Abstract
Objectives:
Raised glycosylated haemoglobin (HbA1c) concentration is a recognised risk factor for diabetes the incidence of which is rising world-wide. The intake of certain foods has been related to HbA1c concentration . The aim of this study was to investigate whether nutrient intake, sourced by these foods, was predictive of raised glycosylated haemoglobin (HbA1c) concentration in a British cohort.
Subjects/methods:
The subjects were 495 men and 570 women who were members of the Medical Research Council National Survey of Health and Development, 1946 birth cohort. Diet was assessed from 5-day records in 1982, 1989 and 1999. HbA1c was measured in blood samples collected in 1999. Individuals in whom concentration of HbA1c was ≥ 6.3% were identified as being “at risk” and their nutrient intake was compared to those whose concentration of HbA1c was within the normal range (≤6.2%).
Results:
Lower intakes of protein, carbohydrate, non-starch polysaccharide, iron, folate, vitamin B12 and a higher percentage energy from fat in 1989 were significantly predictive of high HbA1c status in 1999. In 1999 there were no nutrient intakes that were predictive of HbA1c status. Global tests of whether the intakes of energy, carbohydrate, sodium, iron, riboflavin and vitamin B12 at all three time-points were related to HbA1c status in 1999, were significant.
Conclusion:
An increased intake of energy, carbohydrate, sodium, iron, riboflavin and vitamin B12 over 10 years was predictive of raised HbA1c status. Increased energy intake may have resulted in the increase in body weight that is a risk factor for diabetes.
Keywords: Diet, Nutrients, Glycosylated haemoglobin, NSHD
Introduction
Elevated glycosylated haemoglobin (HbA1c) in the blood is an indicator of chronically raised blood glucose concentrations that is used as a method of identifying people at risk of developing diabetes or as a marker of poor control in diagnosed diabetics. The incidence of diabetes in the UK is rising; between 1996 and 2007 the number of diagnosed diabetics has risen from 1.4 million to 2.3 million (Diabetes UK 2007). Incidence is projected to reach 3 million by 2010; around 85% being type 2 diabetes (Medical Research Council 2002). Type 2 diabetes is usually associated with obesity and is considered to be a result of inappropriate diet and lifestyle over a long period (Mann 2002; Montonen et al. 2005; Schulze et al. 2005). Similarly, elevated HbA1c in older people may be attributed to unhealthy dietary and other behaviours (Boeing et al. 2000). Raised HbA1c is also a risk factor for cardiovascular disease particularly when combined with high blood pressure and raised cholesterol (Adler 2008)
The UK Prospective Diabetes Study (UKPDS) group reported the normal range of HbA1c to be 4.5-6.2 % and values above may indicate individuals at risk of diabetes (UKPDS 1994; Stratton et al. 2000). Khaw et al. reported that the concentration of HbA1c in the men of the EPIC (Norfolk) cohort not only explained most of the excess mortality risk of diabetes but was also continuously related to all-cause mortality through the whole population distribution even below the threshold, HbA1c≥ 7%, for undiagnosed diabetes (Khaw et al. 2001).
The relationship between HbA1c and components of the diet, such as fish, alcohol, fruit and vegetables and fats diet has been examined in several studies of the EPIC (Norfolk) cohort. (Harding et al. 2001; Sargeant et al. 2001; Harding et al. 2002; Harding et al. 2004). These results showed that total fat intake was positively associated with HbA1c concentration (Harding et al. 2001) but there was an inverse relationship with fruit and vegetable consumption (Sargeant et al. 2001). Other studies have also reported that consumption of green vegetables and fruits (Sargeant et al. 2000; Montonen et al. 2005; Bazzano et al. 2008; Harding et al. 2008) has been found to predict a reduced rate of type 2 diabetes. In a sample of British adults aged over 64 years Bates et al. reported that subjects with HbA1c above 6.3% had lower intakes of fruit and vegetables and lower intakes of vitamin C than those with HbA1c concentrations within the normal range (Bates et al. 2004). Meta-analyses that examined the relationship between HbA1c status and dietary glycaemic properties have shown that diets with a lower glycaemic index (GI) reduced HbA1c concentration as did a greater intake of unavailable carbohydrate (Livesey et al. 2008).
