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Urban–rural disparities in cardiovascular disease risks among middle-aged and older Chinese: two decades of urbanisation

Published online by Cambridge University Press:  30 January 2019

Nan Zhang Open the ORCID record for Nan Zhang [Opens in a new window]
Nan Zhang*
Affiliation:
Manchester Institute for Collaborative Research on Ageing (MICRA), Social Statistics, School of Social Sciences, The University of Manchester, Manchester, UK
*
Corresponding author. Email: nan.zhang-2@manchester.ac.uk
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Abstract

China has been undergoing dramatic socio-economic and demographic changes in the last few decades. The rapid growth of the ageing population will pose tremendous challenges to its public health and social welfare system. This study aims to examine how urbanisation has impacted cardiovascular disease (CVD) risks among middle-aged and older Chinese in two decades, from 1991 to 2011. Data were drawn from a nationwide longitudinal data-set of the China Health and Nutrition Survey (CHNS) (sweeps 1991, 1993, 1997, 2000, 2004, 2006, 2009 and 2011). Participants aged ⩾45 years old were included. A dynamic urbanisation index was created for each community (village or neighbourhood) based on community-level data that can reveal the heterogeneity within and across places and capture dimensions of social, economic and physical characteristics of urban living over time and space. Multi-level modelling analyses (level 1: occasions; level 2: individuals; level 3: households; level 4: communities) were performed on outcomes of CVD risks such as body mass index, waist circumference, and systolic and diastolic blood pressure. The results show upward trends in all CVD risks for both genders over 20 years of urbanisation after adjustment for socio-economic and demographic confounders. Urbanisation in China is associated with absolute increases in CVD risks over time among its middle-aged and older people, despite its contribution to relative reduction of the rural–urban gap over time. This is particularly true for women from the least urbanised areas. It is relevant to inform policy-making processes to target the most vulnerable groups of older people in China during its rapid urbanisation process. There is a possibility for policy intervention to reduce inequality during the process of China's planned urbanisation.

Keywords

urbanisationageingcardiovascular diease risksinequalityChina
Type
Article
Information
Ageing & Society , Volume 40 , Issue 7 , July 2020 , pp. 1405 - 1427
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © Cambridge University Press 2019

Introduction

China is undergoing rapid urbanisation. It will reach the same levels of urbanisation much quicker and the number of people involved in this shift will be much larger compared to other countries (McGee, Reference McGee2008), with the proportion of the urban population rising from 18 per cent (172.45 million) in 1978 to 55 per cent (749.16 million) in 2014 (National Bureau of Statistics of China, 2015). Urbanisation is associated with a range of changes in environmental and lifestyle factors that may affect individual health and wellbeing. As the pace of urbanisation accelerates, new challenges arise to characterise these environments, and to understand their positive and negative implications for health (McDade and Adair, Reference McDade and Adair2001). However, attributing diseases to specific environmental influences has proved elusive (Zhu et al., Reference Zhu, Ioannidis, Li, Jones and Martin2011). Factors beyond individual level, such as the social and physical environment, are the primary determinants of the health and wellbeing of people (Vlahov et al., Reference Vlahov, Galea, Gibble and Freudenberg2005).

Three theoretical perspectives have been proposed regarding research on urban health. The urban penalty approach argues that cities concentrate poor people and expose them to unhealthy physical and social environments. Urban sprawl focuses on the adverse health and environmental impacts of urban growth into outlying areas. These two approaches stress the negative aspects of health, and fail to consider the strengths within metropolitan areas. The third approach, ‘urban health advantage’, considers the special resources and protective effects of cities and only focuses on the positive aspects of urban living. All three perspectives are relatively static, describing health within a particular stage of urban development rather than exploring the changing processes between and within cities and their surrounding areas (Freudenberg et al., Reference Freudenberg, Galea and Vlahov2005). The impact of urbanisation on health is likely two-edged. Urbanisation is often associated with economic growth and poverty reduction. There are the benefits of ready access to health care, sanitation and secure nutrition, whilst there are also the evils of overcrowding, pollution, social deprivation, crime and stress-related illness. Some argue that urbanisation worsens the health status of the population affected, especially when health infrastructure and social security are under-developed (Moore et al., Reference Moore, Gould and Keary2003; Godfrey and Julien, Reference Godfrey and Julien2005). Therefore, whether and to what extent urbanisation is associated with the health and wellbeing of its population is an empirical question.

