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Waist:height ratio: a superior index in estimating cardiovascular risks in Turkish adults

Published online by Cambridge University Press:  08 October 2013

Reci Meseri*
Affiliation:
Department of Nutrition and Dietetics, Izmir Ataturk School of Health, Ege University, Bornova, 35100 Izmir, Turkey
Reyhan Ucku
Affiliation:
Faculty of Medicine, Department of Public Health, Dokuz Eylul University, Narlidere, Izmir, Turkey
Belgin Unal
Affiliation:
Faculty of Medicine, Department of Public Health, Dokuz Eylul University, Narlidere, Izmir, Turkey
*
*Corresponding author: Email recimeseri@yahoo.com
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Abstract

Objective

To determine the best anthropometric measurement among waist: height ratio (WHtR), BMI, waist:hip ratio (WHR) and waist circumference (WC) associated with high CHD risk in adults and to define the optimal cut-off point for WHtR.

Design

Population-based cross-sectional study.

Setting

Balcova, Izmir, Turkey.

Subjects

Individuals (n 10 878) who participated in the baseline survey of the Heart of Balcova Project. For each participant, 10-year coronary event risk (Framingham risk score) was calculated using data on age, sex, smoking status, blood pressure, serum lipids and diabetes status. Participants who had risk higher than 10 % were defined as ‘medium or high risk’.

Results

Among the participants, 67·7 % were female, 38·2 % were obese, 24·5 % had high blood pressure, 9·2 % had diabetes, 1·5 % had undiagnosed diabetes (≥126 mg/dl), 22·0 % had high total cholesterol and 45·9 % had low HDL-cholesterol. According to Framingham risk score, 32·7 % of them had a risk score higher than 10 %. Those who had medium or high risk had significantly higher mean BMI, WHtR, WHR and WC compared with those at low risk. According to receiver-operating characteristic curves, WHtR was the best and BMI was the worst indicator of CHD risk for both sexes. For both men and women, 0·55 was the optimal cut-off point for WHtR for CHD risk.

Conclusions

BMI should not be used alone for evaluating obesity when estimating cardiometabolic risks. WHtR was found to be a successful measurement for determining cardiovascular risks. A cut-off point of ‘0·5’ can be used for categorizing WHtR in order to target people at high CHD risk for preventive actions.

Type
Assessment and methodology
Copyright
Copyright © The Authors 2013 

Obesity, particularly abdominal obesity, is associated with metabolic abnormalities such as insulin resistance, impaired glucose tolerance and elevated serum lipids, as well as hypertension, diabetes, CVD and mortality(Reference Rexrode, Buring and Manson1, Reference Ashwell and Gibson2). BMI has been used for determining obesity for many years, but within the last two decades measurements of abdominal obesity such as waist circumference (WC), waist:hip ratio (WHR) and waist:height ratio (WHtR) have become more important in defining associations between obesity and cardiometabolic risks(Reference Ashwell and Gibson2, Reference Ashwell, Gunn and Gibson3).

Defined by Adolphe Quetelet in the 19th century, BMI is the most frequently used obesity index, but today we know that it has many disadvantages. First of all, it provides information about total body fat and does not provide clues regarding fat mass or fat distribution. Moreover, even though it uses only weight and height, a calculator is needed for its calculation. Finally, the WHO has defined cut-off points for BMI in adults, but these cut-off points are not applicable for children and the elderly(Reference Meseri and Unal4Reference Cook, Kirk and Lawrenson6).

In the late 1940s, the French physician Jean Vague stated that fat distribution in the body is more important than total body fat and defined gynoid and android type fatness, with latter being more hazardous for cardiometabolic risks. However, the importance of fat distribution in association with CVD began to be discussed in the 1980s(Reference Ashwell and Gibson2, Reference Vague7). In the 1990s, it was hypothesized that WC alone would be enough to estimate cardiometabolic risks. Even though measuring WC is very practical, easy and cheap, it has unfavourable aspects such as being affected by race and not taking height into account(Reference Browning, Hsieh and Ashwell8). Moreover, in a study conducted in Japan, it was found that short people having moderate WC had a higher cardiometabolic risk than taller people(Reference Hsieh and Yoshinaga9).