Most of these studies were cross-sectional so diet prior to the assessment of HbA1c status could not be assessed. The MRC National Survey of Health and Development, (NSHD) (1946 Birth Cohort) has provided a unique opportunity to investigate whether the diet over a period of nearly 20 years can be related to HbA1c concentration measured at the last assessment of the subjects in this time period. Analysis of the dietary data collected at three time-points over 17 years may provide evidence of association between HbA1c status and both current and previous diet.
Subjects and methods
The MRC National Survey of Health and Development (NSHD), the 1946 British Birth Cohort, is a social class stratified random sample of 5,362 singleton legitimate births in England, Scotland or Wales during the first week of March 1946. The members of the cohort were interviewed and dietary data were collected at age 36, 43 and 53 years (in 1982, 1989 and 1999 respectively). Of the 3035 cohort members who were contacted in 1999, there were 1065 subjects who provided blood samples and for whom there were also diet records collected in 1982 and 1989. None of these subjects had been diagnosed as having diabetes (type 1 or type 2).
The subjects were interviewed at each time-point when height and weight were measured from which body mass index (BMI) was calculated (kg m−2). A non-fasting blood sample was collected and HbA1c was measured by ion exchange chromatographic separation using HPLC on a Tosoh A1c-2.2 Analyser.
Dietary Assessment
Details of the dietary assessment have been reported earlier (Prynne et al. 2005). Subjects were given a diary in which to record details of all food and drink consumed at home and away over a 5-day period. This method of dietary assessment has been validated by Bingham et al. (Bingham et al. 1995). Food and nutrient intakes for all three time points were calculated using the in-house suite of programs based on McCance and Widdowson's The Composition of Foods, 4th edition (Paul and Southgate 1978) for 1982 and supplements (Holland et al. 1988; Holland et al. 1989) for 1989 and 6th edition (Food Standards Agency 2002) for 1999. Vitamin K1 values were added from the database provided by Bolton-Smith and Shearer (Bolton-Smith et al. 2000) and unpublished data.
Analysis
For the analysis the subjects were grouped according to their HbA1c status measured in 1999. Those individuals in whom concentration of HbA1c was ≥ 6.3% were identified as being “at risk” (UKPDS 1994). These subjects were compared to those whose HbA1c was within the normal range (≤6.2%). The particular nutrients investigated were those found in foods of interest; fruits, vegetables, meat and dairy products, the latter two being principal sources of fat in the diet. Logarithmic transformations of all the vitamin intakes were performed prior to analysis to normalise their distributions. Geometric means and confidence intervals are presented for these variables. Logistic regression was used to investigate the relationship between nutrient intake and HbA1c status. For the nutrient explanatory variables, an odds ratio greater than one is interpreted as an increased chance of having a HbA1c above 6.3% corresponding to an increase in the nutrient, similarly an odds ratio less than one is interpreted as a lower chance of HbA1c being above 6.3% for an increase in the nutrient. The adjusted odds ratios (ORs) were calculated controlling for the possible confounders; BMI, socio-economic status and smoking; the latter two were treated as unordered categorical covariates and the former is a continuous variable.
Multiple logistic regression was used to examine the relationship between diet over time and HbA1c status. Nutrient intakes in 1982 and 1989 as well as 1999 were considered as independent predictors in the same model and two global tests were calculated: 1) whether nutrients were related to HbA1c status and 2) whether this relationship varied over time. Both tests were controlled for the confounders above. Stepwise logistic regression was used to identify the years that most predicted HbA1c status. The parsimonious model, that was used to elucidate when the association occurred, included only 1989 and 1999 and the nutrient intake at each time point was adjusted for the other.
