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Prediction of hypertension by different anthropometric indices in adults: the change in estimate approach

Published online by Cambridge University Press:  17 September 2009

Nguyen T Tuan
Affiliation:
Department of Nutrition, University of North Carolina, Chapel Hill, NC, USA Carolina Population Center, University of North Carolina, 123 West Franklin Street, Chapel Hill, NC 27516-3997, USA
Linda S Adair
Affiliation:
Department of Nutrition, University of North Carolina, Chapel Hill, NC, USA Carolina Population Center, University of North Carolina, 123 West Franklin Street, Chapel Hill, NC 27516-3997, USA
June Stevens
Affiliation:
Department of Nutrition, University of North Carolina, Chapel Hill, NC, USA Department of Epidemiology, University of North Carolina, Chapel Hill, NC, USA
Barry M Popkin*
Affiliation:
Department of Nutrition, University of North Carolina, Chapel Hill, NC, USA Carolina Population Center, University of North Carolina, 123 West Franklin Street, Chapel Hill, NC 27516-3997, USA
*
*Corresponding author: Email [email protected]
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Abstract

Objective

To examine the relative contribution for the prediction of hypertension by waist circumference (WC), waist:stature ratio (WSR) or waist:hip ratio (WHR) with that by BMI, to ascertain if WC, WSR or WHR enhances the prediction of hypertension by BMI.

Design

Population-based, cross-sectional study. A change of ≥10 % in the prevalence ratio of BMI (PR) or the area under the receiver-operating characteristic curve (AUC) when WC, WSR or WHR was added to a model with BMI was used as the criterion for significant contribution to the prediction of hypertension by BMI. For greater contributions (≥10 %) these waist measures were considered as better predictors.

Setting

Nine provinces in China.

Subjects

Chinese adults aged 18 to 65 years (n 7336) who participated in the 2004 China Health and Nutrition Survey.

Results

The prevalence of hypertension (17 % and 23 % for women and men, respectively) was significantly related to increased BMI, WC, WSR and WHR (P for trend <0·001). Although there was a better model fit when WC, WSR or WHR was added to a model with BMI (P < 0·05; likelihood ratio test), the changes in PR and AUC were <10 % and <5 %, respectively. The sex-specific AUC for the prediction of hypertension by BMI (of 0·7–0·8) was similar to that by WC, WSR or WHR.

Conclusions

The waist indices do not perform better than BMI or markedly enhance the prediction of increased hypertension risk by BMI in Chinese adults.

Type
Research paper
Copyright
Copyright © The Authors 2009

Anthropometric indicators for body fat are widely used to predict increased chronic disease risk at the individual and population level. Compared with BMI, which is a good indicator for body fatness in adults at the population level, waist circumference (WC), waist:stature ratio (WSR) and waist:hip ratio (WHR) provide additional information about central fat distribution(Reference Gibson1, Reference Klein, Allison, Heymsfield, Kelley, Leibel, Nonas and Kahn2). Studies aimed at determining whether WC, WHR and WSR predict hypertension better than BMI or add to the prediction of hypertension have shown controversial results in both Western(Reference Visscher, Seidell, Molarius, van der Kuip, Hofman and Witteman3Reference Zhu, Wang, Heshka, Heo, Faith and Heymsfield5) and Asian populations(Reference Ho, Chen, Woo, Leung, Lam and Janus6Reference Wildman, Gu, Reynolds, Duan, Wu and He12). As a criterion for judging predictions of alternative indicators these studies used a larger point estimate, a P value <0·05 or a non-overlap of 95 % confidence intervals. Because P values and 95 % confidence intervals are driven by both the magnitude of effect and the sample size(Reference Weinberg13, Reference Rothman, Greenland and Lash14), different conclusions would result from different sample sizes or BMI distributions.

The present study undertook a comparison of the predictive ability of these alternative indicators as they relate to Chinese adults. We utilized two criteria that are less affected by sample size, the difference in prevalence ratio and the area under the receiver-operating characteristic curve(Reference Greenland and Rothman15, Reference Zweig and Campbell16), to: (i) compare the prediction of hypertension by WC, WSR or WHR with that by BMI; and (ii) determine if WC, WSR or WHR enhances the prediction of hypertension by BMI in 18- to 65-year-old Chinese adults.

Methods

Study sample

We used data from the China Health and Nutrition Survey (CHNS) conducted in 2004 with a representative sample drawn from nine provinces in China (Guangxi, Guizhou, Heilongjiang, Henan, Hubei, Hunan, Jiangsu, Liaoning and Shandong). This sample was diverse, with variation found in a wide-ranging set of socio-economic factors (income, employment, education and modernization) and other related health, nutritional and demographic measures(17, Reference Popkin, Paeratakul, Zhai and Ge18). Of the 8258 participants aged 18 to 65 years who were men, non-pregnant or non-lactating women, 7336 (89 %) had complete and plausible measurements of weight, height, WC, hip circumference (HC) and blood pressure (e.g. BMI of 15–35 kg/m2, weight of 30–150 kg, height of 130–190 cm, WC of 45–150 cm, HC of 55–155 cm, WHR of 0·6–1·1, difference between systolic and diastolic blood pressure ≥10 mmHg). We only included 18- to 65-year-old adults, non-pregnant and non-lactating women because adolescents, the elderly, and pregnant or lactating women require different BMI and WC cut-offs(19). The exclusion of participants with extreme values in anthropometric measurements and blood pressure helped to increase the estimate precision without changing the overall results.