Unlike other countries, China's rapid urbanisation is not merely driven by spontaneous rural–urban migration, but also partly planned by the government which has maintained a bias in favour of urban residents to preserve regime stability (Ma, Reference Ma2002; Chan and Buckingham, Reference Chan and Buckingham2008). The process of China's rapid urbanisation may cause the unequal distribution of socio-economic resources and life chances among its population, thus contributing to rural–urban health inequalities (Zhang and Treiman, Reference Zhang and Treiman2013). Alongside rapid urbanisation, China is entering a stage of ‘super ageing’ (Joseph and Phillips, Reference Joseph and Phillips1999). It is predicted that China will become the world's most aged society by 2030, with its proportion of senior citizens aged 60 years or over rising from 15.2 per cent (209 million) in 2015 to 36.5 per cent (492 million) in 2050 (United Nations Department of Economic and Social Affairs, 2015). Massive internal migration (mostly taken up by the working-age population) and rapid urbanisation are likely to drive the ageing problem to be more challenging in rural than in urban China (Chen et al., Reference Chen, Dietzenbacher and Los2015): by 2030, the proportion of people aged 60 years or over in rural and urban areas will be 21.8 and 14.8 per cent, respectively (Cai and Wang, Reference Cai, Wang, Garnaut and Song2005). Urbanisation and migration have enhanced the geographical separation between adult children and their elderly parents, restricting familial social support (Joseph and Phillips, Reference Joseph and Phillips1999; Chen and Liu, Reference Chen, Liu and Uhlenberg2009). This, together with the impact of urbanisation on socio-economic structures, is likely to have significant implications for the health and wellbeing of older people in China.

Cardiovascular disease (CVD) is one of the leading causes of death in China, which is more prevalent among older people (Moran et al., Reference Moran, Gu, Zhao, Coxson, Wang, Chen, Liu, Cheng, Bibbins-Domingo and Shen2010). Rapid urbanisation and improvements in people's living standards have contributed to the increase of CVD events. An upward temporal trend in CVD risk factors (i.e. obesity, hypertension) has been observed among Chinese elderly (Yu et al., Reference Yu, Nissinen, Vartiainen, Song, Guo and Tian2000; Gordon-Larsen et al., Reference Gordon-Larsen, Wang and Popkin2014; Wang et al., Reference Wang, Ning, Yang, Lu, Tu, Jin, Zhang and Su2014) in the past few decades. Population ageing is estimated to bear two-thirds of the total disease burden in China by 2030 (Chatterji et al., Reference Chatterji, Kowal, Mathers, Naidoo, Verdes, Smith and Suzman2008), which is likely to drain its health-care and social welfare system.

Despite well-documented rural–urban inequalities among older people in China, there are few attempts to examine how these relationships have changed during the process of China's urbanisation. Most studies examining the health consequences of urbanisation employ a dichotomous urban–rural classification of individuals living in urban versus rural environments. This approach ignores the heterogeneity of experience within and across urban and rural situations, and fails to consider the specific aspects of local environments that are causally related to health outcomes (McDade and Adair, Reference McDade and Adair2001). Modern ‘rural’ areas are now experiencing factors traditionally associated with the urban environment which has blurred urban–rural distinctions (Hugo, Reference Hugo2017). This is particularly relevant due to substantial regional variations in economic development and public resources across China. Another pitfall of employing an urban–rural dichotomy is its inability to detect changes in urbanisation over time (Dahly and Adair, Reference Dahly and Adair2007). This makes it impossible to examine temporal trends and patterns of urbanisation on health outcomes among older people in China. Previous research has tended to rely on a cross-sectional study design and has failed to examine the dynamics in the health of middle-aged and older people in a rapidly urbanising society. This study will examine how the rural–urban gap in CVD risks changes over China's rapid urbanisation process. This study aims to answer two questions:

  1. (1) What is the trend in CVD risks among Chinese middle-aged and older people over the last two decades?