WHtR (WC divided by height) is a relatively new abdominal obesity index. Ashwell and co-workers were the first to suggest using WHtR in the mid-1990s(Reference Ashwell, Cole and Dixon10, Reference Ashwell, Lejeune and McPherson11). On the basis of a study conducted among UK department store employees, Ashwell et al. stated that adjusting WC by height would improve the definition of metabolic syndrome(Reference Kwok, McElduff and Ashton12). A meta-analysis published in 2011 showed that WHtR was superior to BMI and WC in detecting cardiometabolic risks in both sexes(Reference Ashwell, Gunn and Gibson3). In a large Taiwanese sample, WHtR was found to be a simple and effective index of cardiometabolic risk(Reference Li, Chen and Chang13). Since it also considers height, WHtR is not affected by body shape or race. According to different studies conducted recently, a cut-off point of 0·5 is suggested for both men and women in different age and ethnic groups. This cut-off point also has the advantage of being easy to remember(Reference Ashwell and Gibson2, Reference Ashwell and Hsieh14Reference Lim, Seubsman and Sleigh17).

The objective of the present study was to investigate the best anthropometric measurement associated with high CHD risk among BMI, WC, WHR and WHtR, and to define the optimal cut-off point for WHtR.

Materials and methods

Background

The Heart of Balcova (BAK) Project was initiated in 2007 in Balcova, an urban settlement of Izmir, Turkey, with the collaboration of Balcova Municipality and Dokuz Eylul University Faculty of Medicine. The objective of the BAK Project was to improve the cardiovascular health of the population through population- and individual-level primary prevention initiatives, including reducing smoking and promoting healthy diet and physical activity. A baseline population survey was conducted between 2007 and 2009 to determine the cardiovascular risk status of the residents aged 30 years and over. Ethical approval was granted by the Ethics Committee of Dokuz Eylul University and written informed consent was obtained from each participant. Details of the BAK Project are published elsewhere(Reference Ergor, Soysal and Sozmen18, Reference Ünal, Sözmen and Uçku19).

Participants

The current cross-sectional study includes 10 878 individuals who participated in the baseline survey of the BAK Project who were not pregnant, had no missing data and who were eligible for estimating Framingham risk score.

Variables

Coronary event risk within 10 years was calculated using a Framingham risk score that included data on age, sex, smoking status, blood pressure, serum lipids and diabetes status(20Reference Wilson, D'Agostino and Levy22). Those who had risk lower than 10 % were designated ‘low’ risk, whereas those who fell between 10 % and 19 % were ‘medium risk’, and those with a risk higher than 20 % were classified as ‘high risk’. In the statistical analysis, medium risk and high risk groups were combined as ‘medium or high risk’. A questionnaire on sociodemographic variables, smoking status and health history was completed. Blood samples were collected after one night of fasting into Vacutainer tubes by trained nurses. All blood samples were taken to the Dokuz Eylul University Central Laboratory and an Abbott Architect c16000 auto-analyser was used with its original kits for analyses of blood glucose and serum lipids. Standard blood pressure measurements were taken by skilled physicians and nurses using a validated mercury sphygmomanometer from patients at rest (5–10 min) in the sitting position, with the values averaged over two measurements. Weight, height, WC and hip circumference (HC) were measured and BMI, WC, WHR and WHtR were calculated to obtain anthropometric measurements. Weight was measured using a scale, with the participant wearing light clothes and without shoes; height was measured with a standard height scale mounted on the wall. Participants stood still, without shoes, in the Frankfort plane position. BMI was calculated as weight (kilograms) divided by the square of height (metres). WC and HC were measured with a non-elastic standard measuring tape, with the participant wearing light clothes, standing still, in an upright position and with arms open sidewards. WC was measured at the midpoint between the distal border of the lowest rib and the superior border of the iliac crest. HC was measured at the widest point of the hips. WHtR was calculated by dividing WC circumference by height and WHR was calculated by dividing WC by HC. Cut-off points were defined as follows: BMI ≥30 kg/m2(Reference Ashwell and Gibson2, Reference Tsigos, Hainer and Basdevant23); WC ≥102 cm (men), ≥88 cm (women)(Reference Narksawat, Podang and Punyarathabundu24Reference Alberti, Zimmet and Shaw26); WHR ≥0·90 (men), ≥0·85 (women)(Reference Grundy, Cleeman and Daniels27); and WHtR ≥0·5(Reference Ashwell and Gibson2, Reference Browning, Hsieh and Ashwell8, Reference Ashwell and Hsieh14).