All analyses were conducted using SPSS for MS Windows (version 10) and Stata 1 (version 9.1). The nominal significance level was taken as P≤ 0.05.
Results
Table 1 shows characteristics and concentrations of HbA1c of subjects who provided dietary data in 1982, 1989 and 1999. Of the 1065 subjects, 19 (3.8%) men and 27 (4.7%) women had concentrations of HbA1c ≥ 6.3%. Compared with those subjects whose HbA1c was within the normal range these individuals had significantly greater BMIs in 1982 (p=0.003), 1989 (p=0.001) and 1999 (p=0.001) and a higher percentage were smokers. All subjects gained weight between 1982 and 1999; there was no significant difference between the two groups in the size of this weight gain.
Table 1.
n= 1065 | HbA1c <6.3% | HbA1c ≥ 6.3% | P |
---|---|---|---|
Men, n 495 | 476 (96.2%) | 19 (3.8%) | |
Women, n 570 | 543 (95.3%) | 27 (4.7%) | |
1982 BMI (wt ht−2) | 23.1 (23.0,23.3) | 24.5 (23.4,25.5) | 0.003 |
1989 BMI (wt ht−2) | 24.3 (24.1,24.5) | 26.1 (24.8,7.4) | <0.001 |
1999 BMI (wt ht−2) | 26.5 (26.2,26.7) | 28.6 (27.0,30.3) | 0.001 |
Weight change (kg) 1982-99 | 8.6 | 10.4 | NS |
Mean HbA1c % | 5.52 | 6.60 | |
Range of HbA1c % | 4 – 6.2 | 6.3 – 12.8 | |
Smokers | 16% | 26% | 0.068* |
Manual social class | 28% | 31% | NS* |
Pearson Chi square
BMI = Body mass index
Table 2 shows the mean daily intake of selected nutrients measured in the same subjects in 1982 and 1989 categorised by HbA1c status measured in 1999; HbA1c < 6.3% and HbA1c ≥ 6.3%. Lower intakes of iron and folate and non-starch polysaccharides (NSP) in 1982 and 1989 were significantly predictive of high HbA1c status in 1999. In addition, in 1989, lower intakes of protein, carbohydrate, and vitamin B12 and a greater percent energy from fat were significantly predictive of high HbA1c status in 1999. Before adjustment for BMI, SES and smoking, lower intakes of vitamins C and K1 in 1982 and 1989 were predictive of high HbA1c status (results not shown) but after adjustment these intakes were no longer significant.
Table 2.
n= 1065 | HbA1c <6.3% | HbA1c ≥ 6.3% | Adjusted 1 OR (95%CI) |
P |
---|---|---|---|---|
1982 Energy, MJ | 8.8 (8.6,9.0) | 8.1 (7.5,8.8) | 0.92 (0.82,1.0) | NS |
1989 Energy, MJ | 9.2 (9.1,9.4) | 8.3 (7.6,9.0) | 0.88 (0.77,1.0) | 0.053 |
1982 Protein, g | 74.3 (73.1,75.5) | 70.1 (64.6,75.6) | 0.91 (0.77,1.1) | NS |
1989 Protein, g | 79.5 (78.1,80.7) | 71.7 (66.4,77.0) | 0.83 (0.70,0.98) | 0.031 |
1982 Fat, g | 91.9(90.1,93.7) | 86.6 (78.4,94.7) | 0.94 (0.85,1.04) | NS |