  2. (2) Do the trends in CVD risks change according to the degree of urbanisation?

Methods

Study design and participants

Data were drawn from the CHNS, an on-going open-cohort study that employs a multi-stage, random-clustered sampling process to draw a sample of about 4,400 households with a total of about 19,000 participants from over 200 communities or neighbourhoods in nine provinces, with the first round conducted in 1989. The CHNS covers nine provinces that vary substantially in geography, economic development, public resources and health indicators. The design, sampling and response rates are reported elsewhere (Popkin et al., Reference Popkin, Du, Zhai and Zhang2009). The sample began with eight provinces (Liaoning, Jiangsu, Shandong, Henan, Hubei, Hunan, Guangxi and Guizhou) and added a ninth, Heilongjiang, in 1997, and three autonomous cities, Beijing, Shanghai and Chongqing, in 2011. The nine provinces were included and the three autonomous cities in 2011 were excluded from the analyses. This study used data from 1991, 1993, 1997, 2000, 2004, 2006, 2009 and 2011. In 1989, health data were only collected from pre-schoolers and adults aged 20–45 and therefore were not included in this study. Middle-aged and elder people ⩾45 years were included and underweight people (N = 2,379) were excluded from analyses.

The institutional review committees from the University of North Carolina at Chapel Hill and the National Institute for Nutrition and Food Safety, China Centre for Disease Control and Prevention approved the survey protocols and instruments and the process for obtaining informed consent for the survey. All participants and/or their parents/guardians provided written informed consents for their participation in the survey.

Outcomes

CVD risks included body mass index (BMI), waist circumference (WC), systolic blood pressure (SBP) and diastolic blood pressure (DBP).

Anthropometric data were recorded for each individual within the household, as measured by health professionals. Height was measured without shoes to the nearest 0.1 centimetres (cm) using a portable SECA stadiometer; weight was measured without shoes and in light clothing to the nearest 0.1 kilogram (kg) on a calibrated beam balance. BMI (kg/metre (m)2) was calculated as weight (kg) divided by height squared (m2). Obesity was defined as BMI ⩾ 28 for men and women (Zhou, Reference Zhou2002). WC (cm) was measured using an non-elastic tape at a point midway between the lowest rib margin and the iliac crest in a horizontal plane (Tuan et al., Reference Tuan, Adair, Stevens and Popkin2010). Abdominal obesity was defined as WC ⩾ 90 cm for men and WC ⩾ 80 cm for women (World Health Organization, 1997).

SBP and DBP were measured on the right arm, using mercury sphygmomanometers with appropriate cuff sizes (Blumenthal et al., Reference Blumenthal, Epps, Heavenrich, Lauer, Lieberman, Mirkin, Mitchell, Boyar, O'Hare and McFate1977). Measures were collected in triplicate after a ten-minute seated rest and the mean of the three measurements was used in analyses. Hypertension was defined as an average SBP ⩾ 140 millimetres of mercury (mmHg) and/or an average DBP ⩾ 90 mmHg (Gu et al., Reference Gu, Reynolds, Wu, Chen, Duan, Muntner, Huang, Reynolds, Su, Whelton and He2002).

