India leads the world with 40·9 million individuals with diabetes and this number is projected to rise to 69·9 millions by the year 2025(Reference Sicree, Shaw, Zimmet and Gan1). Although genetic causes and physical inactivity have been shown, at least in part, to explain the increased susceptibility to insulin resistance and type 2 diabetes in Asian Indians(Reference Mohan2, Reference Mohan, Gokulakrishnan and Deepa3), very little is known about specific dietary factors in conferring the risk of type 2 diabetes in this ethnic group.
Cereal-based carbohydrates provide the bulk of the energy in Asian Indian diets(4). In the past, these carbohydrates have been derived from whole grains. However, today, they are replaced with refined carbohydrates, predominantly from rice, due to modern milling technology(Reference Chattopadhyay, Toriyama, Heong and Hardy5). It is known that high-carbohydrate diets raise plasma glucose, insulin, TAG and NEFA and thus contribute to insulin resistance(Reference Wolever and Mehling6).
In addition to the quantity, the quality of carbohydrate is also important, particularly its ability to raise glucose levels. Glycaemic index (GI) indicates the glucose-raising effect of a food in comparison with a standard glucose-containing equivalent amount of carbohydrate whereas glycaemic load (GL) is a product of the GI and available carbohydrate content per serving of the food and both have been shown to increase risk of type 2 diabetes in both Western and Asian populations(Reference Villegas, Liu and Gao7–Reference Schulze, Liu and Rimm13). However, some studies report no association between carbohydrates, or GL and diabetes risk(Reference Meyer, Kushi and Jacobs14–Reference Lundgren, Bengtsson and Blohme16).
Studies have been done in the West where carbohydrates usually do not form the bulk of the energy and also among Asian countries, particularly China and Japan, where the diet is high in carbohydrates(Reference Villegas, Liu and Gao7, Reference Murakami, Sasaki and Takahashi17). However, the present study is unique, as it was conducted among Asian Indians who are at much higher risk of diabetes(Reference Mohan, Shanthirani and Deepa18) and premature coronary artery disease(Reference McKeigue19, Reference Reddy and Yusuf20) and also habitually consume a high-carbohydrate diet. Thus, we felt it would be of interest to study the relationship between total carbohydrate intake (quantity), GL (quality and quantity of carbohydrates), carbohydrate-rich food groups and type 2 diabetes among an urban Asian Indian population in Chennai, India.
Methods and subjects
Participants were recruited from the urban component of the Chennai Urban Rural Epidemiology Study (CURES), conducted on a representative population of Chennai city (formerly Madras) in southern India, with a population of about 5 million individuals. The methodology of the study has been published elsewhere(Reference Deepa, Pradeepa and Rema21) and our website http://www.drmohansdiabetes.com provides details of the sampling frame. Briefly, Chennai is divided into 155 corporation wards, representing a socio-economically diverse group. In phase I of CURES, 26 001 adults (aged ≥ 20 years) from forty-six corporation wards were screened for diabetes using a systematic random sampling technique. Phase 2 of CURES deals with studies on the prevalence of complications of diabetes and both these phases are not discussed further.
In phase 3 of CURES, every tenth participant recruited in phase 1 (n 2600) was invited to our centre for detailed biochemical tests. Of these, 2220 participants took part in the dietary assessment study, of whom participants with a self-reported history of diabetes (n 114), CVD, hypertension or drug therapy of dyslipidaemia (n 42), with missing information on physical activity (n 11) and with reported energy intake of < 2092 kJ or >17 573 kJ/d ( < 500 or >4200 kcal/d) (n 210) were excluded(Reference Michles, Welch and Luben22). Thus, a total of 1843 participants were included for the present analysis. The protocol for the study was approved by the Institutional Ethics Committee of the Madras Diabetes Research Foundation and written informed consent was obtained from all study participants.