1982 Fat % energy | 39.3 (39,36.6) | 40.0 (38.6,41.5) | 1.04 (0.98,1.1) | NS |
1989 Fat, g | 95.8 (93.9,97.8) | 89.8 (81.2,98.5) | 0.94 (0.85,1.04) | NS |
1989 Fat % energy | 38.9 (38.5,39.2) | 40.7 (39.0,42.3) | 1.13 (1.06,1.2) | 0.023 |
1982 Carbohydrate, g | 234 (229,238) | 216 (196,234) | 0.81 (0.54,1.2) | NS |
1989 Carbohydrate, g | 246 (241,250) | 216 (195,237) | 0.62 (0.39,0.99) | 0.043 |
1982 Non-starch polysaccharide, g |
12.4 (12.1,12.7) | 10.4 (9.4,11.4) | 0.89 (0.82,0.98) | 0.012 |
1989 Non-starch polysaccharide, g |
13.5 (13.2,13.9) | 11.3 (9.9,12.6) | 0.90 (0.84,0.98) | 0.012 |
1982 Sodium, mg | 2690 (2636,2744) | 2520 (2298,2742) | 0.83 (0.57,1.2) | NS |
1989 Sodium, mg | 2965 (2905,3025) | 2661 (2419,2903) | 0.73 (0.51,1.1) | 0.09 |
1982 Calcium, mg | 877 (859,895) | 882 (769,995) | 1.05 (0.4,2.78) | NS |
1989 Calcium, mg | 950 (932,968) | 868 (780,956) | 0.37 (0.13,1.08) | NS |
1982 Iron, mg | 12.0 (11.7,12.3) | 10.3 (9.4,11.2) | 0.90 (0.81,0.99) | 0.030 |
1989 Iron, mg | 13.0 (12.7,13.3) | 11.2 (10.1,12.4) | 0.91 (0.83,0.99) | 0.033 |
1982 Beta carotene, μg 2 | 1569 (1503,1638) | 1257 (1001,1577) | 0.70 (0.45,1.09) | NS |
1989 Beta carotene, μg 2 | 2056 (1971,2145) | 1871 (1433,2444) | 0.87 (0.56,1.33) | NS |
1982 Riboflavin, mg 2 | 1.69 (1.65,1.73) | 1.50(1.33,1.73) | 0.70 (0.31,1.6) | NS |
1989 Riboflavin, mg 2 | 1.73 (1.69,1.76) | 1.49 (1.33,1.68) | 0.43 (0.17,1.07) | 0.07 |
1982 Folate, ug 2 | 205 (200,209) | 175 (158,193) | 0.39 (0.16,0.94) | 0.016 |
1989 Folate, ug 2 | 267 (262,272) | 226 (203,252) | 0.27 (0.10,0.69) | 0.006 |
1982 Vitamin B12, ug 2 | 4.9 (4.6,5.1) | 3.9 (3.3,4.7) | 0.95 (0.89,1.01) | NS |
1989 Vitamin B12, ug 2 | 5.2 (5.0,5.4) | 4.0 (3.5,4.7) | 0.85 (0.74,0.97) | 0.015 |
1982 Vitamin C, mg 2 | 61 (59,63) | 52 (45,60) | 0.61 (0.32,1.16) | NS |
1989 Vitamin C, mg 2 | 63 (61,65) | 52 (44,62) | 0.57 (0.32,1.02) | 0.057 |
1982 Vitamin K1, ug 2 | 68 (65,70) | 58 (50,66) | 0.69 (0.39,1.27) | NS |
1989 Vitamin K1, ug 2 | 74 (71,76) | 61 (51,73) | 0.60 (0.35,1.03) | 0.062 |
Adjusted for body mass index, smoking and socio-economic status in 1999
Indicates geometric mean, back transformed from natural log
Table 3 shows the mean daily intake of energy and selected nutrients in 1999 categorised as above. The calculated ORs (adjusted for BMI, SES and smoking) showed that none of the nutrient intakes were predictive of high HbA1c status. Before adjustment for BMI, SES and smoking, lower intakes of K1 were predictive of high HbA1c status (OR; 0.42 (0.19,0.9) p=0.027) but significance disappeared on adjustment.