Measurements

Three blood pressure measurements were taken in a seated position and on the right arm by trained health workers who followed a standardized procedure using regularly calibrated mercury sphygmomanometers with appropriate-sized cuffs. Systolic blood pressure was measured at the first appearance of a pulse sound (Korotkoff phase 1) and diastolic blood pressure at the disappearance of the pulse sound (Korotkoff phase 5). Three measurements of systolic or diastolic blood pressure were averaged to reduce the effect of measurement error. Hypertension was defined as systolic blood pressure ≥140 mm Hg, diastolic blood pressure ≥90 mm Hg or being previously diagnosed by a doctor(Reference Chobanian, Bakris and Black20). The definition of hypertension was not based on the use of an antihypertensive medication because, in the present sample, a small proportion of Chinese adults were diagnosed (<7 %) or treated (<5 %) with an antihypertensive medication and none used an antihypertensive medication without being diagnosed by a doctor. Moreover, sensitivity analysis showed that incorporating these measures produced similar findings.

BMI was calculated based on weight and height measured by trained health workers who followed standardized procedures using regularly calibrated equipment (SECA 880 scales and SECA 206 wall-mounted metal tapes). The health workers used a non-elastic tape to measure WC at a point midway between the lowest rib and the iliac crest in a horizontal plane and HC at the point yielding the maximum circumference over the buttocks(17, Reference Popkin, Paeratakul, Zhai and Ge18). WSR (WC/height) and WHR (WC/HC) were calculated based on the measured WC, height and HC. Covariates such as age, sex, smoking habits, alcohol consumption and place of residence were collected by direct interviews.

Statistical analysis

We used Poisson regression models to examine the association between BMI and hypertension. Potential confounding factors, such as age (centred at the mean age of 45 years), sex, smoking habits (dichotomized to never smoker or ever smoker), alcohol consumption (dichotomized to current drinker or non-drinker) and place of residence (urban or rural), were also taken into account in regression models. A covariate was considered as an effect measure modifier if its interaction term with BMI in regression models had a P value of <0·15 (χ 2 test) or as a confounder if it caused a change in prevalence ratios of BMI (PR) of ≥10 %(Reference Greenland and Rothman15). Based on these criteria, age was the only effect measure modifier and there were no confounders. To make our results comparable with those of other studies, we stratified our analyses by sex in crude, age-adjusted and age-specific models. BMI, WC, WSR and WHR were kept in continuous scale to maximize the power of statistical tests.

The receiver-operating characteristic (ROC) curve is an analytical approach to define the highest combination of sensitivity and specificity of a screening test. The approach has been widely used to determine a cut-off point for decision making (e.g. having a disease or not) in both public health and clinical settings(Reference Ho, Lam and Janus7, Reference Lin, Lee, Chen, Lo, Hsia, Liu, Lin, Shau and Huang10, Reference Zweig and Campbell16). The most common measurement to quantify the performance of a screening test is the area under the ROC curve (AUC), which shows the ability of a test to correctly classify those with and without the disease. For example, an AUC value of 0·75 indicates that, 75 % of the time, a randomly selected individual from the diseased group has a test value larger than that for a randomly selected individual from the non-diseased group. AUC values range from 0·5 (no prediction) to 1·0 (perfect prediction). The AUC values are usually used as criteria to compare overall performances of different screening tests(Reference Zweig and Campbell16). In the current study, AUC values were estimated by using logistic regression models.

To determine if the inclusion of WC, WSR or WHR improved the prediction of hypertension by BMI, we estimated the change in sex-specific PR (from Poisson regression models) and sex-specific AUC (from logistic regression models) between a model with BMI + WC, BMI + WSR or BMI + WHR and a model with BMI alone. A change in PR or AUC of ≥10 % was used as a criterion for a significant contribution of WC, WSR or WHR to the prediction of hypertension by BMI. We separately compared sex-specific AUC between a model with WC, WSR or WHR and a model with BMI to examine if any was better than BMI in predicting hypertension; an increase of ≥10 % in AUC was used as a criterion for a superior prediction. We used the criterion of ≥10 % because it is arbitrarily used to determine a notable confounding factor(Reference Greenland and Rothman15).

