Evaluation of body mass index,waist-to-hip ratio,and waist-to-height ratio as predictors of insulin resistance in Syrian adult women: A cross-sectional study

Introduction

Obesity, as described by the World Health Organization (WHO), is a chronic, relapsing disease arising from multiple interacting factors, including genetics, neurobiology, the broader environment, and eating behaviors. ¹ In 2022, 2.5 billion adults aged ≥18 years were overweight, of whom more than 890 million adults were obese. Additionally, more than 390 million children and adolescents were overweight in 2022. ¹ This epidemic is closely linked to an increased risk of cardiovascular disease, type 2 diabetes mellitus (T2DM), various cancers, and metabolic syndrome, conditions that collectively result in millions of avoidable deaths each year. ² The pathophysiological basis of these complications is largely attributed to the relationship between obesity and insulin resistance (IR). ³ This relationship is complex and has been linked to a wide range of molecular processes, including inflammatory, neural, and endocrine pathways, that affect the sensitivity of organs to insulin, leading to decreased insulin-stimulated glucose transport and metabolism in adipocytes and skeletal muscle as well as impaired suppression of hepatic glucose output. ⁴ The homeostasis model assessment of insulin resistance (HOMA-IR) was introduced by Matthews et al. in 1985 to estimate insulin sensitivity using fasting plasma glucose and insulin concentrations. ⁵ This test is a safe, low-cost method used as an accurate clinical and epidemiological tool to describe the pathophysiology of diabetes. ⁶

Anthropometric measures such as body mass index (BMI), waist-to-hip ratio (WHR), and waist-to-height ratio (WHtR) are often used in clinical practice due to their low cost and convenience. BMI, calculated as weight divided by height squared, is used to screen for macronutritional status. This anthropometric index is widely used for classifying underweight, overweight, and obesity. ⁷ Its simplicity, affordability, and reproducibility have made it a cornerstone of epidemiological studies and clinical practice. However, BMI has notable limitations, as it is unable to distinguish between lean and fat mass and does not inform practitioners of either the origin or the heterogeneity of obesity and its outcomes in specific individuals or populations. ⁸ WHR, derived from waist circumference divided by hip circumference, is more strongly related to visceral fat than to subcutaneous fat. ⁹ Visceral fat is metabolically active and secretes pro-inflammatory cytokines such as tumor necrosis factor-alpha (TNF-α); interleukin (IL)-6 (IL-6), IL-13, and IL-18; and adipokines such as leptin and resistin, which impair insulin signaling. ¹⁰ The prevalence of WHR-defined obesity was approximately three times that of BMI-defined obesity. Individuals with WHR-defined obesity also had significantly higher metabolic complications, including hypertension (57%), dyslipidemia (62%), and IR (14%). ¹¹ Several studies have reported significant positive correlations between BMI and HOMA-IR, reinforcing the role of overall adiposity in metabolic impairment. Raju et al. reported a significant positive correlation (r = 0.64, p < 0.001) between BMI and the HOMA-IR index in prediabetic individuals. ¹² Similarly, Raj et al. reported a positive correlation between BMI and the HOMA-IR index in 100 apparently normal participants. ¹³ However, other investigations highlight the superior predictive value of WHR and related indices. Liu et al. showed that visceral fat accumulation, rather than subcutaneous fat, was more strongly associated with IR in 107 Chinese participants with prediabetes. ¹⁴ Zhu et al. and Benites-Zapata et al. further highlighted WHR as a sensitive marker of IR, particularly in women and high-risk populations.^15,16 WHtR, a newer index for abdominal fat assessment, has the advantage of a unisex cutoff value of 0.5. ¹⁷ A recent meta-analysis on studies evaluating different indices of adiposity showed that WHtR was a better predictor of central obesity and cardiovascular risk in the general population and in people with type 2 diabetes, in both men and women. ¹⁸

Despite extensive research on the relationship between different anthropometric measurements and IR, the relative contributions of BMI, WHR, and WHtR to IR remain debated. Additionally, to the best of our knowledge no information exists on the application of these anthropometric indicators for the detection of IR in Syrian women. Taking into account that ethnicity may influence body composition, this study was therefore designed to evaluate correlations among BMI, WHR, WHtR, and HOMA-IR in a cohort of Syrian adult women.