Exposure

A dynamic measure, the urbanisation index, was created based on in-depth community contextual measures that capture major dimensions of modernisation across all 288 communities currently in the CHNS sample. The standardised, validated measure captures the changes in 12 dimensions: population density, economic activity, traditional markets, modern markets, transportation infrastructure, sanitation, communications, housing, education, diversity, health infrastructure and social services (Jones-Smith and Popkin, Reference Jones-Smith and Popkin2010). Each domain was scored from 0 to 10, weighted equally and then added together scoring up to 120. Each is based on numerous measures relevant to each dimension (Zhang et al., Reference Zhang, Zhai, Du and Popkin2014) and can distinguish features of urban–rural places. This measure has been validated for content validity, reliability (α ⩾ 0.85) and stability (r ⩾ 0.90) (Jones-Smith and Popkin, Reference Jones-Smith and Popkin2010). Also, a fixed measure, Hukou, which officially segregates China's population into ‘urban residents’ born in urban areas and ‘rural residents or peasants’ born in rural areas and is an important structural driver of inequality, was also examined.

Covariates

Covariates included age (centred at 45 years), quadratic term of age, education (completed years of formal education in regular school), log transformation of household income per capita (inflated to 2011) and survey years (1991, 1993, 1997, 2000, 2004, 2006, 2009 and 2011).

Statistical analysis

To account for the hierarchical nature of the CHNS, where multiple occasions (level 1) are nested within individuals (level 2) within households (level 3) clustered in villages/communities (level 4), multi-level modelling analyses were constructed within Stata/SE 13 (StataCorp, 2013) to correct for non-independence of observations due to geographic clustering and repeated observations of individuals. A multi-level approach also allows examination of neighbourhood/contextual effects given the key exposure – urbanisation – lies at the community level. The log likelihood ratio test was used to determine the preferred model among nested models for continuous outcomes including BMI, WC, SBP and DBP and the Wald test was used to test statistical significance in multi-level logistic regressions for categorical outcomes including obesity, abdominal obesity and hypertension. The better fit of the models is associated with lower values in −2 log likelihood statistics. Nested models are compared through deviance statistics (difference in −2 log likelihood) over the difference in degrees of freedom using an ordinary chi-square distribution. A significant difference between two nested models indicates that the models with the lowest value have a better fit to the data. Given gender differences in potential CVD risk factors and traditional gender roles in China, all analyses were stratified by sex.

To examine if there are any significant trends in outcomes, first a quadratic function of age and survey years was fitted (Model 1). This was followed by adjustment for urbanisation (Hukou or urbanisation index) to see if urbanisation has an independent impact on outcomes (Model 2). In order to examine if urbanisation impacts change over time, adjustment was made for the interaction between survey year and urbanisation (Model 3). All models were adjusted for family socio-economic circumstances in terms of education and household income per capita to remove potential confounding effects. Also examined were the relationships between non-linear terms of the urbanisation index and outcomes, and non-linear terms were not significant (not reported here).

To enable an easier interpretation, time trends were plotted so that they can be interpreted visually. This was done by calculating predicted values of selected outcomes (obesity, abdominal obesity and hypertension) under different conditions of urbanisation, including the most urbanised areas (the top 20th percentile) and the least urbanised areas (the bottom 20th percentile), and showing the predicted relationship between outcome variables and survey year at different levels of urbanisation. These plots can offer an overall picture of trends in urban–rural inequalities in bio-markers among Chinese middle-aged and elder people over two decades.

Results

Table 1 summarises the socio-economic characteristics and CVD risks of middle-aged and older people aged ⩾45 across gender and survey years: the CHNS. The two decades from 1991 to 2011 saw persistent improvements in socio-economic status (education and household income per capita) for both men and women regardless of their Hukou status. A clear rural–urban gap was observed for both men and women: urban people tend to fare better in terms of socio-economic circumstances and to be more prone to CVD risks compared with their rural counterparts. Obesity, abdominal obesity in particular, increased dramatically among rural people, especially among women. Blood pressure and hypertension appeared to increase among rural people and did not show a consistent pattern among their urban peers.

Table 1. General characteristics of middle-aged and older Chinese ⩾45 years by gender over time, China Health and Nutrition Survey 1991–2011

Notes: Index: urbanisation index. cm: centimetre. kg: kilogram. m: metre. BMI: body mass index. mmHg: millimetres of mercury.

