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Dietary glycaemic index and glycaemic load in relation to all-cause and cause-specific mortality in a Japanese community: the Takayama study

Published online by Cambridge University Press:  20 October 2014

Chisato Nagata ,
Keiko Wada ,
Michiko Tsuji ,
Toshiaki Kawachi  and
Kozue Nakamura
Chisato Nagata*
Affiliation:
Department of Epidemiology and Preventive Medicine, Gifu University Graduate School of Medicine, Gifu, Japan
Keiko Wada
Affiliation:
Department of Epidemiology and Preventive Medicine, Gifu University Graduate School of Medicine, Gifu, Japan
Michiko Tsuji
Affiliation:
Department of Epidemiology and Preventive Medicine, Gifu University Graduate School of Medicine, Gifu, Japan Department of Food and Nutrition, Japan Women's University, Tokyo, Japan
Toshiaki Kawachi
Affiliation:
Department of Epidemiology and Preventive Medicine, Gifu University Graduate School of Medicine, Gifu, Japan
Kozue Nakamura
Affiliation:
Department of Epidemiology and Preventive Medicine, Gifu University Graduate School of Medicine, Gifu, Japan Department of Food and Nutrition, Gifu City Women's College, Gifu, Japan
*
*Corresponding author: C. Nagata, fax +81 58 230 6411, email chisato@gifu-u.ac.jp
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Abstract

Diets with a high glycaemic index (GI) or glycaemic load (GL) have been hypothesised to increase the risk of diabetes, CVD and some cancers. In the present study, the associations of dietary GI and GL with the risk of all-cause and cause-specific mortality were prospectively examined in a general population in Japan, where white rice is the main contributor of dietary GI and GL. A total of 28 356 residents of Takayama City, Japan, who responded to a self-administered questionnaire in 1992 were included in the present analyses. Dietary intake was assessed using a validated FFQ. Mortality was ascertained over 16 years. In men, dietary GI was found to be significantly inversely associated with the risk of all-cause and non-cancer, non-cardiovascular mortality; the hazard ratios (HR) for the highest v. lowest quartile were 0·80 (95 % CI 0·68, 0·95) and 0·64 (95 % CI 0·49, 0·84), respectively. Dietary GL was found to be significantly inversely associated with the risk of all-cause, cancer, and non-cancer, non-cardiovascular mortality; the HR for the highest v. lowest quartile were 0·71 (95 % CI 0·59, 0·86), 0·71 (95 % CI 0·52, 0·99) and 0·64 (95 % CI 0·48, 0·87), respectively. The results obtained for the GL derived from white rice, but not from other foods, closely mirrored those obtained for overall GL. In women, dietary GI was found to be significantly positively associated with the risk of cardiovascular mortality; the HR for the highest v. lowest quartile was 1·56 (95 % CI 1·15, 2·13). The results of the present study suggest potential favourable effects of dietary GI and GL on mortality in men, but an association between high GI and an increased risk of cardiovascular mortality in women.

Keywords

Glycaemic indexGlycaemic loadMortalityProspective cohort studies
Type
Full Papers
Information
British Journal of Nutrition , Volume 112 , Issue 12 , 28 December 2014 , pp. 2010 - 2017
Copyright
Copyright © The Authors 2014 

