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Dietary Fat and Incidence of Type 2 Diabetes in Older Iowa Women

¹ Department of Epidemiology, Harvard School of Public Health, Boston, Massachusetts
² Teachers’ College, Columbia University, New York, New York
³ Division of Epidemiology, University of Minnesota School of Public Health, Minneapolis, Minnesota

	ABSTRACT

TOP ABSTRACT INTRODUCTION RESEARCH DESIGN AND METHODS RESULTS CONCLUSIONS References

 
OBJECTIVE—To examine the associations between reported intakes of dietary fat and incident type 2 diabetes.

RESEARCH DESIGN AND METHODS—We studied the relation between dietary fatty acids and diabetes in a prospective cohort study of 35,988 older women who initially did not have diabetes. Diet was assessed with a food frequency questionnaire at baseline, and 1,890 incident cases of diabetes occurred during 11 years of follow-up.

RESULTS—After adjusting for age, smoking, alcohol consumption, BMI, waist-to-hip ratio, physical activity, demographic factors, and dietary magnesium and cereal fiber, diabetes incidence was negatively associated with dietary polyunsaturated fatty acids, vegetable fat, and trans fatty acids and positively associated with -3 fatty acids, cholesterol, and the Keys score. After simultaneous adjustment for other dietary fat, only vegetable fat remained clearly related to diabetes risk. Relative risks across quintiles of vegetable fat intake were 1.00, 0.90, 0.87, 0.84, and 0.82 (P = 0.02). Diabetes risk was also inversely related to substituting polyunsaturated fatty acids for saturated fatty acids and positively correlated to the Keys dietary score.

CONCLUSIONS—These data support an inverse relation between incident type 2 diabetes and vegetable fat and substituting polyunsaturated fatty acids for saturated fatty acids and cholesterol.

Abbreviations: IGT, impaired glucose tolerance • RR, rate ratio • WHR, waist-to-hip ratio

	INTRODUCTION

TOP ABSTRACT INTRODUCTION RESEARCH DESIGN AND METHODS RESULTS CONCLUSIONS References

 
Although a low-fat diet is recommended for diabetic and nondiabetic patients (1), findings from epidemiological studies on the association of total dietary fat with type 2 diabetes or insulin sensitivity have been inconsistent (2,3,4,5,6,7,8). Metabolic and epidemiological studies suggest that dietary fat subtypes may be relevant to diabetes pathophysiology. Specific dietary fatty acids may influence the development of diabetes by modifying the phospholipid composition of cell membranes, which in turn may alter the function of the insulin receptor (9,10).

While controlling for dietary and nondietary factors, we examined the relation between baseline intake of total dietary fat and dietary fat subtypes and the development of type 2 diabetes over 11 years of follow-up in the Iowa Women’s Health Study.

	RESEARCH DESIGN AND METHODS

TOP ABSTRACT INTRODUCTION RESEARCH DESIGN AND METHODS RESULTS CONCLUSIONS References

 
The Iowa Women’s Health Study is a prospective cohort study of older Iowa women. In January 1986, a random sample of 99,826 women aged 55–69 years who had a valid Iowa driver’s license were mailed a 16-page questionnaire and asked to participate. The study sample consisted of the 41,836 women who returned the baseline questionnaire. Respondents had a lower mean BMI (0.4 kg/m² less), were 3 months older, and were more likely to live in counties that were rural and less affluent than nonrespondents (11).

Women were excluded from analysis if they reported implausibly high (>5,000 kcal) or low (<600 kcal) energy intakes, left 30 items blank on the food-frequency questionnaire, or had diabetes at baseline. Women were considered to have diabetes at baseline if they responded "yes" or "don’t know" to one of the following questions: 1) have you ever been told by a doctor that you have sugar diabetes? and 2) have you ever taken insulin or pills for sugar diabetes (or to lower blood glucose)? After exclusions, 35,988 women remained eligible for the study.