Table 3.
n = 1065 | HbA1c <6.3% | HbA1c ≥6.3% | Adjusted 1 OR (95%CI) |
P |
---|---|---|---|---|
1999 Energy, MJ | 8.5(8.4,8.6) | 8.6 (8.0,9.2) | 1.05 (0.91,1.21) | NS |
1999 Protein, g | 78 (77,79) | 80 (75,86) | 1.01 (0.99,1.02) | NS |
1999 Fat, g | 78 (76,79) | 82 (76,89) | 1.01 (0.99,1.02) | NS |
1999 Fat %energy | 34.3 (33.9,34.7) | 36.1 (34.7,37.4) | 1.13 (1.06,1.2) | NS |
1999 Carbohydrate, g | 239 (235,243) | 241 (221,261) | 1.00 (0.99,1.00) | NS |
1999 Non-starch polysaccharide, g |
14.6 (14.4,14.9) | 13.3 (12.0,14.6) | 0.94 (0.87,1.01) | NS |
1999 Sodium, mg | 2728 (2679,2777) | 2941 (2691,3192) | 1.35 (0.95,1.92) | NS |
1999 Calcium, mg | 985 (966,1003) | 997 (912,1082) | 1.59 (0.6,4.2) | NS |
1999 Iron, mg | 11.7 (11.5,11.9) | 11.9 (10.9,12.9) | 1.05 (0.96,1.14) | NS |
1999 Beta carotene, μg 2 | 2348 (2238,2464) | 2053 (1661,2538) | 0.81 (0.55,1.2) | NS |
1999 Riboflavin, mg 2 | 1.87 (1.83,1.91) | 1.94 (1.75,2.160 | 1.98 (0.78,5.0) | NS |
1999 Folate, μg 2 | 286 (280,291) | 270 (249,292) | 0.70 (0.26,1.89) | NS |
1999 Vitamin B12, μg 2 | 5.6 (5.4,5.7) | 6.1 (5.1,7.4) | 1.67 (0.95,2.92) | NS |
1999 Vitamin C, mg 2 | 87 (84,90) | 78 (66,92) | 0.93 (0.55,1.58) | NS |
1999 Vitamin E, mg 2 | 10.0 (9.8,10.3) | 9.9 (8.8,11.1) | 0.96 (0.45,2.0) | NS |
1999 Vitamin K1, μg 2 | 83 (80,85) | 69 (60,79) | 0.52 (0.27,0.99) | NS |
Adjusted for body mass index, smoking and socio-economic status in 1999
Indicates geometric mean, back transformed from natural log
Table 4 shows the results of the global tests of association that indicated whether the 1982, 1989 and 1999 intakes of energy, carbohydrate, sodium, iron, riboflavin and vitamin B12 were related to HbA1c status in 1999. ORs are given for nutrient intakes in 1989 and 1999 that were significantly predictive of HbA1c status in 1999 when each year's nutrient intakes were adjusted for the other. For each nutrient the adjusted ORs were all <1 in 1989 but> 1 in 1999. This indicated that a higher intake of energy and these nutrients in 1999, controlling for the level in 1989, i.e. the change over time of the individual nutrients, was associated with high HbA1c status. For example, subjects who increased sodium intake in 1999 by 1 g/day relative to 1989 were 73% more likely to have a high HbA1c status in 1999. Subjects who increased carbohydrate intake in 1999 by 100 g/day relative to 1989 were 95% more likely to have a high HbA1c status in 1999.
Table 4.
Nutrient | 1989 Adjusted 2 OR (95%CI) |
1999 Adjusted 2 OR (95%CI) |
P for global test of association |
---|---|---|---|
Energy, MJ 3 | 0.80 (0.68,0.95) | 1.22 (1.02,1.46) | 0.049 |
Carbohydrate, 100g 3 | 0.44 (0.25,0.78) | 1.95 (1.1,3.47) | 0.023 |
Sodium, 1g 3 | 0.60 (0.41,0.90) | 1.73 (1.17,2.56) | 0.016 |
Iron, 1mg 3 | 0.87 (0.79,0.96) | 1.10 (1.00,1.21) | 0.013 |
Riboflavin, 1mg 3 | 0.43 (0.23,0.80) | 1.78 (1.14,2.78) | 0.019 |
Vitamin B12, 1μg 3 | 0.84 (0.73,0.96) | 1.06 (1.01,1.10) | 0.012 |
Odds ratios were obtained from the parsimonious model and p-values were from the model with all three years' nutrient intakes.
