Study population

In the current study, we used the data collected in the territory-wide cross-sectional Population Health Survey (PHS) conducted by the Department of Health of the Hong Kong Special Administrative Region Government in 2014–2015, which covered the land-based non-institutional population aged 15 years or above in Hong Kong, excluding foreign domestic helpers and visitors of Hong Kong. The PHS comprised two parts, a household survey for all recruited respondents and subsequently a health examination for a random subsample of eligible and consented respondents⁽²³⁾. The household survey part adopted the Frame of Quarters maintained by the Census and Statistics Department of Hong Kong as the sampling frame. The Frame of Quarters consists of the Register of Quarters and the Register of Segments, of which the former contains records of all addresses of permanent quarters (i.e., dwellings in a residential building) in built-up areas, whereas the latter contains records of area segments (i.e., small districts) in non-built-up areas. Specifically, records in the Frame of Quarters were first stratified by geographical area and type of quarters (records in the Register of Segments were sorted by geographical area only as quarters in these area segments may not have clear addresses and thus cannot be identified individually). Then, systematic replicated sampling was applied in each stratum for sample selection. Living quarters were drawn systematically to form replicates according to fixed sampling interval by making use of non-repetitive random numbers. Hence, the Frame of Quarters was divided into a large number of replicates comprising about 500 quarters each (including both permanent quarters and quarters in segments). Each replicate could be deemed as a representative sample of domestic households in Hong Kong. These replicates of living quarters were then randomly sampled. All eligible individuals aged 15 years or above in the households of selected living quarters were enumerated individually. Eventually, 12 022 individuals from 5435 domestic households were successfully recruited, representing a household response rate of 75·4 %.

Upon completing a structured questionnaire administered by trained interviewers, all respondents aged between 15 and 84 years were further invited to sign a PHS consent form of health examination. For respondents under 18 years of age, their consent forms were signed by parents or guardians. Eligible and consented respondents were randomly selected to undergo a follow-up health examination. In total, 2347 respondents aged between 15 and 84 years had completed both the household survey and the health examination. After excluding the missing data, outliers and dubious clinical readings (n 50), 2297 respondents were eventually included in the final sample for complete case analyses.

Measurements

Demographic and socio-economic characteristics were obtained using questionnaire. Specifically, marital status was classified as ‘married’ and ‘non-married’ (including never married, divorced, separated and widowed). With reference to the International Standard Classification of Education proposed by the Organisation for Economic Co-operation and Development⁽²⁴⁾, the highest attained education level was grouped into ‘primary or below’ ‘lower secondary’ ‘upper secondary’ ‘sub-degree’ (i.e., post-secondary education below degree level including technical/vocational training, diploma programmes and other non-degree certificate courses) and ‘degree or above’. The self-reported monthly household income, in Hong Kong dollars (HKD$7·8 ≈ USD$1), was categorised into ‘$0–9999’ ‘$10000–29999’ ‘$30000–49999’ and ‘≥ $50 000’.

As for lifestyle factors, smoking status was categorised into ‘currently smoking’, ‘previously smoking’ and ‘never smoking’. Based on data on the average volume and types of alcoholic beverages consumed in the 12 months preceding the survey, the consumption level of alcohol was classified as ‘0’ ‘0·1–2’ ‘2·1–4’ and ‘> 4’ alcohol units/d (1 alcohol unit = drink volume (ml) × alcohol content (% by volume) × 0·789/1000). As for the fruit and vegetable intake level, respondents were first asked about the intake frequency and then the serving on a typical day they consumed fruits and vegetables, respectively. One serving of fruit was defined as equivalent to half piece of large-sized fruit (e.g., banana) or one piece of medium-sized fruit (e.g., apple, orange and pear), whereas one serving of vegetables was defined as equivalent to a bowl of raw leafy vegetables or half a bowl of cooked vegetables. The fruit and vegetable intake level per day was estimated by taking the sum of the average daily servings of fruits and that of vegetables, and then grouped into ‘0–1·9’” ‘2–4·9’ and ‘≥ 5’ servings/d. The physical activity level of respondents was assessed using the Global Physical Activity Questionnaire developed by the WHO for physical activity surveillance⁽²⁵⁾. Information on the respondent’s physical activity participation in a typical week for work, travel between places and recreational activities, including the number of days and time spent in each setting, was collected. The average time spent across types of physical activities per week was assessed. Hence, the metabolic equivalent of task-min/week of respondents was calculated based on the analysis guide for Global Physical Activity Questionnaire⁽²⁵⁾ and then ranked by quartiles.

