64.4) |
0.008 |
Intermediate |
1481 (29.5) |
668 (31.1) |
813 (28.3) |
|
|
Ideal |
397 (7.9) |
187 (8.7) |
210 (7.3) |
|
|
Total cholesterol, n (%) |
Poor |
513 (10.2) |
100 (4.7) |
413 (14.4) |
<0.001 |
Intermediate |
1537 (30.6) |
525 (24.4) |
1012 (35.2) |
|
|
Ideal |
2976 (59.2) |
1525 (70.9) |
1451 (50.5) |
|
|
Fasting blood glucose, n (%) |
Poor |
437 (8.7) |
168 (7.8) |
269 (9.4) |
0.032 |
Intermediate |
1151 (22.9) |
471 (21.9) |
680 (23.6) |
|
|
Ideal |
3438 (68.4) |
1511 (70.3) |
1927 (67.0) |
|
|
Global CVH metrics, n (%) |
Poor |
1598 (31.8) |
760 (35.3) |
838 (29.1) |
<0.001 |
Intermediate |
2982 (59.3) |
1222 (56.8) |
1760 (61.2) |
|
|
Ideal |
446 (8.9) |
168 (7.8) |
278 (9.7) |
|
|
Behavioral CVH metrics, n (%) |
Poor |
2087 (41.5) |
1186 (55.2) |
901 (31.3) |
<0.001 |
Intermediate |
2208 (43.9) |
760 (35.3) |
1448 (50.3) |
|
|
Ideal |
731 (14.5) |
204 (9.5) |
527 (18.3) |
|
|
Biological CVH metrics, n (%) |
Poor |
2740 (54.5) |
975 (45.3) |
1765 (61.4) |
<0.001 |
Intermediate |
2069 (41.2) |
1058 (49.2) |
1011 (35.2) |
|
|
Ideal |
217 (4.3) |
117 (5.4) |
100 (3.5) |
|
Abbreviation: CVH, cardiovascular health.
ap-value is for the test of differences between men and women.
Table 3. Prevalence, awareness, treatment, and control rates of biological cardiovascular health metrics in total sample and by gender (n=5026)
Cardiovascular health metrics |
n |
Rate (95% confidence interval) (%) |
p-valuea |
||
Total sample (n=5026) |
Men (n=2150) |
Women (n=2876) |
|||
Hypertension |
|
|
|
|
|
Prevalence |
3374 |
67.1 (65.8 - 68.4) |
64.6 (62.5 - 66.6) |
69.1 (67.4 - 70.7) |
0.001 |
Awareness |
2003 |
59.4 (57.7 - 61.0) |
54.3 (51.7 - 57.0) |
62.9 (60.8 - 65.0) |
<0.001 |
Treatment |
1113 |
33.0 (31.4 -34.6) |
30.8 (28.3 - 33.2) |
34.5 (32.5 - 36.6) |
0.022 |
Control Ab |
226 |
20.3 (17.9 - 22.7) |
21.8 (17.9 - 25.7) |
19.4 (16.4 - 22.4) |
0.335 |
Control Bb |
226 |
6.7 (5.9 - 7.5) |
6.7 (5.4 - 8.0) |
6.7 (5.6 - 7.8) |
0.991 |
Diabetes |
|
|
|
|
|
Prevalence |
722 |
14.4 (13.4 - 15.3) |
11.6 (10.2 - 12.9) |
16.5 (15.1 - 17.8) |
<0.001 |
Awareness |
583 |
80.7 (77.9 - 83.6) |
72.3 (66.7 - 77.9) |
85.2 (82.0 - 88.4) |
<0.001 |
Treatment |
240 |
33.2 (29.8 - 36.7) |
32.1 (26.3 - 38.0) |
33.8 (29.6 - 38.1) |
0.645 |
Control Ab |
89 |
37.1 (30.9 - 43.2) |
33.8 (21.2 - 44.3) |
38.8 (31.1 - 46.4) |
0.450 |
Control Bb |
285 |
39.5 (35.9 - 43.1) |
32.5 (26.7 - 38.4) |
43.1 (38.7 - 47.6) |
0.006 |
High cholesterol |
|
|
|
|
|
Prevalence |
761 |
15.1 (14.2 - 16.1) |
9.8 (8.5 - 11.0) |
19.2 (17.7 - 20.6) |
<0.001 |
Awareness |
193 |
25.4 (22.3 - 28.5) |
27.1 (21.1 - 33.2) |
24.7 (21.1 - 28.3) |
0.486 |
Treatment |
262 |
34.4 (31.1 - 37.8) |
54.8 (48.0 - 61.6) |
26.7 (23.0 - 30.4) |
<0.001 |
Control Ab |
248 |
94.7(91.9 - 97.4) |
95.7 (91.9 - 99.4) |
93.9 (90.0 - 97.8) |
0.526 |
Control Bb |
248 |
32.6 (29.3 - 35.9) |
52.4 (45.6 - 59.2) |
25.1 (21.4 - 28.7) |
<0.001 |
ap-value is for the test of differences between men and women.
bControl A indicates the rate of achieving the treatment goal among people who were treated with the corresponding medication; Control B means the rate of achieving the treatment goal among people who had the corresponding cardiovascular risk factor.