The concept of glycaemic index (GI) was introduced by Jenkins et al. ( Reference Jenkins, Wolever and Taylor 1 ) to quantify the glycaemic response to carbohydrates in different foods. High-GI foods result in high postprandial glucose concentrations that decline rapidly, whereas low-GI foods result in lower postprandial glucose concentrations that decline more gradually( Reference Jenkins, Wolever and Taylor 1 ). Glycaemic load (GL), calculated by summing both the GI value and the amount of carbohydrates in a food, has been proposed as a global indicator that represents both the quality and quantity of carbohydrates( Reference Salmerón, Manson and Stampfer 2 ). High-GI and -GL food consumption may result in a chronic elevation of blood glucose concentrations. Epidemiological studies have suggested that high-GI or -GL diets may increase the risk of diabetes( Reference Greenwood, Threapleton and Evans 3 ), CVD( Reference Ma, Liu and Song 4 ) and some cancers( Reference Gnagnarella, Gandini and La Vecchia 5 ), although most of these studies have been conducted in Western populations. CVD and cancer are the leading causes of death in developed countries, and in addition to cardiovascular death, diabetes has been reported to be associated with premature death from several cancers and other non-CVD( 6 , Reference Sasazuki, Charvat and Hara 7 ). Therefore, dietary GI or GL is suspected to increase the risk of total mortality as well as mortality from relevant diseases. To our knowledge, only one study, the Nurses’ Health Study( Reference Baer, Glynn and Hu 8 ), has reported the association of dietary GL with total mortality; dietary GL has been found to be significantly associated with an increased mortality risk (hazard ratio (HR) per 41 units = 1·22). No study has been carried out on this association in men. In Japan, white rice, a food with a high GI, is consumed as a staple food and is the main contributor of dietary GI and GL. In spite of its high GI value, a high intake of rice has been found to be associated with a decreased risk of death from CVD among Japanese men in a prospective study( Reference Eshak, Iso and Date 9 ). Dietary GI and GL have never been studied in relation to CVD (except stroke( Reference Oba, Nagata and Nakamura 10 )) or cancer in Japan. Especially in rice-consuming populations, it is important to evaluate the associations of dietary GI or GL with the risk of death from a broad range of causes. In the present study, the associations of dietary GI and GL with the risk of all-cause and cause-specific mortality were examined in a population-based cohort of Japanese men and women (the Takayama study).

Methods

The Takayama study

The Takayama study was initiated in 1992 to identify dietary and lifestyle factors that are associated with the morbidity of cancer and various other diseases. A total of 31 552 residents, aged ≥ 35 years, of Takayama City, Gifu Prefecture, Japan, completed a baseline self-administered questionnaire that included questions on demographic characteristics, smoking status, diet, physical activity, and medical and reproductive histories, yielding a participation rate of 85·3 %. The rationale and design of the Takayama study have been described in detail elsewhere( Reference Shimizu 11 ). Subjects who reported having or having had cancer during baseline questionnaire administration (186 men and 540 women), stroke or CHD (886 men and 861 women) were excluded from the present analyses. Subjects who died during the first 3 years of follow-up (402 men and 321 women) were also excluded. In total, 28 356 subjects (12 953 men and 15 403 women) were included in the present analyses.

Dietary intake was assessed using a validated 169-item semi-quantitative FFQ. The subjects were asked to report how often, on average, they consumed each of the food items listed in the questionnaire and what was the usual serving size of each item consumed during the previous year. The intakes of nutrients and foods were estimated from the frequency of consumption and portion size using the Japanese Standard Tables of Food Composition, 5th revised and enlarged edition, published by the Science and Technology Agency of Japan. Fatty acid composition was evaluated using data published by Sasaki et al. ( Reference Sasaki, Kobayashi and Tsugane 12 ). A detailed description of the FFQ, its reliability and validity, and the method used for calculating nutrient intakes has been published previously( Reference Shimizu, Ohwaki and Kurisu 13 , Reference Nagata, Takatsuka and Shimuzu 14 ). The Spearman correlation coefficients between the questionnaire and twelve daily diet records kept over a 1-year period for the intakes of total energy, carbohydrates and dietary fibre were 0·44, 0·34 and 0·63, respectively, in men and 0·53, 0·45 and 0·60, respectively, in women.

Details regarding the methods used for assessing the GI of individual foods and mixed meals have been reported elsewhere( Reference Oba, Nagata and Nakamura 10 ). Briefly, GI values were assigned based on the International Table of GI( Reference Atkinson, Foster-Powell and Brand-Miller 15 ) and published data from studies carried out in Japan( Reference Murakami, Sasaki and Takahashi 16 ). Values for foods for which only the white rice-based GI was available were transformed into glucose-based GI values. Foods containing ≤ 3·5 g of carbohydrates per serving were assigned a value of 0. Values obtained for the amount of carbohydrates available after subtracting the amount of dietary fibre from that of total carbohydrates were used to calculate the GI and GL. Dietary GL was computed by adding the products of the available carbohydrates of each food consumed multiplied by the GI of individual foods and dividing the products by 100. Dietary GI was calculated by dividing the dietary GL by the amount of total carbohydrate consumed and multiplying by 100. GL derived from white rice and other foods were also assessed separately. White rice with germs, but not brown rice, was considered as white rice.