To facilitate the comparison with previous studies that use P value as a decision criterion, we compared the fit of a model with BMI with that of a model with BMI + WC, BMI + WSR or BMI + WHR. A P value of <0·05 (likelihood ratio test) was used as the criterion for a significant increase in model fit. In addition, independent t tests (P value <0·05) were used to compare PR of BMI from different regression models (e.g. models hypertension = BMI + WC v. hypertension = BMI). We did not adjust for the cluster effects from the CHNS because the adjustment did not affect point estimates of PR or AUC, which were used to estimate percentage change in PR or AUC. To evaluate if these findings were consistent at different BMI levels, we performed similar analyses for participants with BMI < 23 kg/m2 and BMI ≥ 23 kg/m2 (data are presented in Supplementary tables 1 and 2). All analyses were performed using the STATA statistical software package version 9·2 (Stata Inc., College Station, TX, USA).

Role of the funding sources and ethical considerations

The authors had full access to all of the data in the study and take responsibility for the integrity of the data and the accuracy of the data analysis. The sponsors were not involved in the study design, the collection, analysis or interpretation of the data, the writing of the manuscript, or the decision to submit the manuscript for publication. Written informed consent was obtained from each participant for each CHNS round. We certify that all applicable institutional and governmental regulations concerning the ethical use of human volunteers were followed during this research. The relevant Institutional Review Boards have reviewed and approved the study.

Results

The crude prevalence of hypertension among men of 23·0 % (95 % CI 21·6, 24·4 %) was higher than that among women (16·8 %; 95 % CI 15·6, 18·0 %; P < 0·001). The mean systolic and diastolic blood pressures were higher among men (122 and 80 mmHg, respectively) compared with women (118 and 77 mmHg; P < 0·001). Only a small proportion of the Chinese adults was diagnosed or treated with any antihypertensive medications (about 5 %). A small proportion of hypertensive participants, identified by measured blood pressures, was diagnosed by a doctor (35 %) or treated with an antihypertensive medication (25 %). Men and women had similar mean (23 kg/m2) and distribution of BMI. Men had higher means of WC, HC and WHR, but smaller mean WSR compared with women. The proportions of Chinese men who were smokers (58·8 %) and alcohol drinkers (62·3 %) were much higher than those of women (Table 1).

Table 1 CharacteristicsFootnote of the 18- to 65-year-old Chinese participantsFootnote

WC, waist circumference; HC, hip circumference; WHR, waist:hip ratio; WSR, waist:stature ratio.

Significantly different compared with women (independent t test for continuous variables or χ 2 test for categorical variables): *P < 0·001.

Values are means or percentages with 95 % confidence intervals.

The samples included participants who were 18- to 65-year-old men and women (not pregnant or lactating), for whom measurements of anthropometric indices and blood pressure were complete and plausible (e.g. BMI of 15–35 kg/m2, weight of 30–150 kg, height of 130–190 cm, WC of 45–150 cm, HC of 55–155 cm, WHR of 0·6–1·1, difference between systolic and diastolic blood pressure ≥10 mmHg).

§ Hypertension was defined as systolic blood pressure ≥140 mmHg, diastolic blood pressure ≥90 mmHg or being diagnosed by a doctor.

|| Hypertension diagnosed: proportion of the population that was diagnosed as being hypertensive by a doctor.

Use anti-hypertensive medication: proportion of the population that used any antihypertensive medications.

There was a significant trend of increased prevalence of hypertension with an increase in BMI, WC, WSR or WHR (P for trend <0·001) in both men and women (Fig. 1).

Fig. 1 Prevalence and 95 % CI of hypertension by levels of (a) BMI, (b) waist circumference (WC) and (c) waist:stature ratio (WSR). Hypertension was defined as systolic blood pressure ≥140 mmHg, diastolic blood pressure ≥90 mmHg or being diagnosed by a doctor. The samples included participants who were 18- to 65-year-old men (█, n 3542) and women (, not pregnant or lactating; n 3794), for whom measurements of anthropometric indices and blood pressure were complete and plausible (e.g. BMI of 15–35 kg/m2, weight of 30–150 kg, height of 130–190 cm, WC of 45–150 cm, hip circumference of 55–155 cm, waist:hip ratio of 0·6–1·1, difference between systolic and diastolic blood pressure ≥10 mmHg). P for trend <0·001 for all

On average, each unit increase in BMI was associated with an 18 % and 14 % increase in PR for hypertension in women and men, respectively (P < 0·001; crude models). There was about a 15 % increase in PR associated with each unit increase in BMI in age-adjusted and age-specific models (P < 0·001). Although there was an increase in model fit when adding WC, WSR or WHR to a model with BMI (P < 0·05 in almost all of the models; likelihood ratio test), the changes in PR were <10 % in the crude models and <5 % in the age-adjusted and age-specific models (Table 2). The changes in PR increased slightly (<10 % except for WSR in the crude model for women) among participants with BMI < 23 kg/m2 (Supplementary table 1).

Table 2 Sex-specific prevalence ratios of BMI for hypertensionFootnote ,Footnote

PR, prevalence ratio of BMI; WC, waist circumference; WHR, waist:hip ratio; WSR, waist:stature ratio.

Significantly different compared with PR of a model with BMI (independent t test): *P < 0·05.