Adjusted for body mass index, smoking and socio-economic status in 1999
The units given are those used to calculate the odds ratios
Discussion
In this examination of dietary intakes in relation to HbA1c concentration in 1999, there were no nutrient intakes in 1999 that were univariately predictive of concentrations above the “at risk” cut-off point. However, increases in intakes of energy, carbohydrate, sodium, iron, riboflavin and vitamin B12 relative to 1989 were associated with raised HbA1c status. These results suggest that an increase in the intake of some foods containing these nutrients might be related to elevated HbA1c.
Although there were indications of trends over the 3 survey years in intakes of vitamin C, folate and vitamin K1 in relation to HbA1c concentrations, due to the small numbers of subjects classified as being “at risk” there were few significant relationships. A weakness of the study is that the number of subjects who completed diaries at all 3 time points and gave blood samples in 1999 was small. These may be the most motivated members of the cohort, with dietary characteristics that may have been different from those who did not complete diaries. The majority of these subjects were from non-manual occupational social classes (Wadsworth 2003) who tend to have a greater degree of literacy and are more health-aware. The fact that none of the subjects who had been diagnosed with diabetes completed diaries in 1999 would also indicate a bias in the sample.
Several studies have shown a relationship between dietary fat and hyperglycaemia although it is not clear whether this is due to its association with obesity and the ensuing insulin resistance. Data on 9772 non-diabetic adults from the Health Survey for England 1994 showed that higher HbA1c was associated with the frequent consumption of fat containing foods (Gulliford and Ukoumunne 2001). In the present study there was a significant relationship between percent energy from fat in 1989 and HbA1c status although there was no relationship with actual fat intake. In 1989 energy and carbohydrate intakes were lower in the “at risk” subjects but in 1999, although fat intakes had fallen and carbohydrate intakes had risen in all subjects, the percent energy from fat was still greater in those with elevated HbA1c.
Kirk et al. showed in a meta-regression analysis that HbA1c status improved in patients with type 2 diabetes given lower carbohydrate diets (Kirk et al. 2008) but Livesey et al. published evidence that the effect of carbohydrate intake would depend on the GI of the diet (Livesey et al. 2008). In the present study we have shown that an increase in carbohydrate intake over 10 years was predictive of elevated HbA1c and, at all three time points, intake of NSP, a factor contributing to GI, was lower in those with elevated HbA1c.
Several studies have examined the intake of fruits and vegetables in relation to HbA1c concentrations or the incidence of type 2 diabetes (Williams et al. 1999; Sargeant et al. 2000; Montonen et al. 2005; Bazzano et al. 2008). Participants in the EPIC- Norfolk study who reported never or seldom consuming both fruit and green leafy vegetables had higher mean HbA1c concentrations while mean plasma vitamin C concentrations were significantly higher in subjects with HbA1c concentrations < 7% (Sargeant et al. 2000). Extrapolating from these results would seem to indicate that the intake of the anti-oxidant vitamins, vitamin C and beta carotene as well as folate and vitamin K1, also found in vegetables, may have a role in regulating blood glucose and HbA1c concentrations. Yoshida et al. measured vitamin K1 intake of 2719 men and women of the Framingham Offspring Cohort and found a decreased hazard of HbA1c ≥ 6.5% with increasing intakes of vitamin K1, although this trend was not significant (Yoshida et al. 2008). Our study showed no significant association between HbA1c and vitamins C and K1 or carotene intake in 1999. When intakes of these vitamins at all 3 time points were examined, there was a trend for mean intakes to be lower in subjects with elevated HbA1c but the range in this latter group was very wide. This, together with the small sample size, made it difficult to achieve a significant difference compared to those subjects in the normal range of HbA1c.