Physical activity was assessed from the average hours per week spent performing various kinds of activities during the previous year. The time spent per week performing an activity of specific intensity was multiplied by its corresponding energy expenditure requirements, expressed as a metabolic equivalent, and summed to obtain a score (metabolic equivalents-h/week). Details including the validity of this method have been described elsewhere( Reference Suzuki, Kawakami and Shimizu 17 ).

Follow-up and endpoints

Information regarding subjects who died or moved out of Takayama City between the baseline and 1 October 2008 was obtained from residential registers or family registers. Causes of death were identified from death certificates provided by the Legal Affairs Bureau. They were coded according to the International Classification of Diseases (ICD), 10th revision. The endpoints were all-cause mortality and disease-specific mortality including mortality from cancer (ICD-10: C00–D48), CVD (ICD-10: I00–I99), and all other causes (non-cancer, non-CVD). As dietary GI and GL were significantly associated with non-cancer, non-cardiovascular mortality in men, major causes of deaths in this category, such as infections (ICD-10: A00–A99 and B00–B99), endocrine, nutritional, and metabolic diseases (ICD-10: E00–E90), respiratory diseases (ICD-10: J00–J99), digestive diseases (ICD-10: K00–K93), genitourinary diseases (ICD-10: N00–N99), and external causes of injury and poisoning (ICD-10: S00–T98), were further assessed. During the study period, 941 (6·5 %) men and 971 (5·7 %) women moved out of Takayama City. The date of moving out of the city was not known for 104 (0·7 %) men and 147 (0·9 %) women. They were censored at the latest date when they were known to reside in the city. The present study was approved by the Ethics Committee of the Gifu University Graduate School of Medicine.

Statistical analyses

For each subject, person-years of follow-up were calculated from the date of responding to the baseline questionnaire to the date of death, the date of moving out of Takayama City or 1 October 2008, whichever occurred first. The mean duration of follow-up was 14·4 years (409 198 person-years). The subjects were divided into four groups according to the quartile of dietary GI, dietary GL, GL derived from white rice and GL derived from other foods. Using the Cox proportional-hazards model, the HR and their 95 % CI for all-cause mortality and cause-specific mortality for each category were calculated in comparison with the lowest intake category. The median value obtained for each category was used to assess linear trend. Dietary GI, GL and the intakes of all nutrients and foods were adjusted for total energy using the residual method( Reference Willett and Willett 18 ). First, age and total energy were included in the models as covariates. Additional adjustments were made for non-dietary factors including marital status (married, not married or missing), education ( ≤ 11, 12–14, ≥ 15 years, or missing), height (in quartile or missing), BMI (in quartile or missing), physical activity (metabolic equivalents-h/week), alcohol consumption (in quartile for men and non-drinkers and drinkers below or above the median alcohol level for women), smoking status (never, former, current with ≤ 30 years of smoking, current with >30 years of smoking, or missing for men and never, former, current, or missing for women), histories of diabetes and hypertension (yes or no) and menopausal status (premenopausal, postmenopausal or missing; only women) and dietary factors including saturated fat, polyunsaturated fat, salt, vegetables and fruits. All the statistical analyses were performed using SAS programs. Significance was defined as two-sided P< 0·05.

Results

The baseline characteristics of the study population by sex and quartile of dietary GI and GL are summarised in Table 1. Men with greater dietary GI were found to more likely be physically active and less educated and to less likely have reported histories of hypertension and diabetes. They were also found to have a higher intake of carbohydrates and lower intakes of alcohol, fats, salt, fruits and vegetables. Women with greater dietary GI were found to more likely be married, premenopausal, and less educated and to less likely have reported a history of diabetes. They were also found to have a higher intake of carbohydrates and lower intakes of alcohol, total energy, fats, salt, fruits and vegetables. These characteristics were also observed in relation to dietary GL, except that it was found that men with higher dietary GL were more likely to be never smokers and have a higher intake of fruits and that women with higher dietary GL were more likely to be never smokers and their menopausal status was irrelevant. The questionnaire used in the present study was designed to measure an individual's relative intakes of nutrients or foods rather than absolute values. Although the mean values for dietary intakes are given in the table, some of them may be overestimated by the questionnaire.