Materials and methods

Results and discussion

IR is significantly associated with the occurrence of a wide variety of chronic diseases, including diabetes, cardiovascular diseases, and metabolic syndrome. ²² Therefore, early identification and management of IR could be of great significance in preventing related diseases. Currently, biochemical examinations, including HOMA-IR, euglycemic–hyperinsulinemic clamp, Quantitative Insulin Sensitivity Check Index (QUICKI), Matsuda Index, and Insulin Secretion-Sensitivity Index-2 (ISSI-2), are the most commonly used parameters for IR detection. ²³ However, all these examinations are complex, expensive, and invasive and require specialized equipment and trained professionals. In recent studies, anthropometric measurements such as BMI, WHR, and WHtR have been shown to be cost-effective, rapid, and safe tools for IR prediction and detection. ²⁴

Before examining the associations between anthropometric indices and IR, the baseline characteristics of the study population were summarized. Table 1 presents the distribution of age, height, weight, waist and hip circumferences, BMI, WHR, WHtR, and HOMA-IR among the 70 participating Syrian women, providing essential context for interpreting the subsequent analyses.

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Table 1.

Baseline anthropometric and biochemical characteristics of the study population (n = 70). Values are presented as mean ± SD with observed ranges.

Variable	Mean ± SD	Range
Age (years)	26.88 ± 7.4	17–46
Height (cm)	163.97 ± 5.9	150–175
Weight (kg)	81.5 ± 20.0	50–163
Waist circumference (cm)	87.83 ± 17.0	50–163
Hip circumference (cm)	110.16 ± 17.3	61–155
BMI (kg/m²)	30.34 ± 7.1	17.3–72.4
WHR	0.79 ± 0.09	0.53–1.10
WHtR	0.53 ± 0.11	0.34–0.89
HOMA-IR	3.03 ± 1.63	0.8–8.6

BMI: body mass index; WHR: waist-to-hip ratio; WHtR: waist-to-height ratio; HOMA-IR: homeostasis model assessment of insulin resistance.

Although many studies have found a positive relationship between BMI and IR, the scatter plot illustrated in Figure 1 reveals a weak, non-significant correlation between BMI and HOMA-IR (r = 0.18, p = 0.1338).

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Figure 1.

Scatter plot showing the weak, non-significant correlation between BMI and HOMA-IR in Syrian adult women (n = 70). Pearson correlation analysis showed a weak, non-significant association (r = 0.18, p = 0.1338). BMI: body mass index; HOMA-IR: homeostasis model assessment of insulin resistance.

Uludağ et al. reported that individuals with higher BMI exhibited elevated HOMA-IR values and increased levels of high-sensitivity C-reactive protein (CRP) (hs-CRP), reinforcing the role of inflammation in obesity-related IR. ²⁵ Similarly, Chung et al. found a significant positive correlation between BMI and HOMA-IR among adults with obesity, highlighting BMI’s predictive value for metabolic impairment. ²⁶ However, numerous studies have emphasized the limitations of BMI as a sole measure for predicting IR, as it does not distinguish between lean mass and fat mass nor does it account for fat distribution. Results demonstrated by Meah et al. failed to reveal a significant relationship between BMI and HOMA-IR. ²⁷ Gastaldelli et al. demonstrated that visceral fat accumulation, rather than subcutaneous fat, was more strongly associated with IR. ²⁸ Eboka-Loumingou Sakou et al. suggested that combining BMI with inflammatory markers such as CRP and IL-6 enhances the predictive accuracy for IR. ²⁹

Therefore, complementary measures such as WHR may provide more nuanced insights into metabolic risk. As presented in Figure 2, a statistically significant moderate positive correlation between WHR and HOMA-IR (r = 0.44, p = 0.0001) was observed. This finding supports the hypothesis that central adiposity, as reflected by WHR, is a key contributor to IR. Unlike BMI, WHR captures fat distribution, particularly visceral fat accumulation, which is metabolically active, secreting inflammatory cytokines and adipokines, thereby enhancing IR and predisposing individuals to a wide range of chronic diseases. ³⁰

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Figure 2.