Tables 2–4 present trends in CVD risks among middle-aged and older Chinese ⩾45 years during China's urbanisation process. The positive time trends were observed on all CVD risks for both genders after adjustment for socio-economic confounders (Model 1), and persisted regardless of urbanisation levels (Model 2). Higher levels of urbanisation appear to be associated with an increased risk of CVD and such impacts seem to be independent of individual socio-economic positions (Model 2). Significant negative interaction effects (between the urbanisation index and survey years) were observed on all CVD risks for both genders: the positive time trends tend to decrease as the areas become more urbanised (Model 3).

Table 2. Trends in the influence of urbanisation on body mass index (BMI) and obesity of middle-aged and older Chinese ⩾45 years, China Health and Nutrition Survey 1991–2011

Notes: CI: confidence interval. Index: urbanisation index. Year was centred at 1991. All models adjusted for age (centred at 45 years old), quadratic term of age, education (completed years of formal education in regular school) and log transformation of household income per capita.

Significance levels: *p < 0.05, **p < 0.01, ***p < 0.001.

Table 3. Trends in the influence of urbanisation on waist circumference and abdominal obesity of middle-aged and older Chinese ⩾45 years, China Health and Nutrition Survey 1991–2011

Notes: CI: confidence interval. Index: urbanisation index. Year was centred at 1991. All models adjusted for age (centred at 45 years old), quadratic term of age, education (completed years of formal education in regular school) and log transformation of household income per capita.

Significance levels: **p < 0.01, ***p < 0.001.

Table 4. Trends in the influence of urbanisation on systolic blood pressure, diastolic blood pressure and hypertension of middle-aged and older Chinese ⩾45 years, China Health and Nutrition Survey 1991–2011

Notes: CI: confidence interval. Index: urbanisation index. Year was centred at 1991. All models adjusted for age (centred at 45 years old), quadratic term of age, education (completed years of formal education in regular school) and log transformation of household income per capita.

Significance levels: *p < 0.05, **p < 0.01, ***p < 0.001.

Figures 1 and 2 plot the time trends of the probability of obesity for the most urbanised and the least urbanised areas for males and females aged ⩾45 years. For both overall obesity and abdominal obesity, an upward trend was observed for both men and women regardless of levels of urbanisation. For males, those from the most urbanised areas appear to be more likely to be obese than those from the least urbanised areas. The gap between the two groups seems stable over two decades. However, the patterns appear to be more complex for females than for males. The risk of female obesity increased rapidly in particular for those from the least urbanised areas over time. The gap between two groups appears to shrink over two decades. This may suggest rapid urbanisation in China may help reduce inequality in obesity among women but may have limited impact on men.

Figure 1. Trends in the influence of urbanisation on the probabilities of obesity among males (a) and females (b) aged ⩾45 years in China.

Figure 3 illustrates the time trends of the probability of hypertension for men and women from the most urbanised and the least urbanised areas separately. The disparities between two urbanised groups appear to decrease and further cease: the probability of hypertension for those from the highest urbanised areas appears to decline while that of their least urbanised peers continues to increase. For women, the gap continued to converge till 2008 and after that the gap widened, whereas the least urbanised areas seem to override the most urbanised areas. This may suggest that older people, especially women from the less urbanised/rural areas, may be more vulnerable to China's urbanisation process in terms of hypertension risk. Results of the time trends of Hukou, a rural–urban fixed measure of urbanisation, on CVD risks showed similar patterns and are reported in the online supplementary material. However, the use of the urbanisation index enabled us to explore the full spectrum of urbanisation levels and its association with time trends of CVD risks.