Table 1 Baseline characteristics of the study population by sex and quartile (Q) of dietary glycaemic index (GI) and glycaemic load (GL)*

MET, metabolic equivalent.

* Values are means for continuous variables and percentages for categorical variables.

During the follow-up period excluding the first 3 years, there were 2499 male deaths and 2117 female deaths. When compared with the lowest quartiles, the highest quartiles of dietary GI, dietary GL, and GL derived from white rice were found to be significantly associated with a decrease in all-cause mortality in men after controlling for covariates (Table 2). The trends towards a greater reduction in the risk of mortality were also statistically significant. The HR for all-cause mortality in men in the highest quartile of GL derived from white rice was significantly lower than that in men in the highest quartile of GL derived from other foods (P= 0·01). Dietary GL was significantly inversely associated with the risk of cancer mortality. The results obtained for GL derived from white rice mirrored those obtained for overall GL. Dietary GI, dietary GL, and GL derived from white rice were significantly inversely associated with the risk of non-cancer, non-cardiovascular mortality. Among non-cancer, non-cardiovascular causes of death, a significant or suggestive inverse association with dietary GI or GL was observed for endocrine, nutritional, and metabolic diseases, respiratory diseases, and digestive diseases. The HR for the highest v. lowest quartile of GI and GL were as follows: endocrine, nutritional, and metabolic diseases, GI, 0·29 (95 % CI 0·21, 1·21; P trend= 0·03); GL, 0·14 (95 % CI 0·04, 0·54; P trend= 0·003); respiratory diseases, GI, 0·74 (95 % CI 0·48, 1·13; P trend= 0·09); GL, 0·63 (95 % CI 0·38, 1·05; P trend= 0·04); digestive diseases, GI, 0·40 (95 % CI 0·16, 1·04; P trend= 0·10); GL, 0·44 (95 % CI 0·16, 1·25; P trend= 0·10).

Table 2 All-cause and cause-specific mortality in men by quartiles (Q) of dietary glycaemic index (GI) and glycaemic load (GL) (Hazard ratios (HR) and 95 % confidence intervals; medians and number of deaths)

* Adjusted for age, energy, height, BMI, physical activity, smoking status, education, marital status, histories of diabetes and hypertension, and intakes of alcohol, saturated fat, polyunsaturated fat, salt, vegetables and fruits.

In women, dietary GI was significantly positively associated with the risk of cardiovascular mortality after controlling for covariates (Table 3). The GL derived from white rice was significantly inversely associated with the risk of cancer mortality.

Table 3 All-cause and cause-specific mortality in women by quartiles (Q) of dietary glycaemic index (GI) and glycaemic load (GL) (Hazard ratios (HR) and 95 % confidence intervals)

* Adjusted for age, energy, height, BMI, physical activity, smoking status, education, marital status, menopausal status, histories of diabetes and hypertension, and intakes of alcohol, saturated fat, polyunsaturated fat, salt, vegetables and fruits.

Additional adjustments made for the intakes of dietary fibre, vitamins, and minerals, vitamin use, and history of cancer screenings did not alter the results. For example, the HR for all-cause mortality in men in the highest v. lowest quartile of dietary GL was 0·71 (95 % CI 0·59, 0·86; P trend= 0·0001) and that for cardiovascular mortality in women in the highest v. lowest quartile of dietary GI was 1·61 (95 % CI 1·17, 2·21; P trend= 0·004) after additionally controlling for the intakes of dietary fibre and Ca, vitamin use, and attendance at stomach cancer screenings. Adjustments made for the intakes of traditional Japanese foods, such as fish, tofu, miso, soya sauce and seaweed, did not alter the results substantially. Adjustments made for the intakes of red meat, poultry and fish did not alter the results. Dairy food intake was neither a confounder nor a modifier of the associations. The inverse association observed between vegetable intake and dietary GI as well as GL in the present study may lead to a concern that vegetable intake may be associated with an increased risk of mortality in men. However, vegetable intake was independently significantly associated with a decreased risk of mortality; the HR for all-cause mortality for every 100 g increase in vegetable intake was 0·96 (95 % CI 0·95, 0·99) in the multivariate model for dietary GI. On the other hand, salt intake was significantly associated with an increased risk of all-cause mortality (HR for every 1 g increase in salt intake was 1·04, 95 % CI 1·02, 1·06).