Regarding measurements on hypertension, diabetes and other clinical cardiometabolic risk factors, we collected data on blood pressure, blood glucose, general and abdominal obesity, lipid profiles and self-reported use of the medications and insulin therapy. During the health examination, anthropometric and blood pressure measurements, as well as blood tests for biochemical markers, were conducted by trained staff supervised by medical practitioners in designated health examination centres. Procedures of all physical and biochemical measurements complied with the WHO STEPwise approach to surveillance Manual⁽²⁶⁾. In the current study, hypertension and diabetes were regarded as the primary CMD outcomes. Hypertension was defined as systolic blood pressure ≥ 140 mmHg, and/or diastolic blood pressure ≥ 90 mmHg, and/or use of anti-hypertensive medications⁽²⁷⁾, whereas diabetes was defined as HbA_1c ≥ 6·5 %, and/or fasting plasma glucose ≥ 7 mmol/l, and/or use of insulin, and/or use of anti-diabetic medications^(28,29) . As for other clinical cardiometabolic risk factors, general obesity was defined as BMI ≥ 25 kg/m² according to the official classification of BMI adopted by the Hong Kong Government. As such a classification may not be the most up-to-date, sensitivity analyses using an alternative cut-off of BMI ≥ 27 kg/m² were performed to ensure the robustness of our results^{(Reference Barba, Cavalli-Sforza and Cutter30)}. Abdominal obesity was defined as waist-to-hip ratio ≥ 0·85 for female or ≥ 0·9 for male^{(31,Reference Alberti and Zimmet32)} . Regarding the lipid profiles, LDL-cholesterol ≥ 160 mg/dl, HDL-cholesterol < 40 mg/dl, total cholesterol ≥ 240 mg/dl and total TAG ≥ 200 mg/dl were considered as unhealthy lipid profiles according to the National Cholesterol Education Program Adult Treatment Panel III classification⁽³³⁾.

Statistical analyses

Continuous variables were reported as mean and sd, while categorical variables were reported as percentages. The crude associations of sample characteristics with education levels were tested by Mantel–Haenszel test for trend or one-way ANOVA.

As for multivariable analyses, Fig. 1 displays the conceptual framework on the separate associations of education with both hypertension and diabetes, the possible mediating roles of clinical cardiometabolic risk factors and lifestyle factors, and the potential effect modification between women and men. As the current study aimed to explore the mediating roles of clinical cardiometabolic risk factors, we focused on the indirect pathway through these clinical risk factors while adjusting for the effects of lifestyle factors and other potential confounding factors for analyses in the current study. Multiple binary logistic regressions, stratified by women and men, were first employed to examine the associations of education level with hypertension, diabetes and related clinical risk factors, controlling for demographic, socio-economic and lifestyle factors. Interaction terms between education and gender were also included to test for the potential effect modification between women and men, with P < 0·2 as the cut-off for statistical significance to avoid missing a true interaction effect due to inadequate statistical power^{(Reference Selvin34)}. Second, the associations of clinical risk factors with hypertension and diabetes were also examined. Finally, for the respective association of education with hypertension and that with diabetes, we performed two separate multiple mediation analyses according to the method proposed by Preacher and Hayes^{(Reference Preacher and Hayes35)}. The mediating roles of clinical risk factors that were significantly associated with hypertension and diabetes (as identified in the second part of analysis) were simultaneously assessed in the mediation analyses. Specifically, we estimated the indirect effects and the resultant mediation ratios through these clinical risk factors in the multivariable binary logistic regression analyses for hypertension and diabetes, with adjustments for the same set of potential confounders. All data analyses were conducted using statistical software R 3.4.0 and Stata 14. OR and 95 % CI are presented, and all statistical tests were two-tailed with a significance level of P < 0·05.

Fig. 1 Conceptual framework on the associations of education with (a) hypertension and (b) diabetes, the possible mediating roles of clinical cardiometabolic risk factors and the potential effect modification between women and men. Solid bold arrows represent main associations; solid thin arrows represent associations that were taken in account only for adjustment; dashed arrows represent effect modifications