Ascertainment of outcome
An oral glucose tolerance test was performed after 8–10 h of overnight fasting. Participants were instructed on the day before the test to report between 06.00 and 07.00 hours after abstaining from alcohol and to remain fasting (except for water) after the last meal which was to be consumed before 21:00 hours the previous evening. If the participant did not follow the instructions or in the case of any unexpected illness, appointments were rescheduled and the instructions reinforced again. Blood samples were collected before and 2 h after a glucose load consisting of 75 g glucose in 250 ml water. Blood samples were stored at − 70°C until the assays were performed and all biochemical analyses were done on a Hitachi 912 auto-analyser (Hitachi, Mannheim, Germany) utilising kits supplied by Roche Diagnostics (Mannheim, Germany). Diagnosis of diabetes was based on WHO Consulting Group criteria, i.e. fasting plasma glucose ≥ 1260 mg/l (7 mmol/l) or 2 h post-load plasma glucose ≥ 2000 mg/l ( ≥ 11·1 mmol/l)(Reference Alberti and Zimmet23).
Ascertainment of covariates
Anthropometric measurements including height, weight and waist measurements were measured by the trained research assistants, using standardised techniques as described earlier(Reference Deepa, Pradeepa and Rema21). Height and weight were measured in light clothing without shoes. The BMI was calculated using the formula: weight (kg)/height (m2). Waist circumference was measured horizontally midway between the lowest rib margin and the iliac crest at minimal respiration and hip circumference was measured at the widest level over the greatest trochanters. Sociodemographic information, medical history, medications, family history of diabetes, smoking and alcohol consumption were also obtained. Details on physical activity were assessed using a previously validated physical activity questionnaire(Reference Mohan, Gokulakrishnan and Deepa3).
Assessment of carbohydrates, glycaemic load and other food groups
Interviews were conducted to collect dietary intakes using a validated meal-based semi-quantitative FFQ containing 222 food items to estimate the usual food intake over the past year. A detailed description of this FFQ and the data on reproducibility and validity have been published elsewhere(Reference Sudha, Radhika and Sathya24). The energy-adjusted de-attenuated correlation coefficient for estimates from the questionnaire and the six 24 h recalls were 0·72 for carbohydrates (g), 0·51 for GI, 0·54 for GL, 0·70 for refined cereals (g), 0·65 for pulses (g), 0·60 for tubers (g), 0·71 for sugars (g), 0·28 for fruits and vegetables (g) and 0·68 for dairy products (g). The ability of this FFQ to assess dietary carbohydrates and GL was evident in a study that evaluated the relationship of these two variables to HDL-cholesterol levels and TAG levels among men and women(Reference Radhika, Ganesan and Sathya25).
Individuals were asked to estimate the usual frequency (number of times per day/week/month/year or never) and their usual serving size of the given portion size of the various food items. Common household measures such as cups, ladles, spoons, wedges and circles and a visual atlas were shown. Participants were also asked to specify type of cereals usually consumed. Refined grains were defined as foods in which the bran and germ layer are removed, with loss of dietary fibre, vitamins and minerals, leaving the starchy endosperm and included polished white rice, vermicelli, semolina and white flour-based products. To avoid confounding by body size, physical activity and metabolic efficiency and reduce extraneous variation, dietary carbohydrates and GL were adjusted for total energy intake using the residual method(Reference Willet, Howe and Kushi26).
Nutrient intakes were calculated for each participant using an in-house EpiNu India® database developed by our team(Reference Sudha, Radhika and Sathya24). Weighted dietary GI for each participant was calculated by summing the products of daily available carbohydrate content per portion for each food item multiplied by the usual serving size and the average frequency per d multiplied by its GI, divided by the total daily carbohydrate intake. Available carbohydrate intake was calculated as total carbohydrate minus total dietary fibre wherever direct measurements were not available.
The GL of the individual food was calculated by multiplying the dietary GI by the total amount of available carbohydrate intake and multiplied by the frequency of consumption and summed to obtain average daily dietary GL. Since there are no national food composition tables containing values of Indian foods for GI, for single foods we used the 2002 international table of GI and GL values(Reference Foster-Powell, Holt and Brand-Miller27); for mixed Indian meals, the GI was derived from the GI of the individual foods as proposed by FAO/WHO in 1998(28). As there is likelihood of wide variation in the rice varieties, GI testing was done in-house for the common white polished rice variety using standardised international methodology(28), and substituted in the EpiNu database.
