Download Report

Trans Fatty
Acids Report
(PDF)


About Adobe PDF



Contact
Information


Robin Herman
Director of
Communications

  TRANS FATTY ACIDS AND CORONARY HEART DISEASE


UPDATE

Under new FDA guidelines, as of January 1, 2006, trans fat must be listed on food labels in the U.S.

The trans fat labeling requirement is the first significant change to the Nutrition Facts panel since the Nutritional, Labeling, and Education Act regulations were finalized in 1993, according to the FDA.

Harvard School of Public Health researchers helped sound the alarm about trans fat and coronary heart disease risk in the early 1990s and advocated that it be explicitly listed on food labels.

In an updated analysis of the trans fat-heart disease link, HSPH researchers have found that removing trans fats from the industrial food supply could prevent tens of thousands of heart attacks and cardiac deaths each year in the U.S.(1) The findings are published in the April 13, 2006 issue of the New England Journal of Medicine.

For the latest information on the link between trans fat consumption and heart disease, and for details on the trans fat labeling law, please visit HSPH’s Nutrition Source website. The detailed Background and Scientific Review article, below, will be updated shortly to reflect the latest developments.

References

1. Mozaffarian D, Katan MB, Ascherio A, Stampfer MJ, Willett WC. Trans fatty acids and cardiovascular disease. N Engl J Med. 2006 Apr 13;354(15):1601-13.

On November 12, 1999, the Food and Drug Administration announced its proposal to include the trans-fatty acid (trans fat) content of foods on the standard food label. A 90-day period in which the public may comment then began. At present, only saturated fats are listed. Because many persons will be unfamiliar with trans fat and its health effects, we have prepared the following review.

BACKGROUND AND SCIENTIFIC REVIEW
by Alberto Ascherio, Meir J. Stampfer, and Walter C. Willett

Departments of Nutrition and Epidemiology, Harvard School of Public Health; The Channing Laboratory, Department of Medicine, Brigham and Women's Hospital

What are trans fatty acids?

Trans unsaturated fatty acids, or trans fats, are solid fats produced artificially by heating liquid vegetable oils in the presence of metal catalysts and hydrogen.1 This process, partial hydrogenation, causes carbon atoms to bond in a straight configuration and remain in a solid state at room temperature. Naturally-occurring unsaturated fatty acids have carbon atoms that line up in a bent shape, resulting in a liquid state at room temperature.

Which foods contain trans fatty acids?

Trans fats are produced commercially in large quantities to harden vegetable oils into shortening and margarine. Food manufacturers also use partial hydrogenation of vegetable oil to destroy some fatty acids, such as linolenic and linoleic acid, which tend to oxidize, causing fat to become rancid with time. The oils used to cook french fries and other fast food are usually this kind of partially hydrogenated oil, containing trans fats. Commercial baked goods frequently include trans fats to protect against spoilage. A small amount of trans fat is also produced in the gastrointestinal tract of cattle, so that low levels of these isomers are found in dairy and beef fat.

Commercial production of partially hydrogenated fats began in the early 20th century and increased steadily until about the 1960s as processed vegetable fats displaced animal fats in the diets of the U.S. and other Western countries. Lower cost was the initial motivation, but health benefits were later claimed for margarine as a replacement for butter.

Although the average level of trans fat in margarines has declined with the advent of softer versions, per capita consumption of trans fatty acids has not changed greatly since the 1960s because of the increased use in commercially-baked products and fast foods.

What are the health effects of trans fats?

Concerns have been raised for several decades that consumption of trans fatty acids might have contributed to the 20th century epidemic of coronary heart disease.2

Metabolic studies have shown that trans fats have adverse effects on blood lipid levels--increasing LDL ("bad") cholesterol while decreasing HDL ("good") cholesterol. This combined effect on the ratio of LDL to HDL cholesterol is double that of saturated fatty acids.3

Trans fats have also been associated with an increased risk of coronary heart disease in epidemiologic studies.4

Based on the available metabolic studies, we estimated in a 1994 report that approximately 30,000 premature coronary heart disease deaths annually could be attributable to consumption of trans fatty acids.4

In response to these reports, a 1995 review sponsored by the food industry concluded that the evidence was insufficient to take action and that further research was needed.5 Since that time many more metabolic studies have been conducted and additional prospective epidemiologic studies have been reported.

Because of the weight of the evidence, the FDA has recently issued a proposal for including trans fatty acid content on the food label. One important issue is whether to list trans fat as a separate constituent or to combine it with saturated fat.

What are the arguments for listing trans fat separately from saturated fat?

The combined results of metabolic and epidemiologic studies strongly support an adverse effect of trans fat on risk of CHD. Furthermore, two independent methods of estimation indicate that the adverse effect of trans fat is stronger than that of saturated fat. By our most conservative estimate, replacement of partially hydrogenated fat in the U.S. diet with natural unhydrogenated vegetable oils would prevent approximately 30,000 premature coronary deaths per year, and epidemiologic evidence suggests this number is closer to 100,0000 premature deaths annually. These reductions are higher than what could be achieved with realistic reductions in saturated fat intake.