Discussion

This study has drawn on a nationwide longitudinal data-set – the CHNS – to examine time trends in related CVD risks among middle-aged and older people aged ⩾45 years old in China by considering an important wider contextual factor – urbanisation. Chinese middle-aged and older people have been experiencing an upward trend in CVD risks in the last two decades. An upward trend in CVD risks (except for blood pressure) was observed over two decades of urbanisation, especially among women. However, urbanisation may reduce inequality among women between more urbanised areas and less urbanised areas. This study has contributed to current debates on rural–urban inequalities in the health and wellbeing of older people in China at least in two ways. First, the use of multi-level modelling techniques in this study allows disentangling of the effects due to individual, family and neighbourhood characteristics, which is methodologically more robust. Another advantage of this study is, unlike previous studies mostly drawing on the crude classification of the rural–urban dichotomy which is prone to misclassification error, the urbanisation measure used has encompassed dimensions beyond population size and density. It has captured some important dimensions of social, economic and physical characteristics of urban living over time and space (Zhang et al., Reference Zhang, Zhai, Du and Popkin2014).

After adjustment for relevant confounders at the individual and household levels, positive time trends in all CVD risks (BMI, WC, SBP and DBP) among middle-aged and older people over two decades were found. The prevalence of obesity and hypertension in general increases constantly over time from 1991 to 2011. This is consistent with previous studies that found an increased prevalence of obesity and hypertension among elderly Chinese people (Yu et al., Reference Yu, Nissinen, Vartiainen, Song, Guo and Tian2000; Gordon-Larsen et al., Reference Gordon-Larsen, Wang and Popkin2014; Wang et al., Reference Wang, Ning, Yang, Lu, Tu, Jin, Zhang and Su2014).

This study suggested that urbanisation has contributed to an increased risk of CVD among the middle-aged and elderly in China. It was found that urban residents tend to have higher a prevalence of obesity and hypertension than their rural counterparts. The gap shrinks over time, especially for women. Urban residents in China tend to have higher obesity rates than rural residents due to the potentially negative influence of urban living regarding unhealthy diets and lifestyles (physical inactivity and increased access to high-fat and energy-dense diets), as well as exposure to obesogenic environments (Popkin, Reference Popkin1999; Zhai et al., Reference Zhai, Du, Wang, Zhang, Du and Popkin2014; Li et al., Reference Li, Song, Lin, Dixon, Zhang and Ye2016). Westernised diets are associated with an increased likelihood of obesity, hypertension and the metabolic syndrome (Sun et al., Reference Sun, Buys and Hills2014). In recent years, the consumption of a traditional diet has decreased and that of high-energy food has increased substantially at low- and middle-income levels, which has shifted the risk of obesity from high-income groups to middle- and low-income groups and poor and rural areas (Dearth-Wesley et al., Reference Dearth-Wesley, Wang and Popkin2007). Moreover, those from rural and/or less-urbanised areas tend to have less favourable health services compared to those from urban or more urbanised areas, including access to medical facilities, the availability of medical insurance and the quality of health services (Hou, Reference Hou2008). This may cause under-diagnosis and under-treatment of hypertension (Hou, Reference Hou2008; Song et al., Reference Song, Liang, Yan, Sun, Cai, Jiang and Qiu2014), which may contribute to rural residents catching up with urban residents in terms of CVD risks. It is important to examine potential contributing factors such as lifestyles and health-care services more closely, which may explain rural–urban disparities in CVD of older people in China.

Substantial gender differences in CVD risks among middle-aged and older people in China were observed, despite indirect comparisons. In general women tend to have a higher prevalence of abdominal obesity than men, which is consistent with a previous study (Song et al., Reference Song, X, C, JX, K and Wang2018). One possible explanation might be because although men were more likely to adopt an unhealthy lifestyle such as smoking and drinking, women were more likely to be physically inactive than men at older age (Song et al., Reference Song, Liang, Yan, Sun, Cai, Jiang and Qiu2014). In general, women from the rural or less-urbanised areas appear to be worse off in CVD risks over two decades of urbanisation than rural males (Wang et al., Reference Wang, Ning, Yang, Lu, Tu, Jin, Zhang and Su2014). Rural women tend to live longer and are more likely to be widowed than rural men (Zeng and George, Reference Zeng, George, Dannefer and Phillipson2010). Massive internal migration (mostly taken up by the working-age population) and rapid urbanisation are likely to drive the ageing problem to be more challenging in rural than in urban China (Chen et al., Reference Chen, Dietzenbacher and Los2015). Due to lack of institutional social welfare and support, they are more likely to rely on their families compared to their urban peers. However, rapid urbanisation and migration have enhanced the geographical separation between adult children and their elderly parents, restricting familial social support (Joseph and Phillips, Reference Joseph and Phillips1999; Chen and Liu, Reference Chen, Liu and Uhlenberg2009). This is likely to have significant implications for CVD profiles of older women from the less-urbanised communities in China.