All the subjects gained weight between 1982 and 1999 but those with raised HbA1c in 1999 had a significantly higher BMI at all time-points, despite having a lower energy intake in 1989. Thus, by 1999, the mean BMI of this group was within the over-weight range. In the majority of subjects, those with HbA1c within the normal range, energy intakes fell between 1989 and 1999 indicating, perhaps, that physical activity had declined with increasing age. But in those subjects with raised HbA1c, who were already heavier in 1989, energy intake increased between 1989 and 1999. Assuming that these subjects had not increased their physical activity, the increased energy intake would have contributed to the weight gain. A longitudinal study in the US over 10 years showed that for every kilogram of increase in weight the diabetes risk increased by 4.5% (Ford et al. 1997). In the present study the weight gain could be the primary cause of the raised HbA1c in these subjects.
It could be argued that it is the energy intake that is driving the associations between HbA1c and the increased intakes of carbohydrate, sodium, iron, riboflavin and vitamin B12. However, it is still relevant to examine the principal sources of some of these nutrients; namely milk, meat and meat products. In this study, the increase in milk consumption over 10 years, between 1989 and 1999, was found to be associated with elevated HbA1c (results not shown). While cows' milk has been cited as a contributory factor in the development of type1 diabetes (Virtanen and Knip 2003) its involvement with type 2 diabetes is less clear. Dairy consumption was inversely associated with the incidence of insulin resistance components in young adults aged 18 to 30 years in the US but the findings from the British Women's Heart and Health study found that, in these older subjects aged 60-70, avoiding milk was associated with a reduced risk of insulin resistance (Lawlor et al. 2005). The ATTICA study, with subjects aged between 18 and 89 years, also reported a strong positive association between whole milk consumption and blood glucose (Papakonstantinou et al. 2005). The present study found that lower intakes of nutrients found in milk at age 43, but higher intakes at age 53, were associated with raised HbA1c at age 53 and it was the change in intakes of those nutrients between 43 years and 53 years that was significant. Although liquid milk consumption in the general population has fallen (Department for Environment Food and Rural Affairs 2001), in this cohort it had risen between 1989 and 1999 (Prynne et al. 2005).
Consumption of meat, particularly red meat and processed meat, has been implicated as a risk factor for type 2 diabetes (van Dam et al. 2002; Fung et al. 2004; Papakonstantinou et al. 2005; Schulze et al. 2005). The consumption of red and processed meat overall in the NSHD cohort has declined from 1989 to 1999 (Prynne et al. 2007). However, McNaughton et al. showed that in the NSHD cohort a dietary pattern that was characterised by a high consumption of meat, potatoes and sweet foods was significantly positively associated with elevated HbA1c(McNaughton et al. 2007). This agrees with our finding that those with elevated HbA1c had increased their carbohydrate intake between 1989 and 1999. The possible causal factor common to both meat and milk is their content of saturated fat which has been positively associated with HbA1c(Harding et al. 2001) but in the present study we cannot show whether there is a direct link or whether it is the consumption of these foods contributing to the increase in body weight that is of greater importance.
None of the 1065 members of 1946 birth cohort who were included in this study had been diagnosed as diabetic although 4.3% had elevated concentrations of HbA1c in 1999. Within the latter group there was a non-significant trend showing a lower intake of nutrients provided by fruits and vegetables and significant associations with increases in the intake of energy, carbohydrate and certain micronutrients provided by milk and meat. In general, the diets of members of the 1946 cohort who have been examined at all three time points have shown a general improvement which concurs with current dietary guidelines (Prynne et al. 2005) and is characteristic of older people who are more health-aware. However there are still some subjects whose elevated HbA1c and higher energy intake combined with a lower intake of certain micronutrients and a higher intake of others may place them at risk of developing type 2 diabetes some time in the future.
Acknowledgments
Sponsorship: This work was supported by the UK Medical Research Council
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