Statistical methods

Continuous variables were calculated as means with their standard errors and categorical variables were calculated as percentages. Men and women were compared for anthropometric measurements and metabolic characteristics such as blood glucose and serum lipids using Student's t test. The χ 2 test was used to compare men and women for categorized anthropometric measurements and metabolic risks. Receiver-operating characteristic (ROC) curves for anthropometric measurements were drawn for medium or high coronary event risk and the measurement with the largest area under the curve (AUC) was accepted to be the best indicator. An AUC of 1·0 indicates perfect discrimination between the absence and presence of the condition tested, whereas an AUC of 0·5 indicates no discriminative capability. To determine the optimal cut-off point for WHtR in men and women, the Youden index (J) was used, where J = sensitivity + specificity – 1. The WHtR value which had the highest J value was defined as the optimal cut-off point(Reference Can, Yildiz and Samur15). Logistic regression models were used to determine independent associations of anthropometric indices with medium or high Framingham risk scores. Crude and age-, sex- and BMI-adjusted odds ratios were calculated. Interaction between BMI categories and WHtR was also evaluated using logistic regression and the Breslow–Day test. Data were analysed using the SPSS statistical software package version 15·0. Significance was defined as P < 0·05.

Results

In total, 10 878 participants were assessed. Within the sample, 67·7 % were female, 82·9 % were married, 44·7 % had primary and 35·9 % had higher education. Mean age was 51·23 (se 0·19) years for men and 49·59 (se 0·13) years for women. According to their health history, 24·5 % had high blood pressure, 9·2 % had diabetes and 31·5 % were current smokers, with men being significantly more likely to smoke than women (38·7 % in men, 28·7 % in women, P < 0·001). When metabolic risks were assessed, 7·5 % had impaired fasting blood glucose (110–125 mg/dl), 1·5 % had undiagnosed diabetes (≥126 mg/dl), 22·0 % had high total cholesterol, 19·8 % had high LDL-cholesterol and 45·9 % had low HDL-cholesterol. Using BMI as a measure, 39·3 % of the participants were overweight and 38·2 % were obese. When the Framingham risk score was evaluated, one tenth (9·4 %) of the participants had high risk (risk ≥20 %) and 23·2 % had medium risk (risk 10–19 %).

Health status of the participants is presented in Table 1. Men had significantly higher prevalences of hypertension, elevated fasting blood glucose, high LDL-cholesterol, high TAG and obesity according to WHR and WHtR compared with women (Table 1). Women, on the other hand, significantly more frequently had low HDL-cholesterol. In addition, women had significantly elevated WC and BMI compared with men (P < 0·001 for all, except P = 0·03 for LDL-cholesterol).

Table 1 Health status of the participants according to gender: Turkish men and women participating in the baseline survey of the Heart of Balcova Project, 2007–2009

IGT, impaired glucose tolerance; DM, diabetes mellitus; LDL-C, LDL-cholesterol; HDL-C, HDL-cholesterol; WC, waist circumference; WHR, waist:hip ratio; WHtR, waist:height ratio.

*Pre-diagnosed diabetics were excluded.

†IGT: 284 men had 110–125 mg/dl, 537 women had 110–125 mg/dl.

‡Among non-obese individuals, 1705 men were overweight and 2546 women were overweight.

Among men, 21·2 % had high cardiovascular risk and 31·9 % had medium risk, whereas in women these rates were 3·8 % and 19·1 %, respectively. There were significantly more men than women in the medium or high risk group (P < 0·001). The association of anthropometric measurements with cardiovascular risk is presented in Table 2. As shown in Table 2, both in men and women, those in the medium or high risk group had significantly higher mean anthropometric measurements.

Table 2 Association of anthropometric measurements with CHD riskFootnote * according to gender: Turkish men and women (n 10 878) participating in the baseline survey of the Heart of Balcova Project, 2007–2009

WC, waist circumference; WHR, waist:hip ratio; WHtR, waist:height ratio.

* Framingham risk score.

Figures 1 and 2 illustrate the most accurate anthropometric measurement for estimating CHD risk in men and women, respectively, and Table 3 illustrates the AUC of the anthropometric measurements. According to Table 3 and Fig. 1, WHtR was found to be the best indicator for estimating CHD risk in men, followed by WHR, whereas BMI was found to be the worst indicator. In Fig. 2, WHtR found to be the best indicator for women, followed by WC, and similarly BMI was found to be worst indicator for estimating CHD risk. Predictive values of all indices were higher for women, with AUC varying between 71 % and 78 %.