Data collection
The baseline questionnaire included questions on known or suspected risk factors for diabetes, such as age, BMI, waist-to-hip ratio (WHR), physical activity, alcohol consumption, and smoking history. BMI was calculated from weight and height measurements provided by the participants. WHR was calculated as the average of two measurements taken by the participant’s spouse or friend using a paper tape measure that was included with the questionnaire (12). The women reported their frequency of moderate (e.g., golf and long walks) and vigorous (e.g., swimming and aerobics) physical activity. Pack-years of smoking were calculated from information on the intensity and duration of cigarette smoking. Alcohol consumption was assessed with a food frequency questionnaire that queried the participants’ typical intakes of wine, beer, and spirits. In addition, the participants provided information on their marital status, educational attainment, residence, and use of hormone replacement therapy.

The principal dietary exposure of interest was intake of fat, including cholesterol and the Keys score. In addition to total dietary fat, we analyzed saturated, polyunsaturated, monounsaturated, trans fatty acids, long-chain -3 fatty acids, and animal and vegetable fat. The Keys score, which correlates changes in fatty acid intake with changes in serum cholesterol, was calculated as 1.26 (2S - P) + (Z)^1/2, where S = percent of energy from saturated fat, P = percent of energy from polyunsaturated fat, and Z = dietary cholesterol in mg/1,000 kcal (13). A higher Keys score corresponds to higher relative intake of saturated fat and cholesterol and a lower relative intake of polyunsaturated fat. We also examined several foods and food groups high in dietary fats, including total meat, red meat, eggs, nuts, and olive oil salad dressing.

A 127-item food-frequency questionnaire similar to that used in the 1984 Nurses’ Health Study was used to assess typical food intake over the previous year (14). The validity of the food-frequency questionnaire was evaluated by comparing nutrient values determined from the questionnaire with values estimated from the average of five 24-h dietary recall surveys in 44 study participants (15). Energy-adjusted Pearson’s correlation coefficients were 0.62, 0.59, 0.62, 0.43, and 0.21 for total fat, saturated fat, monounsaturated fat, polyunsaturated fat, and cholesterol, respectively. Correlation coefficients were not calculated for other fat variables.

Diabetes incidence was determined by an affirmative response to the following question, which was on all of the follow-up mailed surveys: "Since baseline or respective follow-up, were you diagnosed for the first time by a doctor as having sugar diabetes?" During 11 years of follow-up, 1,890 women reported incident diabetes in the four follow-up surveys administered in 1987 (n = 344), 1989 (n = 331), 1992 (n = 466), and 1997 (n = 749). Response rates for the four follow-up surveys were 91, 89, 86, and 79%, respectively.

A validation study of self-reported diabetes was conducted on 85 cohort participants in 1988 after the first follow-up survey. Subjects tended to over-report having diabetes; of 44 women who reported having diabetes at baseline, 28 (64%) were confirmed as having diabetes by their physician. All 41 women who reported not having diabetes at baseline were confirmed as not having diabetes (16).

Statistical analysis
For women who did not report a diagnosis of diabetes, person-time-at-risk was calculated from baseline to the date of the last completed follow-up survey. For women who reported a diagnosis of diabetes, person-time was calculated as the sum of the known disease-free period and half of the period during which the diagnosis was made. Mortality status was determined annually through linkage with the State Health Registry of Iowa or, in the case of nonrespondents and emigrants from Iowa, via the National Death Index.

Nutrient intakes were adjusted for total energy through the residual method (17) and divided into quintiles. Trend analyses weighted each category of dietary intake by the median intake for that category. Cox proportional hazards regression models provided estimates of rate ratios (RRs). The SAS package was used (18); all P values were two-sided.

To examine the independent effects of specific fat subtypes, we simultaneously adjusted for all fat subtypes. Because we adjusted for dietary protein, the regression coefficients are an estimate of the effect of substituting a specific fat subtype for carbohydrates in the diet. We further examined substituting one fat subtype for another by including total fat and all fat subtypes except the subtype for which we substituted (19).