Hypertension was defined as systolic blood pressure ≥140 mmHg, diastolic blood pressure ≥90 mmHg or being diagnosed by a doctor.

The samples included participants who were 18- to 65-year-old men and women (not pregnant or lactating), for whom measurements of anthropometric indices and blood pressure were complete and plausible (e.g. BMI of 15–35 kg/m2, weight of 30–150 kg, height of 130–190 cm, WC of 45–150 cm, hip circumference of 55–155 cm, WHR of 0·6–1·1, difference between systolic and diastolic blood pressure ≥10 mmHg).

§ % change = 100 × absolute[ln(PRBMI/PRTest variables)]; test variables were BMI + WC, BMI + WSR or BMI + WHR.

|| P value of the increase in model fit compared with a model with BMI (likelihood ratio test).

Crude models: include independent variables in the list; crude PR for each unit increase in BMI.

†† Age-adjusted models: independent variables + age; age-adjusted PR for each unit increase in BMI.

‡‡ Age-specific model: independent variables + age + (age × BMI); PR for each unit increase in BMI at the age of 45 years.

The AUC estimates for the prediction of hypertension by BMI (about 0·7–0·8) were higher among women (P < 0·05 in age-adjusted and age-specific estimates). Although there was an increase in model fit when adding WC, WSR or WHR to a model with BMI (P < 0·05 in almost all of the models; likelihood ratio test), the changes in AUC were <5 % in the crude models and <1 % in the age-adjusted and age-specific models (Table 3). The changes in AUC increased slightly (<10 % except for WSR in crude model for women) among participants with BMI < 23 kg/m2 (Supplementary table 2).

Table 3 Sex-specific AUC for the prediction of hypertension by different anthropometric indicesFootnote ,Footnote

AUC, area under the receiver-operating characteristic curve; WC, waist circumference; WSR, waist:stature ratio; WHR, waist:hip ratio.

Significantly different compared with a model with BMI (independent t test): * P < 0·05.

Significant increase in model fit compared with a model with BMI (likelihood ratio test): **P < 0·005, ***P < 0·001, NS, P = 0·07.

Hypertension was defined as systolic blood pressure ≥140 mmHg, diastolic blood pressure ≥90 mmHg or being diagnosed by a doctor.

The samples included participants who were 18- to 65-year-old men and women (not pregnant or lactating), for whom measurements of anthropometric indices and blood pressure were complete and plausible (e.g. BMI of 15–35 kg/m2, weight of 30–150 kg, height of 130–190 cm, WC of 45–150 cm, hip circumference of 55–155 cm, WHR of 0·6–1·1, difference between systolic and diastolic blood pressure ≥10 mmHg).

§ AUC values range from 0·5 (no prediction) to 1·0 (perfect prediction); estimated by using logistic regression models.

|| % change = 100 × absolute[ln(AUCBMI/AUCTest variables)]; test variables were WC, WSR, WHR, BMI + WC, BMI + WSR or BMI + WHR.

Crude models: include independent variables in the list.

†† Age-adjusted models: independent variables + age.

‡‡ Age-specific model: independent variables + age + (age × BMI).

Models with WC or WSR provided similar AUC compared with models with BMI for men, women and both sexes (difference in AUC < 2·5 %; P > 0·05). A model with WHR had about 4–10 % lower AUC compared with a corresponding model with BMI (Table 3). There were some increases (<10 % except for WSR in crude model for women) in the prediction of hypertension by WC, WSR and WHR compared with that by BMI among participants with BMI < 23 kg/m2 (Supplementary table 2).

Discussion

To our knowledge, we are the first to use changes in PR and AUC as the criteria to evaluate whether WC, WSR or WHR adds to the prediction of hypertension by BMI in an Asian population. Our findings show that even though WC, WSR and WHR are predictors of hypertension and improve the fit of models with BMI, they do not perform better than BMI or add meaningfully to the prediction of hypertension outcome by BMI in Chinese adults.

We observed a significant trend of increased prevalence of hypertension with increased BMI, WC, WSR and WHR. This finding was similar to results from studies in Asian(Reference Ho, Chen, Woo, Leung, Lam and Janus6, Reference Ho, Lam and Janus7, Reference Ito, Nakasuga, Ohshima, Maruyama, Kaji, Harada, Fukunaga, Jingu and Sakamoto9, Reference Lin, Lee, Chen, Lo, Hsia, Liu, Lin, Shau and Huang10, Reference Balkau, Deanfield and Despres21Reference Wildman, Gu, Reynolds, Duan and He25) and Western populations(Reference Zhu, Wang, Heshka, Heo, Faith and Heymsfield5, Reference Canoy, Luben, Welch, Bingham, Wareham, Day and Khaw26, Reference Dalton, Cameron, Zimmet, Shaw, Jolley, Dunstan and Welborn27). Increased blood pressure is associated with increased BMI because an increase in body weight and thus BMI is related to an increase in body fluid volume, peripheral resistance (e.g. hyperinsulinaemia, cell membrane alteration and hyperactivity of the rennin–angiotensin system lead to functional constriction and structural hypertrophy) and cardiac output(Reference Kaplan28). The positive correlation between WC, WSR or WHR and prevalence of hypertension could be explained by an increase in visceral fat that leads to increased leptin and insulin resistance and worse lipid profiles(Reference Kaplan28, Reference Pavey, Plalmer, Sowers and Stump29).