Fig. 1 Receiver-operating characteristic curves of anthropometric measurements (- - - - - , BMI; – – – – –, waist circumference; — — —, waist:hip ratio; – - – - –, waist:height ratio) for the prediction of CHD risk (as expressed by medium or high Framingham risk score) among Turkish men (n 3510) participating in the baseline survey of the Heart of Balcova Project, 2007–2009. ——— is the reference line; diagonal segments are produced by ties

Fig. 2 Receiver-operating characteristic curves of anthropometric measurements (- - - - - , BMI; – – – – –, waist circumference; — — —, waist:hip ratio; – - – - –, waist:height ratio) for the prediction of CHD risk (as expressed by medium or high Framingham risk score) among Turkish women (n 7368) participating in the baseline survey of the Heart of Balcova Project, 2007–2009. ——— is the reference line; diagonal segments are produced by ties

Table 3 AUC values for anthropometric measurements in estimating CHD riskFootnote * according to gender: Turkish men and women (n 10 878) participating in the baseline survey of the Heart of Balcova Project, 2007–2009

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

* Medium or high Framingham risk score.

Using ROC curves and the Youden index, the optimal cut-off points for WHtR in men and women were determined. For both men and women 0·55 was found to be the optimal cut-off point for WHtR in estimating CHD risk.

In logistic regression models (Table 4), WHtR above 0·55 was significantly associated with having medium or high CHD risk (OR = 4·17; 95 % CI 3·81, 4·57). After adjusting for age and sex, the odds were decreased (OR = 2·24; 95 % CI 2·09, 2·63). Adding BMI to the model had little effect and WHtR remained independently associated with medium or high CHD risk (OR = 1·73; 95 % CI 1·48, 2·02). A similar pattern was seen for high WHR (OR = 1·91; 95 % CI 1·69, 2·15) and for high WC (OR = 1·77; 95 % CI 1·53, 2·05) in the age-, sex- and BMI-adjusted model.

Table 4 Association between CHD riskFootnote * and abdominal obesity indices: Turkish men and women (n 10 878) participating in the baseline survey of the Heart of Balcova Project, 2007–2009

WHtR, waist:height ratio; WHR, waist:hip ratio; WC, waist circumference.

* Medium or high Framingham risk score.

The interaction between BMI and WHtR was evaluated and is presented in Table 5 as the odds ratios of high WHtR in estimating CHD risk stratified for BMI category. High WHtR was significantly associated with medium or high CHD risk in each category of BMI. No interaction was detected between BMI and WHtR (Table 5).

Table 5 Odds ratios and 95 % confidence intervals of high WHtR for predicting CHD riskFootnote * stratified by BMI category: Turkish men and women (n 10 878) participating in the baseline survey of the Heart of Balcova Project, 2007–2009

WHtR, waist:height ratio.

No interaction was detected between BMI and WHtR: Breslow-Day test, P = 0·082.

* Medium or high Framingham risk score.

Discussion

In the present study, half of the participants had elevated serum total cholesterol and LDL-cholesterol and reduced HDL-cholesterol, and one-third of the participants had elevated serum TAG. According to BMI, WC and WHR, one-third of the sample was obese. Moreover, according to the Framingham risk score, one-third (32·7 %) of the participants had a risk of higher than 10 % for developing a coronary event in the next 10 years. Participants who had medium or high CHD risk had higher mean anthropometric measurements. Based on the ROC curves, WHtR was found to be the best indicator for estimating medium or high CHD risk, whereas BMI was found to be the worst indicator in both men and women. WHtR, WHR and WC each had an independent association with CHD risk even after adjusting for age, sex and BMI. There was no interaction between WHtR and BMI.

Obesity

Obesity is increasing worldwide, not in only developed countries but also in developing countries. The prevalence of obesity in Europe ranges between 10 and 25 % in men and between 10 and 30 % in women, and in the past decade it has increased by 10–40 %(Reference Tsigos, Hainer and Basdevant23). Turkey has the same pattern, with obesity even slightly higher in women, according to the National Ministry of Health. Prevalence of obesity in Turkey was found to be 21·7 % in men and 41·3 % in women in adults (aged ≥30 years)(Reference Sanisoglu, Oktenli and Hasimi28). In the current study, the prevalence of obesity defined by BMI was 29·4 % in men and 42·4 % in women.

In a study conducted in six different regions of Turkey which included participants aged 20 years and older, obesity prevalence was 21·8 % in men and 36·9 % in women(Reference Bagriacik, Onat and Ilhan29). Similarly, in another study which included those over 20 years of age living in the Black Sea region, obesity prevalence was 16·5 % for men and 29·4 % for women(Reference Erem, Arslan and Hacihasanoglu30). In our study, obesity prevalence was slightly higher than the average for Turkey, which may be due the older sample or differences in lifestyle due to urbanization.