	RESULTS

TOP ABSTRACT INTRODUCTION RESEARCH DESIGN AND METHODS RESULTS CONCLUSIONS References

 
The distributions of several known risk factors for diabetes and correlation coefficients among dietary fat variables are presented in Table 1. Women in the highest category of saturated, monounsaturated, trans fatty acids, and animal fat had a higher BMI and WHR, but they consumed less alcohol and engaged in less physical activity. For cholesterol, these relations were similar but not as pronounced. The risk-factor differences among categories of polyunsaturated and -3 fatty acids and vegetable fat were not extreme. Overall, 99% of the population was non-Hispanic white and 95% were of Protestant or Catholic religious faith; these distributions did not vary according to fat intake. Positive correlations were evident between total and saturated fat, total and monounsaturated fat, animal and saturated fat, and vegetable and polyunsaturated fat.

After simultaneous adjustment for other dietary fat subtypes, vegetable fat remained clearly associated with type 2 diabetes (Table 3). Relative risks across quintiles of vegetable fat intake were 1.00, 0.90, 0.87, 0.84, and 0.82 (P = 0.02), and they did not change appreciably after further adjustment for vitamin E. When we substituted polyunsaturated fatty acids for saturated fatty acids and vegetable fat for animal fat, we found that they were inversely related to diabetes risk. RRs across polyunsaturated fat intake were 1.0, 0.92, 0.89, 0.83, and 0.84 (P = 0.02). Comparing the highest to the lowest category of vegetable intake, the RR was 0.78 (95% CI 0.67–0.91).

There was no evidence in these data for modification of the relation between vegetable fat and diabetes by BMI. The relative risks for increasing vegetable fat intake roughly indicated a 20% reduction in diabetes when comparing the highest and lowest tertiles of vegetable fat in both the lowest and highest BMI tertiles. Similarly, we did not find support for effect modification by physical activity, alcohol consumption, or vitamin E intake.

	CONCLUSIONS

TOP ABSTRACT INTRODUCTION RESEARCH DESIGN AND METHODS RESULTS CONCLUSIONS References

 
Data from this prospective study of older women indicate that the composition of dietary fat may play a role in the development of type 2 diabetes. After adjusting for potential confounding variables and animal fat, we found an inverse relation between vegetable fat and incident type 2 diabetes. Polyunsaturated fatty acid was inversely related to diabetes risk when substituted for saturated fatty acid, and the Keys dietary score was positively correlated to diabetes.

There was no relation between dietary fat and diabetes in several prospective studies, which was consistent with our findings (5,6,7,8). Among 1,462 Swedish women, the mean intake of total dietary fat (based on a diet history) did not differ for women who did and did not go on to develop diabetes (7). The percent of energy derived from fat did not differ among Pima Indian women who developed diabetes compared with those who remained disease free (6).

However, other prospective studies have shown a positive correlation between diabetes and total dietary fat. Among subjects with impaired glucose tolerance (IGT), total dietary fat (assessed by 24-h recall) predicted conversion to diabetes within 1–3 years (21). In two cohorts of the Seven Countries Study, the percent of energy from fat predicted diabetes and was positively correlated to postload glucose levels after 20 years of follow-up (22).

Results from cross-sectional studies have been similarly mixed. A positive correlation between insulin sensitivity, derived from postload insulin and glucose measurements, and total dietary fat, which was reported by Lovejoy and DiGirolamo (23), was apparent only before adjusting for BMI. Two other studies also found no association with fasting insulin after accounting for BMI (24,25), whereas another study (26) found that total fat was unrelated to fasting insulin in univariate and multivariate analyses. In contrast, several studies (27,28,29,30) found a positive correlation between total dietary fat and fasting or postprandial insulin (independent of BMI) or a negative correlation with insulin sensitivity (34).