There are several possible explanations for the finding that WC and WSR did not perform better or add to the prediction of hypertension by BMI in this population. First, WC and WSR were highly correlated with BMI (sex-specific Pearson correlation coefficients were about 0·75). The high correlation leads to a large overlap among the predictions explained by WC, WSR and BMI. Second, compared with other races and ethnicities, Asians accumulate more total body fat and visceral fat with an increase in body weight(Reference Deurenberg, Deurenberg-Yap and Guricci30Reference Park, Allison, Heymsfield and Gallagher32). In addition, WC and WSR are only proxy indicators for total body fat and visceral fat(Reference Gibson1) while increased visceral fat is a predictor for an increase in metabolic risk(Reference Klein, Allison, Heymsfield, Kelley, Leibel, Nonas and Kahn2).

The findings that WC, WSR and WHR were not superior to BMI in the prediction of hypertension are consistent with those from a representative sample of 55 563 Taiwanese in a study by Lin et al.(Reference Lin, Lee, Chen, Lo, Hsia, Liu, Lin, Shau and Huang10). Their protocols for the measurements of weight, height, WC, HC and blood pressures were similar to ours. Based on their data, we computed the difference in AUC based on the sex-specific AUC of each risk factor or disease condition (e.g. hypertension, diabetes mellitus, dislipidaemia, elevated TAG, total cholesterol or LDL cholesterol, or decreased HDL cholesterol). WC, WSR or WSR was not superior (<10 % increase in AUC) to BMI in the prediction of any risk factors or disease conditions in women or men.

We also computed the difference in AUC with the use of sex-specific AUC from a sample of 2895 Hong Kong Chinese in a study by Ho et al.(Reference Ho, Lam and Janus7). WC provided similar predictions to BMI in the examined diseases and metabolic risk factors (except for stroke in women), while WHR and WSR were better than BMI in some predictions (e.g. hypertension and CVD (men); dislipidaemia (women); and fasting glucose, diabetes and stroke (men and women)). There are three potential explanations for the differences. First, the study by Ho et al.(Reference Ho, Lam and Janus7) was based on a non-representative sample: participants were recruited by telephone (response rate of 78 %), and only 38 % of responders were examined and included in the final sample. Those participants might have very different disease patterns, risk factors and health-related behaviours compared with the non-participants(Reference Grimes and Schulz33). Second, Ho et al.’s study(Reference Ho, Lam and Janus7) included 65- to 74-year-old participants who might have: (i) a lower WC measured at a high location (Ho et al. measured WC at midway between the xiphisternum and the umbilicus), which would underestimate abdominal fat and overestimate the prediction of WC; and (ii) a higher BMI due to a biological decrease in height which would underestimate the prediction of BMI. As a result, there would be an increase in the prediction of WC, WSR or WHR compared with BMI. Third, WC measured in the Ho et al.’s study(Reference Ho, Lam and Janus7) was systematically smaller than ours (we measured WC midway between the lowest rib and the iliac crest)(Reference Wang, Thornton and Bari34). Decreased WSR and WHR, resulting from the smaller WC, would bias the association between WSR and WHR away from the null and would increase their predictions compared with that of BMI.

Our study showed a tendency toward increased prediction of hypertension by WC, WSR or WHR among participants with a lower BMI (e.g. BMI < 23 kg/m2). The finding is consistent with those of Ardern et al.(Reference Ardern, Janssen, Ross and Katzmarzyk35), in which the association between WC and cardiovascular risk was stronger at a lower BMI. However, the studies are not directly comparable. Their sample included American (white, black and Hispanic) and Canadian participants who differed from our Chinese participants in age, body composition, lifestyles and socio-economic characteristics. Also, Ardern et al.(Reference Ardern, Janssen, Ross and Katzmarzyk35) used the Framingham CHD risk index as study outcome, while we used hypertension.

We would have concluded that WC, WSR or WHR added to the prediction of hypertension by BMI (this finding being consistent with other studies(Reference Zhu, Wang, Heshka, Heo, Faith and Heymsfield5, Reference Ito, Nakasuga, Ohshima, Maruyama, Kaji, Harada, Fukunaga, Jingu and Sakamoto9, Reference Wildman, Gu, Reynolds, Duan, Wu and He12)) if a P value of <0·05 in a likelihood ratio test had been used as a decision criterion. However, this criterion is not the best choice because a P value varies with both the magnitude of effect and the sample size(Reference Weinberg13, Reference Rothman, Greenland and Lash14). For example, with a large sample size, we could detect a small difference (e.g. P value <0·05); in contrast, with a small sample size, we may not detect a large difference (e.g. P value >0·05). Our methods are expected to be more stable to the variation in sample size because the estimations of PR, AUC and the change in those estimates are less likely to be affected by the changes sample size(Reference Greenland and Rothman15, Reference Zweig and Campbell16). In addition, our sensitivity analyses, in which samples of 50 % and 10 % of the original sample were selected randomly, showed that P value is more sensitive to changes in sample size than is percentage change in PR and AUC.