Statistical analysis
All analyses were conducted using the SPSS statistical software package (version 12.0; SPSS Inc., Chicago, IL, USA). In separate models, first-order interactions between sex and carbohydrates were entered to determine whether association was similar between men and women. There was no interaction by sex on the association of total carbohydrate and GL and therefore we present results for men and women combined. Subjects were divided into quartiles of total carbohydrate, GL and specific food groups and the mean of each is reported and compared for the descriptive characteristic. One-way ANOVA (continuous variables) and the χ2 test (for proportions) were used to test differences across quartiles.
To evaluate the relationship of carbohydrates, GL and dietary fibre, logistic regression analysis was carried out to calculate the OR and 95 % CI for diabetes, comparing individuals in the highest with those in the lowest quartile as the reference category with adjustment for age (quintiles), sex (males, females) smoking (current, past and never smokers; smokers – smoked at least one cigarette per d for more than 6 months), alcohol (current, past and never consumers: having ever consumed spirits, wine or beer for more than 6 months), household income in Indian rupees ( < 2000, 2000–5000, 5000–10 000, >10 000), BMI (continuous), physical activity (strenuous, moderate and sedentary), family history of diabetes (first-degree family history: yes or no), total energy (kJ) and dietary fibre (g/1000 kJ). To assess trend across quartiles, we assigned median intake of each quartile category to individuals with intakes in that category and then included this quartile median variable as a continuous factor in logistic regression models.
Results
The study comprised of 1843 participants (771 men and 1072 women) with a mean age of 39·8 (sd 13·0) years. For men, the median unadjusted total dietary carbohydrate intake was 406 (sd 117) g/d, GI was 69 (sd 3), GL was 277 (sd 86) and dietary fibre was 2·87 (sd 0·7) g/1000 kJ; for women, the corresponding values were 402 (sd 124) g/d, 69 (sd 2), 276 (sd 89) and 2·94 (sd 0·7) g/1000 kJ, respectively.
Table 1 shows the association of energy-adjusted total carbohydrate with baseline characteristics. Individuals in the higher quartiles were older, with greater BMI; a greater proportion of individuals were physically inactive and there were fewer smokers or alcohol consumers, but there were lower intakes of dietary fat and fibre.
* Quartiles of energy-adjusted carbohydrate using the residual method.
Table 2 shows the association of energy-adjusted GL with baseline characteristics. Subjects in the higher intake of dietary GL tended to be older, exercised less, had a higher BMI and waist circumference but had a lower intake of dietary fat. No association was observed between family history of diabetes and total carbohydrates, or GL intake.
* Quartiles of energy-adjusted glycaemic load using the residual method.
Table 3 shows the association of carbohydrate-specific food groups with type 2 diabetes. Refined grain intake was positively associated with type 2 diabetes in the unadjusted model. The OR for the highest quartile of refined grain, after adjustment for age, sex, BMI, income, physical activity, family history of diabetes, smoking, alcohol and dietary fibre, was 5·31 (95 % CI 2·98, 9·45; P < 0·001). In multivariate analysis, higher intakes of fruits and vegetables (OR 0·77 (95 % CI 0·48, 1·23); P < 0·001) and dairy products (OR 0·54 (95 % CI 0·33, 0·86); P < 0·001) were inversely associated with type 2 diabetes. Added sugar in food preparation, legumes and tubers did not show any association with type 2 diabetes.
T2DM, type 2 diabetes mellitus.
* The adjusted model was adjusted for age (years in quintiles), sex (males, females), BMI (continuous), family history of diabetes (three categories), cigarette smoking (categorised as non-smokers and habitual smokers), alcohol (never, past and current consumers), physical activity (strenuous, moderate, sedentary) and income in Indian rupees ( < 2000, 2000–5000, >5000–10 000, >10 000).