Our findings are consistent with some, but not all, prospective epidemiological studies that have examined subtypes of dietary fatty acids. In one study, vegetable fat and polyunsaturated fatty acids were inversely related to incident type 2 diabetes among lean women but not among obese women (31); saturated fatty acids, monounsaturated fatty acids, and animal fats were not related to diabetes. Although statistically nonsignificant, the RRs (0.85 among women and 0.83 among men comparing the highest with the lowest quintile of vegetable fat consumption) for incident diabetes reported in two studies by Salmeron and colleagues (32,33) were strikingly similar to ours for vegetable fat. Incident diabetes and conversion to diabetes were positively correlated to saturated fat and unrelated to polyunsaturated fat in two other follow-up studies (21,22). These findings are more in line with those from most cross-sectional studies, in which saturated fat was positively correlated to fasting insulin (24,26,27,28,29) or area under the insulin curve (34) and inversely related to insulin sensitivity (34). The findings for polyunsaturated fatty acids from these studies were more varied, showing inverse (34), positive (27), and no correlation (25,28,29,34) with insulin concentrations or sensitivity.

The inverse relationship between diabetes and vegetable fat remained after adjustment for other dietary fat, but that for polyunsaturated fatty acids did not. Likewise, Salmeron and colleagues (32,33) reported no association between polyunsaturated fatty acids and diabetes. When the highest to the lowest quintiles of polyunsaturated fatty acid intake were compared, the adjusted relative risks for diabetes were 0.97 in women and 1.01 in men. Vegetable fat includes fats found in nonanimal sources, including fruits and vegetables, grains, nuts, and oils. It is possible that vegetable fat represents the combination of several potentially healthful fat subtypes, including polyunsaturated fatty acids and monounsaturated fatty acids, from vegetable sources. Furthermore, although we considered several dietary factors that have been hypothesized to relate to diabetes risk, such as vitamin E, cereal fiber, and magnesium, vegetable fat will be highly correlated with any number of additional nutrients that we did not include, which may influence diabetes risk.

Although polyunsaturated fatty acids were not related to diabetes after adjusting for all other fatty acids, a true inverse relation is possible. It may be argued that dietary factors are so highly correlated that a high degree of attenuation is inevitable with simultaneous adjustment for dietary factors. When substituted for saturated fatty acids in the diet, polyunsaturated fatty acids were inversely related to diabetes, whereas the Keys score was positively correlated to diabetes. These findings are consistent with data from a 10-year follow-up study of middle-aged men who did and did not develop type 2 diabetes (35). Men who did develop type 2 diabetes had a higher proportion of saturated fatty acids and a lower proportion of linoleic acid in serum cholesterol esters, which in part reflects dietary fatty acid composition, than men who did not develop type 2 diabetes (35). A cross-sectional study of 45 subjects found no relationship between insulin sensitivity and the ratio of dietary polyunsaturated fatty acids to saturated fatty acids (23).

Feeding studies support a positive correlation between monounsaturated fatty acid intake and insulin sensitivity (36,37,38,39). In our study population, monounsaturated fatty acid consumption was more highly correlated with saturated and animal fat consumption (correlation coefficients 0.70 and 0.62, respectively) than with polyunsaturated and vegetable fat consumption (correlation coefficients 0.43 and 0.29, respectively). This may limit our ability to isolate the effects of individual fats; it underscores the importance of the specific dietary characteristics of studied populations. Such correlations will be somewhat population-specific; they may have contributed to the positive associations between monounsaturated fat and incident diabetes (22), to the progression to diabetes from IGT (21), and to fasting insulin (27,28) in some studies, but the inverse relation with insulin sensitivity (34) appears in other studies.

In our study, diabetes was positively correlated to dietary cholesterol and the Keys score. Similarly, Feskens et al. (22) found a positive correlation between dietary cholesterol and 20-year diabetes incidence in two Seven Countries Study cohorts. Conversely, two cross-sectional studies found no association between dietary cholesterol and fasting or postprandial insulin (26,34). It is unclear how dietary cholesterol may affect diabetes incidence, and our findings should be interpreted with caution, particularly because the association was attenuated after adjustment for other dietary fat variables.