In the context of a developing country, it is important to find a small number of practical, low-cost and culturally accepted anthropometric indices to predict elevated disease burdens(Reference Popkin, Kim, Rusev, Du and Zizza36, 37). In a population or clinical setting among Chinese adults, BMI appears to be sufficient because: (i) the exclusion of WC will save time, money and human resources; and (ii) the interpretation of a WC value would be confusing because of the lack of a universally accepted site for measuring WC and the large variation of WC optimal cut-offs by sex, age, races, ethnicities, BMI levels and health outcomes of interest(Reference Klein, Allison, Heymsfield, Kelley, Leibel, Nonas and Kahn2). Even in the USA, most of the treatment recommendations (99·9 % for men and 98·5 % for women; data from the Third National Health and Nutrition Examination Survey) were based on the evaluation of BMI and cardiovascular risk factors, regardless of the measured WC(Reference Kiernan and Winkleby38).

In conclusion, the present study showed that even though WC, WSR and WHR are predictors of hypertension, they do not perform better than BMI or add to the prediction of hypertension by BMI in Chinese adults. The comparison of PR and AUC, instead of P value or 95 % CI, is considered a strength and a methodological contribution of the present study. Further studies with other outcomes (e.g. glucose intolerance, diabetes mellitus, dyslipidaemia, mortality or events of CVD/non-communicable diseases) and more detailed information about body composition (e.g. total abdominal adipose tissue, visceral adipose tissue, total body fat mass) in representative samples of Chinese, other Asian and Western populations are still needed to confirm the consistency of the finding. Nevertheless, our conclusions about the value of using BMI to predict hypertension are meaningful for decision making in public health and clinical settings. Compared with WC, height and weight and thus BMI are: (i) collected more often in nutrition and health surveys, interventions and in clinics; (ii) collected with the use of universally accepted protocols; and (iii) easier to interpret.

Acknowledgements

Sources of funding: The research was financially supported in part by the Vietnam Educational Foundation (VEF), the National Institutes of Health (NIH; R01-HD30880, HD38700, DK056350 and DK533951) and the Fogarty International Center, NIH for financial support for the CHNS data collection and analysis files. Conflict of interest declaration: None of the authors had a conflict of interest related to any part of this study or manuscript. Author contributions: N.T.T. designed the study, acquired the data, analysed and interpreted the data, and drafted the manuscript. L.S.A. assisted in the analysis and interpretation of the data, and provided critical intellectual feedback for the manuscript. J.S. assisted in the interpretation of the data and provided critical intellectual feedback for the manuscript. B.M.P. assisted in the study design and interpretation of the data, and provided critical intellectual feedback for the manuscript. All authors have read and approved the final version of the manuscript. Acknowledgements: We thank Dr Chirayath Suchindran and Dr Ka He for critically reading the article, Bill Shapbell for editing and Frances Dancy for administrative assistance.