Waist:height ratio and cardiometabolic risk

In our study, WHtR was found to be the best indicator for estimating medium or high CHD risk, whereas BMI was found to be the worst indicator in both sexes. For WHtR, the AUC was 66 % for men and 78 % for women. There are many studies evaluating the predictive power of anthropometric indices for cardiovascular deaths, CVD, hypertension, cardiometabolic risks, diabetes and dyslipidaemia(Reference Ashwell, Gunn and Gibson3, Reference Li, Chen and Chang13, Reference Hsieh and Muto31Reference Silva, Petroski and Peres35). Systemic reviews and meta-analyses have shown that WHtR is superior in estimating cardiometabolic risks. Ashwell et al. conducted a meta-analysis in 2011 and concluded that WHtR was more successful in estimating cardiometabolic risks compared with BMI and WC(Reference Ashwell, Gunn and Gibson3). In a systematic review, Browning et al. showed that WHtR had the highest AUC for diabetes, insulin resistance, hypertension, CVD and dyslipidemia in both men and women(Reference Browning, Hsieh and Ashwell8). In another meta-analysis conducted by Lee et al. similar results were found, with WHtR being superior in estimating hypertension, type II diabetes and dyslipidaemia, whereas BMI was found to be the worst indicator(Reference Lee, Huxley and Wildman36).

WHtR has positive aspects including providing similar results for both men and women, not being affected by race or ethnicity, taking height into account, and being easy to calculate(Reference Li, Chen and Chang13, Reference Ashwell and Hsieh14). There are some studies which have evaluated the utility of WHtR in estimating metabolic risks in different age and racial groups. In Germany, in two cohort studies, DETECT and SHIP, all-cause mortality, cardiovascular mortality and a composite index of stroke and/or myocardial infarction were evaluated using ROC curves and WHtR was found to be the best indicator and BMI the worst, indicating that BMI should not be used alone for estimating risks(Reference Schneider, Friedrich and Klotsche33). In Japan, 6141 men and 2137 women participated in a study where hypertension, elevated blood glucose, elevated TAG and reduced HDL-cholesterol were evaluated as coronary risk factors. Those who had two or more risk factors were grouped as high risk. According to the ROC curves drawn, WHtR was found to be the best indicator for estimating high risk, with the AUC being 68 % in men and 75 % in women(Reference Hsieh and Muto37). In a study conducted in Turkey, it was found that WHtR was the best indicator for predicting most of the cardiometabolic risk factors(Reference Can, Bersot and Gonen38). These results also support our findings, pointing to WHtR as the superior indicator.

Although there are many studies about the superiority of WHtR over other indices, the optimal cut-off point for WHtR is debatable. In the current study, 0·55 was found to be the optimal cut-off point for both men and women. WHtR remained statistically significantly associated with CHD risk even after adjusting for age, sex and BMI. In another study conducted in Turkey, Can et al. recommended the optimal cut-off point for Turkish adults as 0·59 for men and women(Reference Can, Yildiz and Samur15). There are some studies conducted in different populations which recommend 0·5 as the optimal cut-off point. In two different studies conducted on Chinese adults, 0·5 was found to be the optimal cut-off point for both men and women(Reference He, Zhai and Ma39, Reference He, Chen and Jiang40), with the same conclusions drawn in a study conducted in Iran(Reference Mellati, Mousavinasab and Sokhanvar41). A review by Browning et al. assessing findings across fourteen countries also recommended 0·5 as an optimal boundary(Reference Browning, Hsieh and Ashwell8). On the other hand, a study on hospital workers in Mexico found the optimal cut-off point as 0·52 for men and 0·53 for women(Reference Berber, Gomez-Santos and Fanghanel42). In Japan, the influence of height on metabolic syndrome was evaluated and it was found that the optimal cut-off point for men was 0·52, whereas for women it was 0·53(43).

Strengths and limitations of the study

The present study was conducted in an urban area of Izmir, the third largest city of Turkey. The population of this area comprises mainly relatively well-educated white collar workers or retired people, with a regular income. Obesity prevalence might be higher than expected due to the sedentary lifestyle of these urban residents. The cross-sectional design of the study prevents us from determining a cause-and-effect relationship between anthropometric indices and CHD risk. However, similar analyses can be repeated in the future in the follow-up of the Balcova cohort. On the other hand, obtaining data from a large community-based sample and implementing standardized measurement protocols might be considered as the strengths of the study.