† Tests for linear trend were conducted across increasing categories by treating the medians of intake in categories as continuous variables.
We examined the association of dietary carbohydrates with type 2 diabetes (Table 4). Dietary carbohydrates were positively associated with type 2 diabetes in the unadjusted model. The OR for diabetes for the highest quartile of total carbohydrate, after adjustment for age, sex, BMI, income, physical activity, family history of diabetes, smoking, alcohol and dietary fibre, was 4·55 (95 % CI 2·49, 8·29; P < 0·001). We also observed a positive association between GL and type 2 diabetes (OR 4·25 (95 % CI 2·33, 7·77); P < 0·001). GI was also positively associated with type 2 diabetes, but the OR of 2·51 (95 % CI 1·42, 4·43; P = 0·006) was lower than that for GL. The observed association of carbohydrate intake and GL with diabetes remained unchanged even when waist or waist:hip ratio and fruit and vegetable intake were included in the model. Dietary fibre appeared to have a protective effect on type 2 diabetes, as the OR for diabetes was 0·31 (95 % CI 0·15, 0·62; P < 0·001) after adjustment for the major risk factors including family history of diabetes, smoking, alcohol, physical activity and total carbohydrates.
T2DM, type 2 diabetes mellitus.
* The adjusted model controlled for age (years in quintiles), sex (males, females), BMI (continuous), family history of diabetes (three categories), cigarette smoking (categorised as non-smokers and habitual smokers), alcohol (never, past and current consumers), physical activity (strenuous, moderate, sedentary) and income in Indian rupees ( < 2000, 2000–5000, >5000–10 000, >10 000). There was additional adjustment for dietary fibre (for the carbohydrate and glycaemic load models) and for carbohydrate (for the fibre model).
† Tests for linear trend were conducted across increasing categories by treating the medians of intake in categories as continuous variables.
‡ Energy adjusted using the residual method.
Fig. 1 shows that the risk (OR) of type 2 diabetes after multivariate adjustment was 2·91 (95 % CI 1·78, 4·77; P < 0·0001) among subjects with higher GL (>median) but had no family history of diabetes with reference to no family history of diabetes and consuming GL less than the median. However, the highest risk of diabetes was observed among subjects who had a positive family history of diabetes and also consumed a higher GL (OR 3·67 (95 % CI 1·94, 6·97); P < 0·0001).
Discussion
To our knowledge, this is the first population-based study to examine the association between carbohydrate-specific dietary factors and risk of type 2 diabetes in an Asian Indian population. After adjustment for several risk factors for diabetes, the findings show a positive association between dietary carbohydrates, GL and refined grains while dietary fibre, fruits and vegetables and dairy products had a negative association.
In traditional Asian Indian diets, before the advent of mechanical milling, hand pounding of rice was in practice and hence there was better retention of the bran and germ. While modernisation and the growth of rice mills (seven modern rubber-roll sheller mills in 1963 in India compared with 35 088 in 1999) have led to an increased total rice yield, unfortunately the coarse grain has been replaced by a highly refined rice grain with starchy endosperm(Reference Chattopadhyay, Toriyama, Heong and Hardy5, Reference Juliano29). In the present study, refined grain was positively associated with type 2 diabetes, particularly polished white rice being the major contributor; this result is consistent with our previous study findings of association with components of the metabolic syndrome(Reference Radhika, Van Dam and Sudha30). These findings corroborate those of Burkitt(Reference Burkitt31), who correlated the introduction of roller mills in the USA and the West with a large number of diseases including diabetes.