Figures 1–3 also suggest that over two decades, the gap between women from the rural or least urbanised areas and those from the urban or most urbanised areas narrow much more rapidly than their male counterparts. This may suggest that the urbanisation process may help reduce gender inequality in CVD risks over time. One possible explanation is that urbanisation is associated with improved economic circumstances and better access to health-care services (Li and Wu, Reference Li and Wu2016), whereas men tend to be less likely to use health-care services than their female counterparts (Galdas et al., Reference Galdas, Cheater and Marshall2005). This may persist as people age. Therefore, it is possible that, in China, men at older age may not take advantage of urbanisation as much as women. Previous studies that have examined this among older people in China have not been found. Future studies are needed to further elucidate pathways through which urbanisation contributes to reducing gender inequality in China.

Figure 2. Trends in the influence of urbanisation on the probabilities of abdominal obesity among males (a) and females (b) aged ⩾45 years in China.

Figure 3. Trends in the influence of urbanisation on the probabilities of hypertension among males (a) and females (b) aged ⩾45 years in China.

Limitations

Several methodological limitations warrant cautious interpretation of the findings. The first concerns the measure of urbanisation. Urbanisation is a complex phenomenon that involves social, economic and environmental factors that are exogenous to the individual (Vlahov et al., Reference Vlahov, Galea, Gibble and Freudenberg2005; Smith and Rappaport, Reference Smith and Rappaport2009). Although the classification of urbanisation used has captured some important dimensions of social, economic and physical characteristics of urban living over time and space (Zhang et al., Reference Zhang, Zhai, Du and Popkin2014), there are still other unobserved facets in relation to the urban environment that matter to older people's health and wellbeing, such as pollution (Baumgartner et al., Reference Baumgartner, Schauer, Ezzati, Lu, Cheng, Patz and Bautista2011). For example, environmental risk factors, in particular air and water pollution, are one of the major contributors to morbidity and mortality in China (Li et al., Reference Li, Song, Lin, Dixon, Zhang and Ye2016). Future studies may benefit by collecting a wide array of data on different dimensions of urbanisation in order to disentangle causal links between urbanisation and outcomes. Also, some confounders such as unhealthy diets and lifestyles as mediating factors that operate from urbanisation to CVD risk were not included in this study because disentangling pathways is beyond the focus of this study. Moreover, one key limitation in the CHNS, as in any longitudinal data-set, is missing data and sample attrition. This study only included complete cases and this may lead to biased results.

The different mechanisms through which urbanisation affects CVD risks among middle-aged and older people in China could not be distinguished. The pathways can be complex and multi-factorial. Freudenberg et al. (Reference Freudenberg, Galea and Vlahov2005) proposed an alternative and comprehensive approach that should incorporate and integrate the penalty and sprawl concepts as well as consider other features of living in cities that influence health. Dimensions of urban living conditions include the physical environment, the social environment, health and social services systems, and the characteristics of urban populations (i.e. behaviours, beliefs and demographics) (Freudenberg et al., Reference Freudenberg, Galea and Vlahov2005). Future studies may benefit by further exploring and identifying modifiable risk factors and pathways that can prevent avoidable health inequalities.