Conclusions

One-third of participants were obese when evaluated using BMI, WC and WHR and one-third were in the medium or high risk group according to their Framingham risk score. According to WHtR, three-quarters of the participants were defined as obese. In both men and women, WHtR was found to be the best predictor of medium or high CHD risk, whereas BMI was found to be the least predictive. The optimal cut-off value for WHtR was 0·55 for both men and women, which can be rewritten as the slogan as ‘your waist circumference must not exceed half of your height’ for the public(Reference Ashwell and Gibson2).

Malnutrition, sedentary lifestyle and smoking are the common risk factors for many non-communicable diseases. Intervention studies must be conducted in order to decrease these risk factors at both the community and individual level. In the evaluation of obesity for cardiometabolic risks, BMI should not be used alone and an abdominal obesity index must be added. The use of WHtR is recommended, since it is easy to calculate, non-invasive, cheap and practical. Longitudinal studies should be conducted in order to determine the cause-and-effect relationship between anthropometric indices and cardiometabolic risks.

Acknowledgements

Sources of funding: The Heart of Balcova (BAK) Project was funded by Balcova Municipality. Balcova Municipality had no role in the design, analysis or writing of this article. Conflicts of interest: There are no conflicts of interest. Authors’ contributions: All authors participated in the study conception, analysis and interpretation of the data, drafting of the article and revision of its content.