Scatter plot showing the moderate positive correlation between WHR and HOMA-IR in Syrian adult women (n = 70). Pearson correlation revealed a moderate, statistically significant positive correlation (r = 0.44, p = 0.0001). WHR: waist-to-hip ratio; HOMA-IR: homeostasis model assessment of insulin resistance.

Visceral adipose tissue is frequently associated with elevated levels of triglycerides (TG) and low-density lipoprotein (LDL) cholesterol and decreased levels of high-density lipoprotein (HDL) cholesterol, which impair insulin signaling in hepatic and muscular tissues. ³¹ Additionally, oxidative stress and mitochondrial dysfunction in visceral fat exacerbate IR by disrupting glucose metabolism, ³² whereas subclinical inflammation originating in visceral depots further contributes to insulin signaling impairment and metabolic syndrome development. ³³ A cross-sectional study in euthyroid normal-weight nondiabetic women found that high WHR levels were positively correlated with HOMA-IR and serum insulin after oral glucose tolerance test (OGTT) values. ³⁴ Elevated WHR has been found to be associated with dyslipidemia and IR in children. BMI and WHR are both associated with IR. This indicator has also been found to play a role in the assessment of cardiometabolic risk in children. ³⁵ Liu et al. found that WHR was a superior index in reflecting visceral fat distribution and predicting type 2 diabetes risk in populations with obesity. ³⁶ Therefore, interventions targeting visceral fat reduction, including caloric restriction, anti-inflammatory diets, and aerobic exercise, are essential for improving insulin sensitivity.^37,38

One aspect of research on obesity and IR that is currently attracting attention is WHtR. As illustrated in Figure 3, there is a statistically significant strong positive correlation between WHtR and HOMA-IR (r = 0.62, p = 0.0001).

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Figure 3.

Scatter plot showing the significant strong positive correlation between WHtR and HOMA-IR in Syrian adult women (n = 70). Pearson correlation indicated a significant association (r = 0.62, p = 0.0001).

ROC curve analysis, as presented in Table 2, demonstrated meaningful differences in the ability of BMI, WHR, and WHtR to discriminate IR (defined as HOMA-IR ≥ 2.5). ³⁹ WHtR showed the highest discriminative power with an AUC of 0.82 (95% confidence interval (CI): 0.73–0.90), outperforming both BMI (AUC = 0.78) and WHR (AUC = 0.74). The optimal WHtR cutoff for predicting IR in this cohort was 0.58, yielding a sensitivity of 85% and specificity of 74%. BMI also demonstrated acceptable predictive ability, with an optimal cutoff of 28.4 kg/m². WHR showed the lowest predictive performance among the three indices. Although WHR exhibited a stronger linear correlation with HOMA-IR, BMI achieved better classification accuracy in ROC analysis, reflecting the fact that correlation assesses continuous association and ROC analysis evaluates threshold-based discrimination. ⁴⁰ These findings support the use of WHtR as a simple, practical, and superior screening tool for early identification of IR in young Syrian women, consistent with its superior discriminative performance in ROC analysis.

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Table 2.

ROC analysis evaluating the ability of BMI, WHR, and WHtR to predict insulin resistance (defined as HOMA-IR ≥ 2.5). AUC values, 95% CIs, optimal cutoffs, sensitivity, and specificity are shown.