One important pathway is through improved household economic circumstances. A growing body of research has examined the changing nature of income or wealth inequality in China during its urbanisation in the last few decades. It is hypothesised that during the process of urbanisation, while more people move from the lower-income rural sector to the higher-income urban sector, the overall income inequality will first increase then decrease, following an inverse U-shaped curve (Kuznets, Reference Kuznets1955). China is believed to have already passed the turning point, therefore urbanisation should help reduce income inequality (Kanbur, Reference Kanbur2014). Urbanisation in China has significantly reduced both poverty of rural residents and migrant workers and, consequently, has contributed to narrowing down the rural–urban income gap. It may, however, contribute to urban poverty due to the competition between migrant workers and urban workers in urban labour markets and the failure of the government's anti-poverty policies in urban settings (Zhang, Reference Zhang2016). Despite an immediate alleviating effect on income inequality generally during post-reform, urbanisation in China seems to have a lagged aggravating effect on income inequality whereas neglecting the social dimension of urbanisation may further cause a long-term economic and social segregation such as the rural–urban gap and the persistent marginalisation of rural migrants (Chen et al., Reference Chen, Glasmeier, Zhang and Shao2016). Future studies are needed to further distinguish heterogeneities among social groups of older people and their distinctive socio-economic circumstances.

Conclusion

This study provides an overall picture of time trends of CVD risks among Chinese middle-aged and older people and how it changes with urbanisation over the last two decades. The rapid growth of the ageing population will pose tremendous challenges to the public health and social welfare system in China. The findings may provide a sound evidence basis to inform decision-making processes in relation to tackling health and welfare inequalities among older people in China by targeting the most vulnerable groups. There is a possibility for policy intervention to reduce inequality during the process of China's planned urbanisation.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0144686X18001794.

Data

This research uses data from China Health and Nutrition Survey (CHNS). The National Institute for Nutrition and Health, China Center for Disease Control and Prevention, Carolina Population Center (P2C HD050924, T32 HD007168), the University of North Carolina at Chapel Hill, the National Institutes of Health (NIH) (R01-HD30880, DK056350, R24 HD050924, R01-HD38700) and the NIH Fogarty International Center (D43 TW009077, D43 TW007709) supported the CHNS data collection and analysis files from 1989 to 2015 and future surveys. The China–Japan Friendship Hospital, Ministry of Health supported CHNS 2009, the Chinese National Human Genome Center at Shanghai has supported the CHNS since 2009 and the Beijing Municipal Center for Disease Prevention and Control has supported the CHNS since 2011.

Author ORCIDs

Nan Zhang, 0000-0002-8032-275X.

Financial support

This work was supported by the UK Economic and Social Research Council Global Challenge Research Fund Fellowship (grant number ES/P009824/1) and a Hallsworth Research Fellowship.

Conflict of interest

The author declares no conflicts of interest.

Ethical standards

The institutional review committees from the University of North Carolina at Chapel Hill and the National Institute for Nutrition and Food Safety, China Centre for Disease Control and Prevention approved the survey protocols and instruments and the process for obtaining informed consent for the survey.

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Table 1. General characteristics of middle-aged and older Chinese ⩾45 years by gender over time, China Health and Nutrition Survey 1991–2011

Figure 1

Table 2. Trends in the influence of urbanisation on body mass index (BMI) and obesity of middle-aged and older Chinese ⩾45 years, China Health and Nutrition Survey 1991–2011

Figure 2

Table 3. Trends in the influence of urbanisation on waist circumference and abdominal obesity of middle-aged and older Chinese ⩾45 years, China Health and Nutrition Survey 1991–2011

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Table 4. Trends in the influence of urbanisation on systolic blood pressure, diastolic blood pressure and hypertension of middle-aged and older Chinese ⩾45 years, China Health and Nutrition Survey 1991–2011

Figure 4

Figure 1. Trends in the influence of urbanisation on the probabilities of obesity among males (a) and females (b) aged ⩾45 years in China.

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Figure 2. Trends in the influence of urbanisation on the probabilities of abdominal obesity among males (a) and females (b) aged ⩾45 years in China.

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Figure 3. Trends in the influence of urbanisation on the probabilities of hypertension among males (a) and females (b) aged ⩾45 years in China.

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