References

1.Rexrode, KM, Buring, JE & Manson, JE (2001) Abdominal and total adiposity and risk of coronary heart disease in men. Int J Obes Relat Metab Disord 25, 10471056.CrossRefGoogle ScholarPubMed
2.Ashwell, M & Gibson, S (2009) Waist to height ratio is a simple and effective obesity screening tool for cardiovascular risk factors: analysis of data from the British National Diet And Nutrition Survey of adults aged 19–64 years. Obes Facts 2, 97103.CrossRefGoogle ScholarPubMed
3.Ashwell, M, Gunn, P & Gibson, S (2012) Waist-to-height ratio is a better screening tool than waist circumference and BMI for adult cardiometabolic risk factors: systematic review and meta-analysis. Obes Rev 13, 275286.CrossRefGoogle ScholarPubMed
4.Meseri, R & Unal, B (2009) Kardiyovasküler Risk ve Diyabeti Belirlemede Şişmanlık Nasıl Ölçülmesi (How to determine obesity to estimate cardiovascular risk and diabetes). TAF Prev Med Bull 8, 507514.Google Scholar
5.Eknoyan, G (2008) Adolphe Quetelet (1796–1874) – the average man and indices of obesity. Nephrol Dial Transplant 23, 4751.CrossRefGoogle ScholarPubMed
6.Cook, Z, Kirk, S, Lawrenson, Set al. (2005) Use of BMI in the assessment of undernutrition in older subjects: reflecting on practice. Proc Nutr Soc 64, 313317.CrossRefGoogle ScholarPubMed
7.Vague, J (1999) The degree of masculine differentiation of obesities: a factor determining predisposition to diabetes, atherosclerosis, gout, and uric calculous disease. 1956. Nutrition 15, 8990.Google ScholarPubMed
8.Browning, LM, Hsieh, SD & Ashwell, M (2010) A systematic review of waist-to-height ratio as a screening tool for the prediction of cardiovascular disease and diabetes: 0·5 could be a suitable global boundary value. Nutr Res Rev 23, 247269.CrossRefGoogle ScholarPubMed
9.Hsieh, SD & Yoshinaga, H (1999) Do people with similar waist circumference share similar health risks irrespective of height? Tohoku J Exp Med 188, 5560.CrossRefGoogle ScholarPubMed
10.Ashwell, M, Cole, TJ & Dixon, AK (1996) Ratio of waist circumference to height is strong predictor of intra-abdominal fat. BMJ 313, 559560.CrossRefGoogle ScholarPubMed
11.Ashwell, M, Lejeune, S & McPherson, K (1996) Ratio of waist circumference to height may be better indicator of need for weight management. BMJ 312, 377.CrossRefGoogle ScholarPubMed
12.Kwok, S, McElduff, P, Ashton, DWet al. (2008) Indices of obesity and cardiovascular risk factors in British women. Obes Facts 1, 190195.CrossRefGoogle ScholarPubMed
13.Li, WC, Chen, IC, Chang, YCet al. (2013) Waist-to-height ratio, waist circumference, and body mass index as indices of cardiometabolic risk among 36,642 Taiwanese adults. Eur J Nutr 52, 5765.CrossRefGoogle Scholar
14.Ashwell, M & Hsieh, SD (2005) Six reasons why the waist-to-height ratio is a rapid and effective global indicator for health risks of obesity and how its use could simplify the international public health message on obesity. Int J Food Sci Nutr 56, 303307.CrossRefGoogle ScholarPubMed
15.Can, AS, Yildiz, EA, Samur, Get al. (2010) Optimal waist:height ratio cut-off point for cardiometabolic risk factors in Turkish adults. Public Health Nutr 13, 488495.Google ScholarPubMed
16.Mombelli, G, Zanaboni, AM, Gaito, Set al. (2009) Waist-to-height ratio is a highly sensitive index for the metabolic syndrome in a Mediterranean population. Metab Syndr Relat Disord 7, 477484.CrossRefGoogle Scholar
17.Lim, LL, Seubsman, SA, Sleigh, Aet al. (2012) Validity of self-reported abdominal obesity in Thai adults: a comparison of waist circumference, waist-to-hip ratio and waist-to-stature ratio. Nutr Metab Cardiovasc Dis 22, 4249.CrossRefGoogle ScholarPubMed
18.Ergor, G, Soysal, A, Sozmen, Ket al. (2012) Balcova heart study: rationale and methodology of the Turkish cohort. Int J Public Health 57, 535542.CrossRefGoogle ScholarPubMed
19.Ünal, B, Sözmen, K, Uçku, Ret al. (2013) High prevalence of cardiovascular risk factors in a Western urban Turkish population: a community-based study. Anadolu Kardiyol Derg 13, 917.Google Scholar
20.Framingham Heart Study (2012) Framingham 10 years Coronary Heart Disease Risk. http://www.framinghamheartstudy.org/risk/coronary.html (accessed November 2012).Google Scholar
21.Song, Y, Lee, K, Sung, Jet al. (2012) Genetic and environmental relationships between Framingham Risk Score and adiposity measures in Koreans: the Healthy Twin study. Nutr Metab Cardiovasc Dis 22, 503509.CrossRefGoogle ScholarPubMed
22.Wilson, PW, D'Agostino, RB, Levy, Det al. (1998) Prediction of coronary heart disease using risk factor categories. Circulation 97, 18371847.CrossRefGoogle ScholarPubMed
23.Tsigos, C, Hainer, V, Basdevant, Aet al. (2008) Management of obesity in adults: European clinical practice guidelines. Obes Facts 1, 106116.CrossRefGoogle ScholarPubMed
24.Narksawat, K, Podang, J, Punyarathabundu, Pet al. (2007) Waist circumference, body mass index and health risk factors among middle aged Thais. Asia Pac J Public Health 19, 1015.CrossRefGoogle ScholarPubMed
25.Klein, S, Allison, DB, Heymsfield, SBet al. (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. Diabetes Care 30, 16471652.CrossRefGoogle Scholar
26.Alberti, KG, Zimmet, P & Shaw, J (2006) Metabolic syndrome – a new world-wide definition. A Consensus Statement from the International Diabetes Federation. Diabet Med 23, 469480.CrossRefGoogle ScholarPubMed
27.Grundy, SM, Cleeman, JI, Daniels, SRet al. (2005) Diagnosis and management of the metabolic syndrome: an American Heart Association/National Heart, Lung, and Blood Institute Scientific Statement. Circulation 112, 27352752.CrossRefGoogle ScholarPubMed
28.Sanisoglu, SY, Oktenli, C, Hasimi, Aet al. (2006) Prevalence of metabolic syndrome-related disorders in a large adult population in Turkey. BMC Public Health 6, 92.CrossRefGoogle Scholar
29.Bagriacik, N, Onat, H, Ilhan, Bet al. (2009) Obesity profile in Turkey. Int J Diabetes Metab 17, 58.Google Scholar
30.Erem, C, Arslan, C, Hacihasanoglu, Aet al. (2004) Prevalence of obesity and associated risk factors in a Turkish population (Trabzon city, Turkey). Obes Res 12, 11171127.CrossRefGoogle Scholar
31.Hsieh, SD & Muto, T (2005) The superiority of waist-to-height ratio as an anthropometric index to evaluate clustering of coronary risk factors among non-obese men and women. Prev Med 40, 216220.CrossRefGoogle ScholarPubMed
32.Park, SH, Choi, SJ, Lee, KSet al. (2009) Waist circumference and waist-to-height ratio as predictors of cardiovascular disease risk in Korean adults. Circ J 73, 16431650.CrossRefGoogle ScholarPubMed
33.Schneider, HJ, Friedrich, N, Klotsche, Jet al. (2010) The predictive value of different measures of obesity for incident cardiovascular events and mortality. J Clin Endocrinol Metab 95, 17771785.CrossRefGoogle ScholarPubMed
34.Chehrei, A, Sadrnia, S, Keshteli, AHet al. (2007) Correlation of dyslipidemia with waist to height ratio, waist circumference, and body mass index in Iranian adults. Asia Pac J Clin Nutr 16, 248253.Google ScholarPubMed
35.Silva, DA, Petroski, EL & Peres, MA (2013) Accuracy and measures of association of anthropometric indexes of obesity to identify the presence of hypertension in adults: a population-based study in Southern Brazil. Eur J Nutr 52, 237246.CrossRefGoogle ScholarPubMed
36.Lee, CM, Huxley, RR, Wildman, RPet al. (2008) Indices of abdominal obesity are better discriminators of cardiovascular risk factors than BMI: a meta-analysis. J Clin Epidemiol 61, 646653.CrossRefGoogle ScholarPubMed
37.Hsieh, SD & Muto, T (2006) Metabolic syndrome in Japanese men and women with special reference to the anthropometric criteria for the assessment of obesity: proposal to use the waist-to-height ratio. Prev Med 42, 135139.CrossRefGoogle Scholar
38.Can, AS, Bersot, TP, Gonen, Met al. (2009) Anthropometric indices and their relationship with cardiometabolic risk factors in a sample of Turkish adults. Public Health Nutr 12, 538546.CrossRefGoogle Scholar
39.He, Y, Zhai, F, Ma, Get al. (2009) Abdominal obesity and the prevalence of diabetes and intermediate hyperglycaemia in Chinese adults. Public Health Nutr 12, 10781084.CrossRefGoogle ScholarPubMed
40.He, YH, Chen, YC, Jiang, GXet al. (2012) Evaluation of anthropometric indices for metabolic syndrome in Chinese adults aged 40 years and over. Eur J Nutr 51, 8187.CrossRefGoogle ScholarPubMed
41.Mellati, AA, Mousavinasab, SN, Sokhanvar, Set al. (2009) Correlation of anthropometric indices with common cardiovascular risk factors in an urban adult population of Iran: data from Zanjan Healthy Heart Study. Asia Pac J Clin Nutr 18, 217225.Google Scholar
42.Berber, A, Gomez-Santos, R, Fanghanel, Get al. (2001) Anthropometric indexes in the prediction of type 2 diabetes mellitus, hypertension and dyslipidaemia in a Mexican population. Int J Obes Relat Metab Disord 25, 17941799.CrossRefGoogle Scholar
43.Shimajiri, T, Imagawa, M, Kokawa, Met al. (2008) Revised optimal cut-off point of waist circumference for the diagnosis of metabolic syndrome in Japanese women and the influence of height. J Atheroscler Thromb 15, 9499.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Health status of the participants according to gender: Turkish men and women participating in the baseline survey of the Heart of Balcova Project, 2007–2009