Index	AUC	95% CI	Optimal cutoff	Sensitivity	Specificity
BMI	0.78	0.68–0.87	>28.4	82%	71%
WHR	0.74	0.63–0.84	>0.78	76%	66%
WHtR	0.82	0.73–0.90	>0.58	85%	74%

ROC: receiver operating characteristic; BMI: body mass index; WHR: waist-to-hip ratio; WHtR: waist-to-height ratio; HOMA-IR: homeostasis model assessment of insulin resistance; AUC: area under the curve; CI: confidence interval.

Our results suggest that there are advantages to using WHtR for indicating IR. Recent studies support the predictive value of WHtR. A cross-sectional analysis by Zhu et al. found that WHtR was a strong predictor of IR in women with polycystic ovary syndrome (PCOS) and could be used as a simple, practical, and reliable anthropometric measure to predict the risk of IR in this population. ⁴¹ Jamar et al. found that WHtR was most closely associated with occurrences of IR and predicted the onset of diabetes in individuals with obesity. ⁴² A recent meta-analysis showed that WHtR was a better predictor of hyperinsulinemia and metabolic syndrome than BMI and WHR in both men and women. ⁴³

Limitations and future directions

Because this study used a consecutive sampling approach, the final sample size (n = 70) reflected the number of eligible participants available during the recruitment period, and no a priori sample size calculation was performed. As an exploratory cross-sectional study, the findings provide preliminary evidence rather than definitive predictive thresholds. The relatively small sample size and the exclusive inclusion of Syrian adult women limit the generalizability of our findings. The non-significant correlation observed for BMI may reflect limited statistical power or the narrow age range of participants (17–46 years) rather than a true absence of association. Because the cohort consisted exclusively of women, sex-based comparisons could not be performed, and the results cannot be extrapolated to men. Future studies should therefore include representative samples of both sexes to determine whether WHtR remains superior to BMI and WHR in predicting IR across populations. Additionally, variations in height across different ethnic groups may influence the applicability of WHtR, underscoring the need for larger, multiethnic cohorts to validate these findings and establish population-specific thresholds. ⁴⁴ Furthermore, the cross-sectional design and short study duration limit the ability to infer causality or evaluate long-term metabolic outcomes. Longer-term longitudinal studies with larger and more diverse populations are needed to better understand the mechanisms underlying these associations and to confirm the long-term predictive value of WHtR.

Future research should also examine the utility of WHtR in specific endocrine and metabolic conditions such as PCOS. Additionally, novel anthropometric markers, including the second-to-fourth digit ratio (2D:4D), may provide further insight into predisposition to IR and related comorbidities. Longitudinal studies are needed to determine whether targeting these markers improves long-term metabolic outcomes. A lower 2D:4D ratio (<1) has been associated with higher androgen exposure, increased metabolic risk, and susceptibility to depressive disorders, suggesting that it may serve as a simple, noninvasive predictor of high-risk individuals. Longitudinal studies incorporating 2D:4D measurements alongside traditional anthropometric indices could help clarify its predictive value and potential role in early risk stratification.^45,46

Conclusion

This study suggests that simple anthropometric indices may help in identifying IR among Syrian adult women. Although BMI and WHR showed varying degrees of association with HOMA-IR, WHtR demonstrated the strongest relationship and the highest predictive accuracy. ROC analysis confirmed that WHtR provided the greatest discriminative ability for IR (AUC = 0.82), outperforming both BMI and WHR, with an optimal cutoff of 0.58 offering a favorable balance of sensitivity and specificity. Given its simplicity and low cost, WHtR may represent a practical and effective screening tool for identifying individuals at higher risk of IR in this population, supported by its superior performance in ROC analysis. Nonetheless, the findings are limited by the modest sample size and the exclusive inclusion of women, underscoring the need for larger, multiethnic, and mixed-sex studies to validate these results and establish population-specific thresholds. Continued research integrating additional anthropometric and metabolic markers may further enhance early identification and prevention strategies for IR.