Dietary cholesterol is related to serum cholesterol levels to some extent (40), and it is possible that changes in serum cholesterol explain the association between dietary cholesterol and diabetes risk (40). Our findings for the Keys score are consistent with the finding that the Keys dietary score indicates positive changes in serum cholesterol predicted by positive changes in dietary cholesterol and saturated fatty acids and negative changes in polyunsaturated fatty acids (13). In two other studies, the univariate or age-adjusted rate of incident diabetes was 50% greater in the highest than in the lowest category of serum cholesterol, although the estimate from only one study was statistically significant (5,8). However, it is difficult to distinguish the relations between the Keys score and serum cholesterol from the relation between the Keys score and saturated and polyunsaturated fatty acid intake, for which the evidence of an association with diabetes is far more compelling.

Differential intakes of dietary fat subtypes may affect diabetes risk by modifying the fatty acid composition of the phospholipid membrane, which may play a role in blood glucose regulation through effects on insulin secretion, insulin receptor properties, and glucose transport. Borkman et al. (41) reported significant inverse relations between fasting serum insulin and the content of -3 and -6 fatty acids within skeletal-muscle phospholipids. Compared with saturated fatty acids, polyunsaturated fatty acids appear to enhance insulin secretion (42), and saturated fatty acids have been shown to decrease insulin binding to receptors and to impair glucose transport (9).

Error in the measurement of diet, diabetes, and covariates in this study may have limited our ability to obtain accurate relative-risk estimates. Random measurement error in dietary exposures most frequently attenuates risk estimates (43). Of particular interest is the potential for misclassification of trans fatty acid intake that resulted from temporal changes in the consumption and manufacturing patterns of trans fatty acids in the U.S. during the 1980s, when many consumers switched to soft, reduced trans fat margarine and industry ceased the partial hydrogenation of household salad and cooking oils (44). These changes could have resulted in a large misclassification of trans fatty acid intake in our population.

The validation study correlation coefficient for cholesterol was quite low (0.21). This did not prevent us from detecting an association between cholesterol and diabetes, but it may reflect a degree of random error in this variable that prevented us from detecting a truly larger magnitude of association. Our validation sample was quite small (n = 44), and it is possible that our sample was aberrant; correlations for other fat variables were similar to those obtained in another large study of women, in which the correlation coefficient for cholesterol was 0.61 (14).

Incident cases of diabetes were ascertained by self-report. Our validation study (see above) suggested that participants over-reported diabetes compared with physician diagnoses (16). This is consistent with findings from one study (45) in which 29 of 44 (66%) positive reports of diabetes were validated with medical records. Nonvalidated positive reports may nonetheless reflect some level of diabetes. One study found that several persons with nonvalidated positive reports of diabetes had some history of glycosuria (46). Thus, nondiabetic concentrations of blood glucose may not be entirely benign, and women who falsely reported a diagnosis of diabetes may still have some level of underlying disease, such as IGT. This possibility is supported by the change in the diagnostic criteria for diabetes to lower levels of fasting glucose (47). The ascertainment of diabetes in the present study was sensitive enough to confirm associations with other risk factors for diabetes (i.e., weight [16], physical activity [48], and dietary fiber [20]) obtained from studies with validated diabetes. Assuming that the error in diabetes ascertainment was independent and nondifferential, present findings would only be strengthened by more accurate ascertainment of disease.

Dietary fat may contribute to the etiology of type 2 diabetes. After adjusting for nondietary and dietary covariates, we found that vegetable fat was inversely related to incident diabetes in this population of older Iowa women. In addition, substituting polyunsaturated fatty acids for saturated fatty acids appeared to reduce the rate of diabetes.

	ACKNOWLEDGMENTS

 
The Iowa Women’s Health Study was funded by a grant (RO1 CA39742) from the National Cancer Institute.

	FOOTNOTES

 
Address correspondence and reprint requests to Dr. Aaron R. Folsom, Division of Epidemiology, School of Public Health, University of Minnesota, Suite 300, 1300 South 2nd St., Minneapolis, MN 55454-1015. E-mail: folsom{at}epi.umn.edu.

Received for publication 28 June 2000 and accepted in revised form 9 April 2001.

A table elsewhere in this issue shows conventional and Système International (SI) units and conversion factors for many substances.