We found that total carbohydrate intake was much higher in the present study (first quartile 294 g/d; fourth quartile 587 g/d) compared with that reported in Westerners (first quintile 162 g/d; fifth quintile 238 g/d)(Reference Liu, Manson and Stampfer32) and in another Asian (Chinese) population (first quintile 233·3 g/d; fifth quintile 321·9 g/d)(Reference Villegas, Liu and Gao7). However, the percentage of carbohydrates contributing to total energy was 65·6 %, which is not much higher than that recommended by the WHO guidelines of 55–65 % for the prevention of chronic diseases(33). Bread, potatoes and sugar added in soft drinks are the main sources of dietary carbohydrates in Western populations(Reference Van Dam, Rimm and Willett34). However, in south Indians, neither tubers nor sugars were associated with type 2 diabetes. These results were consistent with previous studies(Reference Hodge, English and O'Dea35–Reference Liu, Serdula and Janket37). In India, tubers are consumed more as an accompaniment and sugar intake was mainly as added sugar in hot beverages (tea and coffee). In this population, the carbohydrate was predominantly derived from polished white rice (66·1 % of total carbohydrate intake). In addition, those who eat more rice, also eat less of virtually all other foods such as legumes, tubers, fruits and vegetables and dairy products.
Epidemiological data on dietary carbohydrates and type 2 diabetes are not consistent(Reference Meyer, Kushi and Jacobs14–Reference Lundgren, Bengtsson and Blohme16). In a cross-sectional study among Japanese female farmers(Reference Murakami, Sasaki and Takahashi17), GL and GI were positively associated with fasting plasma glucose, whereas no correlation was observed among elderly women(Reference Van Dam, Visscher and Feskens38). It is known that the association between dietary carbohydrates and type 2 diabetes may be mediated through other components, for example, low cereal dietary fibre(Reference Meyer, Kushi and Jacobs14). However, in the present study, the association between dietary carbohydrates and GL and diabetes remained unchanged even after adjustment for total dietary fibre. This suggests that carbohydrate intake and GL may be independent risk factors for type 2 diabetes in Asian Indians. In the present study GI was also associated with type 2 diabetes; however, the association was stronger for GL than for GI. It is likely that both genes and the environment, particularly diet, act together and have a cumulative effect on the risk of type 2 diabetes. Hence, in the present study, we studied the combined effect of GL and family history of diabetes in increasing the risk of type 2 diabetes. We found that while both family history and GL were independently associated with type 2 diabetes risk, the highest risk was observed among those subjects with a higher intake of GL who also had a positive family history of diabetes.
Our findings are consistent with previous prospective cohort studies(Reference Villegas, Liu and Gao7, Reference Salmeron, Manson and Stampfer9, Reference Salmeron, Ascherio and Rimm12, Reference Schulze, Liu and Rimm13) that have reported an association between GL and risk of type 2 diabetes. In the Nurses' Health Study, women with the highest dietary GL were 37 % more likely to develop type 2 diabetes mellitus than with the lowest dietary GL(Reference Salmeron, Manson and Stampfer9). Similarly, both among Chinese women(Reference Villegas, Liu and Gao7), and in an elderly Dutch population(Reference Feskens, Bowles and Kromhout8), a positive association was observed with GL and type 2 diabetes. Indeed, a meta-analysis of thirty-seven prospective studies involving nearly two million participants provides evidence that diets with a high GI, high GL, or both, are independently associated with an increased risk of type 2 diabetes(Reference Barclay, Petocz and Joanna39). However, the results are not consistent, as no association was observed in the Iowa Women's Health Study(Reference Meyer, Kushi and Jacobs14), and a borderline association with GL was noted in the Atherosclerosis Risk in the Communities (ARIC) Study(Reference Stevens, Ahn and Juhaeri15). These differences observed could be related to methodological issues. In the Iowa study, diagnosis of diabetes was based entirely on self-reported cases whereas the present study included newly detected subjects diagnosed by the oral glucose tolerance test. In self-reported diabetic subjects, dietary changes could have been made as a result of therapy. The ARIC study did not distinguish between type 1 and type 2 diabetes(Reference Stevens, Ahn and Juhaeri15). Misclassification of either exposure or disease status could have led to underestimation of the association in these studies.