Exclusion of subjects who reported a history of diabetes did not alter the results; for example, the multivariate HR for all-cause mortality in men in the highest v. lowest quartile of dietary GL were 0·74 (95 % CI 0·60, 0·90; P trend= 0·0007) and the HR for cardiovascular mortality in women in the highest v. lowest quartile of dietary GI was 1·47 (95 % CI 1·06, 2·02; P trend= 0·03) after controlling for covariates. Exclusion of subjects who died during the first 6 years also did not alter the results substantially; for example, the HR for all-cause mortality in men in the highest v. lowest quartile of dietary GL was 0·72 (95 % CI 0·58, 0·89; P trend= 0·001) and that for cardiovascular mortality in women in the highest v. lowest quartile of dietary GI was 1·45 (95 % CI 1·03, 2·04; P trend= 0·03). Inclusion of subjects who died during the first 3 years also did not alter the results substantially.

Discussion

In the present prospective study, dietary GI and GL were found to be associated with a decreased risk of all-cause and non-cancer, non-cardiovascular mortality in men. Dietary GL was found to be also associated with a decreased risk of cancer mortality in men. Dietary GI was found to be associated with an increased risk of cardiovascular mortality in women. Several reviews of previous studies on dietary GI or GL and the risk of CVD have been published, and most of them have concluded that a high GI or GL increases the risk of CVD in women but not in men. Our findings concerning cardiovascular mortality in both men and women do not contradict the results of previous studies( Reference Ma, Liu and Song 4 , Reference Dong, Zhang and Wang 19 Reference Mirrahmi, Chiavaroli and Srichaikul 21 ). However, the significant inverse associations observed between dietary GI and GL and non-cancer, non-cardiovascular mortality and between dietary GL and cancer mortality in men were unexpected. These inverse associations contributed to the reduction of all-cause mortality in relation to dietary GI and GL in men.

Numerous epidemiological studies have assessed the associations of dietary GI and GL with the risk of cancers, but the results were less consistent when compared with those obtained for CVD. A recent meta-analysis of prospective studies has revealed a weak association of diabetes-related cancers (bladder, breast, colorectal, endometrial, liver, pancreatic and prostate cancers) with dietary GI (relative risk = 1·07) or GL (relative risk = 1·02)( Reference Choi, Giovannucci and Lee 22 ). The results were interpreted to indicate that GI or GL may not ideally predict insulin secretion, which is more relevant than hyperglycaemia to the development of cancer( Reference Choi, Giovannucci and Lee 22 ).

No study has examined the association of dietary GI or GL with the risk of non-cancer, non-cardiovascular mortality in men as a whole. The association between dietary GI and mortality from inflammatory diseases was examined in one study carried out in Australia( Reference Buyken, Flood and Empson 23 ). The association was almost null in men, although a significant positive association was observed in women. In the present study, among non-cancer, non-cardiovascular causes, mortality from digestive diseases, respiratory diseases, and endocrine, nutritional, and metabolic diseases was found to exhibit a suggestive inverse association with dietary GL. Considering these results, dietary GI or GL may be favoured as a nutritional support for improving the prognosis of various diseases rather than as a risk determinant of diseases in men. It is also possible that certain dietary components in white rice, rather than GL, may have beneficial effects on all-cause and cause-specific mortality in men because the GL derived from white rice contributed to the inverse associations of overall GL with mortality. The GL derived from white rice was also associated with a decreased risk of cancer mortality in women. Howarth et al. ( Reference Howarth, Murphy and Wilkens 24 ) found that a higher GL was associated with a decreased risk of colorectal cancer in women in the Multiethnic Cohort Study. They suggested that this might be because, in this population, a major source of dietary GL is white rice. Given the results of the present and other studies, application of the GI to white rice in the Japanese diet can lead to misinformation and counterproductive dietary guidance.