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TOP ABSTRACT INTRODUCTION RESEARCH DESIGN AND METHODS RESULTS CONCLUSIONS References

 

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				J. Ren, I. Dimitrov, A. D. Sherry, and C. R. Malloy Composition of adipose tissue and marrow fat in humans by 1H NMR at 7 Tesla J. Lipid Res., September 1, 2008; 49(9): 2055 - 2062. [Abstract] [Full Text] [PDF]

				L. F. Tinker, D. E. Bonds, K. L. Margolis, J. E. Manson, B. V. Howard, J. Larson, M. G. Perri, S. A. A. Beresford, J. G. Robinson, B. Rodriguez, et al. Low-Fat Dietary Pattern and Risk of Treated Diabetes Mellitus in Postmenopausal Women: The Women's Health Initiative Randomized Controlled Dietary Modification Trial Arch Intern Med, July 28, 2008; 168(14): 1500 - 1511. [Abstract] [Full Text] [PDF]

				N. J. Webster, G. J. Searle, P. P. L. Lam, Y.-C. Huang, M. J. Riedel, G. Harb, H. Y. Gaisano, A. Holt, and P. E. Light Elevation in Intracellular Long-Chain Acyl-Coenzyme A Esters Lead to Reduced {beta}-Cell Excitability via Activation of Adenosine 5'-Triphosphate-Sensitive Potassium Channels Endocrinology, July 1, 2008; 149(7): 3679 - 3687. [Abstract] [Full Text] [PDF]

				S. S. Bassuk and J. E. Manson Lifestyle and Risk of Cardiovascular Disease and Type 2 Diabetes in Women: A Review of the Epidemiologic Evidence American Journal of Lifestyle Medicine, June 1, 2008; 2(3): 191 - 213. [Abstract] [PDF]

				T. L Halton, S. Liu, J. E Manson, and F. B Hu Low-carbohydrate-diet score and risk of type 2 diabetes in women Am. J. Clinical Nutrition, February 1, 2008; 87(2): 339 - 346. [Abstract] [Full Text] [PDF]

				A. M Hodge, D. R English, K. O'Dea, A. J Sinclair, M. Makrides, R. A Gibson, and G. G Giles Plasma phospholipid and dietary fatty acids as predictors of type 2 diabetes: interpreting the role of linoleic acid Am. J. Clinical Nutrition, July 1, 2007; 86(1): 189 - 197. [Abstract] [Full Text] [PDF]

				T. T. Fung, M. McCullough, R. M. van Dam, and F. B. Hu A Prospective Study of Overall Diet Quality and Risk of Type 2 Diabetes in Women Diabetes Care, July 1, 2007; 30(7): 1753 - 1757. [Abstract] [Full Text] [PDF]

				G. Hu, P. Jousilahti, and J. Tuomilehto Prevalence of Nonalcoholic Fatty Liver Disease and Its Association With Cardiovascular Disease Among Type 2 Diabetic Patients: Response to Talim Diabetes Care, June 1, 2007; 30(6): e56 - e56. [Full Text] [PDF]

				A. H. Auchincloss, A. V. Diez Roux, D. G. Brown, E. S. O'Meara, and T. E. Raghunathan Association of Insulin Resistance with Distance to Wealthy Areas: The Multi-Ethnic Study of Atherosclerosis Am. J. Epidemiol., February 15, 2007; 165(4): 389 - 397. [Abstract] [Full Text] [PDF]

				J. A. Nettleton, L. J. Harnack, C. G. Scrafford, P. J. Mink, L. M. Barraj, and D. R. Jacobs Jr. Dietary Flavonoids and Flavonoid-Rich Foods Are Not Associated with Risk of Type 2 Diabetes in Postmenopausal Women J. Nutr., December 1, 2006; 136(12): 3039 - 3045. [Abstract] [Full Text] [PDF]

				J. Halkjaer, A. Tjonneland, B. L Thomsen, K. Overvad, and T. I. Sorensen Intake of macronutrients as predictors of 5-y changes in waist circumference. Am. J. Clinical Nutrition, October 1, 2006; 84(4): 789 - 797. [Abstract] [Full Text] [PDF]