We detected an inverse association for total dietary fibre, fruit and vegetable intake and diabetes risk. A similar association was observed in both the Iowa Women's Health Study(Reference Meyer, Kushi and Jacobs14) and the Nurses' Health Study(Reference Salmeron, Manson and Stampfer9). In contrast, no significant association was observed in the Health Professionals study and in the ARIC study(Reference Stevens, Ahn and Juhaeri15). We have previously reported an inverse association between fruit and vegetable intake and cardiovascular risk factors(Reference Radhika, Sudha and Sathya40), but diabetes was not included in that study. In the present study, 3–4 % fat milk was the predominantly consumed dairy product in this population. However, the mechanism behind the inverse association between dairy products and risk of type 2 diabetes remains unclear. Components such as Ca, vitamin D, Mg, P and dairy protein present in dairy products(Reference Anastassios, Joseph and Hu41) have been shown to reduce the risk of type 2 diabetes and obesity.
Several mechanisms have been proposed to explain how the long-term consumption of carbohydrates may increase the risk of type 2 diabetes. The same amount of carbohydrates from high-GI foods produces a higher blood glucose concentration and a greater demand for insulin compared with low-GI foods. The prolonged increase in insulin demand may eventually result in pancreatic β cell exhaustion and thus lead to diabetes(Reference Wolever and Mehling6). It is therefore clearly important to reduce the high GL of the diet either by reducing the carbohydrate content, or by increasing the intake of low-GI foods, or both.
The present study shows that both quantity of carbohydrates (total carbohydrate) and the quality of carbohydrates (GL) are important risk factors for type 2 diabetes in this population. It is unlikely that the total carbohydrate content of south Asian diets can be altered. It thus appears prudent to encourage the introduction of low-GI foods in the market as well as to promote high-fibre foods to reduce the total dietary GL. Increasing awareness about the consequences of consuming higher-GL diets is also necessary. These measures could be included as policies to be adopted in the National Programme for Prevention and Control of Diabetes/Cardiovascular Diseases and Stroke recently launched by the Government of India(42).
The present study has several limitations. First, being a cross-sectional study, it does not allow us to infer causation nor does it permit us to explore the temporal sequence of events between the consumption of carbohydrate-rich foods and development of type 2 diabetes. Second, although we have adjusted for various potential confounders, as in any observational study, residual confounding by unknown or imperfectly measured factors cannot be excluded. Third, there could be possible errors in the dietary calculation mainly resulting from the limited availability of food composition data, particularly with reference to available carbohydrates and dietary fibre among Indian foods. Fourth, adequate food and nutrition labelling on the Indian products limited our definition of refined grains. Fifth, some measurement error is inevitable in the assessment of dietary intakes of a population. However, our validation study indicated that the assessment of dietary carbohydrates, GI and GL using a detailed interviewer-administered FFQ was reasonably accurate(Reference Sudha, Radhika and Sathya24). Moreover, measurement error would be expected to weaken rather than strengthen the observed association.
The study also has several strengths, including the relatively large sample size, the use of newly detected diabetic subjects, the unique ethnic group on whom no data are available and the detailed information on diet that was obtained. As we included a representative population of Chennai, the results can be extrapolated to the whole of urban India. Finally, we carefully controlled for well-documented risk factors for diabetes and possible confounders.
In conclusion, our findings indicate that higher dietary carbohydrates and GL are associated with increased, and dietary fibre with decreased, risk of newly diagnosed type 2 diabetes among urban south Indians who habitually consume high-carbohydrate diets.
Acknowledgements
We thank the Chennai Willington Corporate Foundation, Chennai for the CURES field studies. This is the 59th publication from the Chennai Urban Rural Epidemiology Study (CURES 59).
The guarantor is V. M.
V. M. designed the study. G. R., R. M. S. and S. R. T. led the data collection. G. R. and V. S. wrote the first draft of the manuscript and V. M. rewrote the subsequent drafts. A. G. assisted in doing the statistical analysis. V. M., G. R. and V. S. contributed to the interpretation of the data and all contributors participated in the revisions and final draft of the manuscript. They approved the final version and will take public responsibility for the content of this paper.
There are no conflicts of interest with any organisation.