References

1. Gibson, R (2005) Principles of Nutritional Assessment, 2nd ed. New York: Oxford University Press.CrossRefGoogle Scholar
2. Klein, S, Allison, DB, Heymsfield, SB, Kelley, DE, Leibel, RL, Nonas, C & Kahn, R (2007) Waist circumference and cardiometabolic risk: a consensus statement from Shaping America’s Health: Association for Weight Management and Obesity Prevention; NAASO, The Obesity Society; the American Society for Nutrition; and the American Diabetes Association. Am J Clin Nutr 85, 11971202.CrossRefGoogle Scholar
3. Visscher, TL, Seidell, JC, Molarius, A, van der Kuip, D, Hofman, A & Witteman, JC (2001) A comparison of body mass index, waist–hip ratio and waist circumference as predictors of all-cause mortality among the elderly: the Rotterdam study. Int J Obes Relat Metab Disord 25, 17301735.CrossRefGoogle ScholarPubMed
4. Benetou, V, Bamia, C, Trichopoulos, D, Mountokalakis, T, Psaltopoulou, T & Trichopoulou, A (2004) The association of body mass index and waist circumference with blood pressure depends on age and gender: a study of 10,928 non-smoking adults in the Greek EPIC cohort. Eur J Epidemiol 19, 803809.CrossRefGoogle Scholar
5. Zhu, S, Wang, Z, Heshka, S, Heo, M, Faith, MS & Heymsfield, SB (2002) Waist circumference and obesity-associated risk factors among whites in the third National Health and Nutrition Examination Survey: clinical action thresholds. Am J Clin Nutr 76, 743749.CrossRefGoogle ScholarPubMed
6. Ho, SC, Chen, YM, Woo, JL, Leung, SS, Lam, TH & Janus, ED (2001) Association between simple anthropometric indices and cardiovascular risk factors. Int J Obes Relat Metab Disord 25, 16891697.CrossRefGoogle ScholarPubMed
7. Ho, SY, Lam, TH & Janus, ED (2003) Waist to stature ratio is more strongly associated with cardiovascular risk factors than other simple anthropometric indices. Ann Epidemiol 13, 683691.CrossRefGoogle ScholarPubMed
8. Hsieh, SD, Yoshinaga, H & Muto, T (2003) Waist-to-height ratio, a simple and practical index for assessing central fat distribution and metabolic risk in Japanese men and women. Int J Obes Relat Metab Disord 27, 610616.CrossRefGoogle ScholarPubMed
9. Ito, H, Nakasuga, K, Ohshima, A, Maruyama, T, Kaji, Y, Harada, M, Fukunaga, M, Jingu, S & Sakamoto, M (2003) Detection of cardiovascular risk factors by indices of obesity obtained from anthropometry and dual-energy X-ray absorptiometry in Japanese individuals. Int J Obes Relat Metab Disord 27, 232237.CrossRefGoogle ScholarPubMed
10. Lin, WY, Lee, LT, Chen, CY, Lo, H, Hsia, HH, Liu, IL, Lin, RS, Shau, WY & Huang, KC (2002) Optimal cut-off values for obesity: using simple anthropometric indices to predict cardiovascular risk factors in Taiwan. Int J Obes Relat Metab Disord 26, 12321238.CrossRefGoogle ScholarPubMed
11. Sakurai, M, Miura, K, Takamura, T, Ota, T, Ishizaki, M, Morikawa, Y, Kido, T, Naruse, Y & Nakagawa, H (2006) Gender differences in the association between anthropometric indices of obesity and blood pressure in Japanese. Hypertens Res 29, 7580.CrossRefGoogle ScholarPubMed
12. Wildman, RP, Gu, D, Reynolds, K, Duan, X, Wu, X & He, J (2005) Are waist circumference and body mass index independently associated with cardiovascular disease risk in Chinese adults? Am J Clin Nutr 82, 11951202.CrossRefGoogle ScholarPubMed
13. Weinberg, CR (2001) It’s time to rehabilitate the P-value. Epidemiology 12, 288290.CrossRefGoogle ScholarPubMed
14. Rothman, K, Greenland, S & Lash, T (2008) Precision and statistics in epidemiologic studies. In Modern Epidemiology, 3rd ed., pp. 148167 [S Greenland, K Rothman and T Lash, editors]. Philadelphia, PA: Lippincott Williams & Wilkins.Google Scholar
15. Greenland, S & Rothman, K (2008) Introduction to stratified analysis. In Modern Epidemiology, 3rd ed., pp. 258282 [S Greenland, K Rothman and T Lash, editors]. Philadelphia, PA: Lippincott Williams & Wilkins.Google Scholar
16. Zweig, MH & Campbell, G (1993) Receiver-operating characteristic (ROC) plots: a fundamental evaluation tool in clinical medicine. Clin Chem 39, 561577.CrossRefGoogle ScholarPubMed
17. Carolina Population Center, University of North Carolina (2007) China Health and Nutrition Survey. Chapel Hill, NC: CPC, UNC-CH; also available at http://www.cpc.unc.edu/chinaGoogle Scholar
18. Popkin, BM, Paeratakul, S, Zhai, F & Ge, K (1995) Dietary and environmental correlates of obesity in a population study in China. Obes Res 3, Suppl. 2, 135s143s.CrossRefGoogle Scholar
19. World Health Organization (1995) Physical Status: The Use and Interpretation of Anthropometry. Report of a WHO Expert Committee. Geneva: WHO.Google Scholar
20. Chobanian, AV, Bakris, GL, Black, HR et al. (2003) The Seventh Report of the Joint National Committee on Prevention, Detection, Evaluation, and Treatment of High Blood Pressure: the JNC 7 report. JAMA 289, 25602572.CrossRefGoogle ScholarPubMed