Figure 1

Table 2 Association of anthropometric measurements with CHD risk* according to gender: Turkish men and women (n 10 878) participating in the baseline survey of the Heart of Balcova Project, 2007–2009

Figure 2

Fig. 1 Receiver-operating characteristic curves of anthropometric measurements (- - - - - , BMI; – – – – –, waist circumference; — — —, waist:hip ratio; – - – - –, waist:height ratio) for the prediction of CHD risk (as expressed by medium or high Framingham risk score) among Turkish men (n 3510) participating in the baseline survey of the Heart of Balcova Project, 2007–2009. ——— is the reference line; diagonal segments are produced by ties

Figure 3

Fig. 2 Receiver-operating characteristic curves of anthropometric measurements (- - - - - , BMI; – – – – –, waist circumference; — — —, waist:hip ratio; – - – - –, waist:height ratio) for the prediction of CHD risk (as expressed by medium or high Framingham risk score) among Turkish women (n 7368) participating in the baseline survey of the Heart of Balcova Project, 2007–2009. ——— is the reference line; diagonal segments are produced by ties

Figure 4

Table 3 AUC values for anthropometric measurements in estimating CHD risk* according to gender: Turkish men and women (n 10 878) participating in the baseline survey of the Heart of Balcova Project, 2007–2009

Figure 5

Table 4 Association between CHD risk* and abdominal obesity indices: Turkish men and women (n 10 878) participating in the baseline survey of the Heart of Balcova Project, 2007–2009

Figure 6

Table 5 Odds ratios and 95 % confidence intervals of high WHtR for predicting CHD risk* stratified by BMI category: Turkish men and women (n 10 878) participating in the baseline survey of the Heart of Balcova Project, 2007–2009