The strengths of the present study include the prospective design, validation of dietary questionnaire, representation of the general population, information on potential confounders, a high rate of participation and the length of follow-up. The study also has several limitations. Although adjustments for numerous potential confounders were made, confounding due to unknown factors or residual confounding cannot be ruled out. The sample size was limited, which precluded analyses on causes leading to small numbers of deaths. The results of the study may have been affected by the misclassification of dietary GI or GL. It has been shown that GI values obtained for the same foods are roughly similar in an ethnically and physically wide variety of subjects( Reference Chiu, Liu and Willett 25 ). However, the GI of a food may vary when it is eaten with different foods. It has been reported that dairy foods reduce the GI of white rice when consumed together( Reference Sugiyama, Tang and Wakaki 26 ). Although dairy food intake was found to be neither a confounder nor a modifier of the associations of dietary GI and GL with the risk of mortality, the statistical handling followed in the present study would not be sufficient to disentangle the relative roles of these dietary components. Some degree of misclassification of dietary intake is also expected, just as in other nutritional epidemiological studies. However, it is unlikely that measurement errors in the estimation of dietary GI and GL and the intakes of nutrients at the baseline were dependent on the subsequent deaths. Usual dietary intake was estimated through a single dietary intake assessment. According to the National Health and Nutrition Survey in Japan( 27 ), rice intake was 33·9 % of energy in 1992 and 30·7 % of energy in 2008. The corresponding values for fat and protein intakes were 25·5 and 15·6 % of energy, respectively, in 1992 and 25·1 and 14·6 % of energy, respectively, in 2008. Although these data indicate that dietary intake during the follow-up period did not change greatly at the population level, dietary intake change at the individual level cannot be ruled out. Underlying diseases or preclinical signs at the baseline may have affected dietary intake assessment. However, the exclusion of those who died during the first 6 years of follow-up did not alter the results substantially. The question of generalisability is also relevant. Our findings were recorded in a population that is leaner, similar to other Japanese populations, when compared with Western populations and that consumes rice as the main contributor of dietary GI and GL. Foods that contribute to dietary GI and GL can differ across populations and may have different health implications.

In conclusion, the results of the present study do not support the associations of dietary GI and GL with an increased risk of all-cause or cause-specific mortality in men. Rather, potential favourable effects were observed in men. On the other hand, a high GI was found to be associated with an increased risk of cardiovascular mortality in women. Further studies are needed to confirm or refute these findings. As these associations appear to be dependent on the food sources of dietary GI and GL and sex, studies among various populations are encouraged.

Acknowledgements

The authors thank Dr Shougen Matsushita and Mr Takehiko Minaguchi for their help with data collection.

The present study was supported in part by grants from the Ministry of Education, Culture, Sports, Science, and Technology and the National Cancer Center Research and Development Fund, Japan. The Ministry of Education, Culture, Sports, Science, and Technology and the National Cancer Center had no role in the design and analysis of the study or in the writing of this article.

The authors’ contributions were as follows: C. N. organised the study and wrote the manuscript; K. W., M. T. and T. K. conducted the data analysis; K. N. helped supervise the field activities and interpret the data. All the authors read and approved the final manuscript.

None of the authors has any conflicts of interest to declare.

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Figure 0

Table 1 Baseline characteristics of the study population by sex and quartile (Q) of dietary glycaemic index (GI) and glycaemic load (GL)*

Figure 1

Table 2 All-cause and cause-specific mortality in men by quartiles (Q) of dietary glycaemic index (GI) and glycaemic load (GL) (Hazard ratios (HR) and 95 % confidence intervals; medians and number of deaths)

Figure 2

Table 3 All-cause and cause-specific mortality in women by quartiles (Q) of dietary glycaemic index (GI) and glycaemic load (GL) (Hazard ratios (HR) and 95 % confidence intervals)