21. Balkau, B, Deanfield, JE, Despres, JP et al. (2007) International Day for the Evaluation of Abdominal Obesity (IDEA): a study of waist circumference, cardiovascular disease, and diabetes mellitus in 168,000 primary care patients in 63 countries. Circulation 116, 19421951.CrossRefGoogle Scholar
22. Colin Bell, A, Adair, LS & Popkin, BM (2002) Ethnic differences in the association between body mass index and hypertension. Am J Epidemiol 155, 346353.CrossRefGoogle ScholarPubMed
23. Tesfaye, F, Nawi, NG, Van Minh, H, Byass, P, Berhane, Y, Bonita, R & Wall, S (2007) Association between body mass index and blood pressure across three populations in Africa and Asia. J Hum Hypertens 21, 2837.CrossRefGoogle ScholarPubMed
24. Weng, X, Liu, Y, Ma, J, Wang, W, Yang, G & Caballero, B (2006) Use of body mass index to identify obesity-related metabolic disorders in the Chinese population. Eur J Clin Nutr 60, 931937.CrossRefGoogle ScholarPubMed
25. Wildman, RP, Gu, D, Reynolds, K, Duan, X & He, J (2004) Appropriate body mass index and waist circumference cutoffs for categorization of overweight and central adiposity among Chinese adults. Am J Clin Nutr 80, 11291136.CrossRefGoogle ScholarPubMed
26. Canoy, D, Luben, R, Welch, A, Bingham, S, Wareham, N, Day, N & Khaw, KT (2004) Fat distribution, body mass index and blood pressure in 22,090 men and women in the Norfolk cohort of the European Prospective Investigation into Cancer and Nutrition (EPIC-Norfolk) study. J Hypertens 22, 20672074.CrossRefGoogle Scholar
27. Dalton, M, Cameron, AJ, Zimmet, PZ, Shaw, JE, Jolley, D, Dunstan, DW & Welborn, TA (2003) Waist circumference, waist–hip ratio and body mass index and their correlation with cardiovascular disease risk factors in Australian adults. J Intern Med 254, 555563.CrossRefGoogle ScholarPubMed
28. Kaplan, N (2006) Primary hypertension: pathogenesis. In Kaplan’s Clinical Hypertension, 9th ed., pp. 50121 [N Kaplan, editor]. Philadelphia, PA: Lippincott Williams & Wilkins.Google Scholar
29. Pavey, B, Plalmer, J, Sowers, J & Stump, C (2006) Hypertension and diabetes mellitus. In Molecular Mechanisms in Hypertension, pp. 361374 [R Re, D DiPette, E Schiffrin and J Sowers, editors]. London: Taylor & Francis.Google Scholar
30. Deurenberg, P, Deurenberg-Yap, M & Guricci, S (2002) Asians are different from Caucasians and from each other in their body mass index/body fat per cent relationship. Obes Rev 3, 141146.CrossRefGoogle ScholarPubMed
31. Lear, SA, Humphries, KH, Kohli, S, Chockalingam, A, Frohlich, JJ & Birmingham, CL (2007) Visceral adipose tissue accumulation differs according to ethnic background: results of the Multicultural Community Health Assessment Trial (M-CHAT). Am J Clin Nutr 86, 353359.CrossRefGoogle ScholarPubMed
32. Park, YW, Allison, DB, Heymsfield, SB & Gallagher, D (2001) Larger amounts of visceral adipose tissue in Asian Americans. Obes Res 9, 381387.CrossRefGoogle ScholarPubMed
33. Grimes, DA & Schulz, KF (2002) Bias and causal associations in observational research. Lancet 359, 248252.CrossRefGoogle ScholarPubMed
34. Wang, J, Thornton, JC, Bari, S et al. (2003) Comparisons of waist circumferences measured at 4 sites. Am J Clin Nutr 77, 379384.CrossRefGoogle ScholarPubMed
35. Ardern, CI, Janssen, I, Ross, R & Katzmarzyk, PT (2004) Development of health-related waist circumference thresholds within BMI categories. Obes Res 12, 10941103.CrossRefGoogle ScholarPubMed
36. Popkin, BM, Kim, S, Rusev, ER, Du, S & Zizza, C (2006) Measuring the full economic costs of diet, physical activity and obesity-related chronic diseases. Obes Rev 7, 271293.CrossRefGoogle ScholarPubMed
37. World Health Organization (2003) The World Health Report 2002. Geneva: WHO.Google Scholar
38. Kiernan, M & Winkleby, MA (2000) Identifying patients for weight-loss treatment: an empirical evaluation of the NHLBI obesity education initiative expert panel treatment recommendations. Arch Intern Med 160, 21692176.CrossRefGoogle Scholar
Figure 0

Table 1 Characteristics† of the 18- to 65-year-old Chinese participants‡

Figure 1

Fig. 1 Prevalence and 95 % CI of hypertension by levels of (a) BMI, (b) waist circumference (WC) and (c) waist:stature ratio (WSR). Hypertension was defined as systolic blood pressure ≥140 mmHg, diastolic blood pressure ≥90 mmHg or being diagnosed by a doctor. The samples included participants who were 18- to 65-year-old men (█, n 3542) and women (, not pregnant or lactating; n 3794), for whom measurements of anthropometric indices and blood pressure were complete and plausible (e.g. BMI of 15–35 kg/m2, weight of 30–150 kg, height of 130–190 cm, WC of 45–150 cm, hip circumference of 55–155 cm, waist:hip ratio of 0·6–1·1, difference between systolic and diastolic blood pressure ≥10 mmHg). P for trend <0·001 for all

Figure 2

Table 2 Sex-specific prevalence ratios of BMI for hypertension†,‡

Figure 3

Table 3 Sex-specific AUC for the prediction of hypertension by different anthropometric indices†,‡

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