				D. Mozaffarian, M. B. Katan, A. Ascherio, M. J. Stampfer, and W. C. Willett Trans Fatty Acids and Cardiovascular Disease N. Engl. J. Med., April 13, 2006; 354(15): 1601 - 1613. [Full Text] [PDF]

				M. J. Riedel and P. E. Light Saturated and cis/trans Unsaturated Acyl CoA Esters Differentially Regulate Wild-Type and Polymorphic {beta}-Cell ATP-Sensitive K+ Channels Diabetes, July 1, 2005; 54(7): 2070 - 2079. [Abstract] [Full Text] [PDF]

				J. N. Clore, J. S. Stillman, J. Li, S. J. D. O'Keefe, and J. R. Levy Differential effect of saturated and polyunsaturated fatty acids on hepatic glucose metabolism in humans Am J Physiol Endocrinol Metab, August 1, 2004; 287(2): E358 - E365. [Abstract] [Full Text] [PDF]

				E. Ros Dietary cis-monounsaturated fatty acids and metabolic control in type 2 diabetes Am. J. Clinical Nutrition, September 1, 2003; 78(3): 617S - 625. [Abstract] [Full Text] [PDF]

				L. Wang, A. R Folsom, Z.-J. Zheng, J. S Pankow, and J. H Eckfeldt Plasma fatty acid composition and incidence of diabetes in middle-aged adults: the Atherosclerosis Risk in Communities (ARIC) Study Am. J. Clinical Nutrition, July 1, 2003; 78(1): 91 - 98. [Abstract] [Full Text] [PDF]

				K. Eitel, H. Staiger, J. Rieger, H. Mischak, H. Brandhorst, M. D. Brendel, R. G. Bretzel, H.-U. Haring, and M. Kellerer Protein Kinase C {delta} Activation and Translocation to the Nucleus Are Required for Fatty Acid-Induced Apoptosis of Insulin-Secreting Cells Diabetes, April 1, 2003; 52(4): 991 - 997. [Abstract] [Full Text] [PDF]

				A. C. Thanopoulou, B. G. Karamanos, F. V. Angelico, S. H. Assaad-Khalil, A. F. Barbato, M. P. Del Ben, P. B. Djordjevic, V. S. Dimitrijevic-Sreckovic, C. A. Gallotti, N. L. Katsilambros, et al. Dietary Fat Intake as Risk Factor for the Development of Diabetes: Multinational, multicenter study of the Mediterranean Group for the Study of Diabetes (MGSD) Diabetes Care, February 1, 2003; 26(2): 302 - 307. [Abstract] [Full Text] [PDF]

				F. B. Hu and W. C. Willett Optimal Diets for Prevention of Coronary Heart Disease JAMA, November 27, 2002; 288(20): 2569 - 2578. [Abstract] [Full Text] [PDF]

				H. S Kahn and R. Valdez Fatty acid composition of abdominal adipose tissue Am. J. Clinical Nutrition, June 1, 2002; 75(6): 1123 - 1123. [Full Text] [PDF]

				R. M. van Dam, W. C. Willett, E. B. Rimm, M. J. Stampfer, and F. B. Hu Dietary Fat and Meat Intake in Relation to Risk of Type 2 Diabetes in Men Diabetes Care, March 1, 2002; 25(3): 417 - 424. [Abstract] [Full Text] [PDF]

				J. A. Marshall and D. H. Bessesen Dietary Fat and the Development of Type 2 Diabetes Diabetes Care, March 1, 2002; 25(3): 620 - 622. [Full Text] [PDF]

M. J. Franz, J. P. Bantle, C. A. Beebe, J. D. Brunzell, J.-L. Chiasson, A. Garg, L. A. Holzmeister, B. Hoogwerf, E. Mayer-Davis, A. D. Mooradian, et al. Evidence-Based Nutrition Principles and Recommendations for the Treatment and Prevention of Diabetes and Related Complications Diabetes Care, January 1, 2002; 25(1): 148 - 198. [Full Text] [PDF]