What alternatives exist to trans fats?

In Europe, producers have responded rapidly to the evidence on effects of trans fats by developing trans-free margarines that are also low in saturated fats.48 More recently, these products have also become available in the U.S., although a large share of the market is still heavily hydrogenated stick margarine.5

It is thus evident that trans-free products are feasible, and that the technical constraints often invoked by the food industry can be overcome. However, out of the trans fatty acids provided by hydrogenated vegetable oil in the U.S., only 25%5 to 37%49 comes from margarines, the remainder comes from baked goods, fast foods and other prepared foods. Replacement of trans in such products by healthier fats may be more difficult than in margarines, but can be achieved.

In spite of this, many products including most baked goods and fried fast foods still are made with partially hydrogenated fat both in Europe and in the U.S. and are high in trans fatty acids. It is unlikely that this situation will change without strong federal regulations.

How important are label changes?

Current regulations in the U.S. require food labels to include the amount of saturated fat, but not the amount of trans, thereby providing an incentive to manufacturers to increase the trans content while decreasing the amount of saturated fat.

Although changes in labeling are extremely important, many products, including fast food, which often contain extremely high levels of trans isomers, are exempt from labeling regulations and can carry deceptive labels such as "cholesterol-free" and "cooked in vegetable oil."

For example, a person eating one doughnut for breakfast (3.2 g)50 and a large order of french fries for lunch (6.8 g)50 would ingest 10 g of trans fatty acids, or 5 percent of the total energy of an 1,800-calorie diet. Thus, simple labeling changes alone will not be sufficient.

The following is a more detailed review of the scientific studies behind these conclusions:

Effects on plasma lipids
Studies in the 1960s compared the effects of partially hydrogenated fat with those of unhydrogenated vegetable oils or saturated fats on the concentrations of total serum cholesterol. Overall, these earlier studies suggested that the cholesterol raising effect of hydrogenated fat was somewhat lower than that of saturated fats.1, 6 Only in 1990 was attention given to the fact that although trans fatty acids increase LDL cholesterol to a similar degree as saturated fat, they decrease HDL cholesterol relative to both cis unsaturated or saturated fats.3 In a rigorous metabolic study, Mensink and Katan demonstrated that replacement of 10% of energy from oleic acid (the primary monounsaturated fat in diets) with trans 18:1 fatty acids caused a 0.34 mmol/L increase in LDL cholesterol and a 0.17 mmol/L decrease in HDL cholesterol; whereas replacement of oleic acid with saturated fat caused a similar increase in LDL cholesterol, but virtually no change in HDL cholesterol. As a result, the LDL/HDL cholesterol ratio was significantly higher on the trans (2.58) than on the saturated (2.34) or oleic (2.02) diets. These findings were soon confirmed in several investigations, including the study by Lichtenstein et al. that appears in this issue of the Journal, using lower levels of trans fatty acids and different mixtures of trans isomers.7-10 Figure 1 summarizes the randomized trials that allow a direct comparison of trans fatty acids with isocaloric amounts of cis unsaturated fat;3, 7-15 also included is the study of Aro et al.13 that used stearic (which is usually said to have a neutral effect on blood lipids) rather than oleic acid as the control diet. Overall, trans fatty acids increased LDL cholesterol similarly to saturated fat, but, unlike saturated fat, they also decreased HDL cholesterol. As a result, the net effect of trans fat on the LDL/HDL cholesterol ratio is approximately double that of saturated fat. The difference between the effect of trans fat and that of saturated fat on the LDL/HDL ratio was significant in each of the six studies that allowed a direct comparison. The corresponding P values were: <0.0001,3 <0.001,7 <0.001,8 <0.009,9 <0.01,10 <0.05.14 Thus, the probability that these results were due to chance is vanishingly low; taken together, these studies provide definitive evidence that trans fats raise the LDL/HDL ratio more than saturated fats. Moreover, these effects of trans fat on the LDL/HDL cholesterol ratio are remarkably constant across studies. The only somewhat discordant result was obtained by Sundram et al. among 27 men and women who were staff of the Palm Oil Research Institute in Malaysia.14 In that study, the effect of trans fat on the LDL/HDL cholesterol ratio was considerably stronger than in the other investigations (see Figure 1), whereas little effect was seen for saturated fat (palmitic acid). The more marked response has been attributed to the habitual Malaysian diet consumed by participants at baseline, which is lower in total fat (26% energy) than typical western diets.14 Although the possibility that the adverse effects of trans fat are more marked in populations with a lower percent of energy from fat cannot be excluded, we have conservatively excluded the Malaysian study in estimating the regression lines in Figure 1. Its inclusion would make the association between trans fat and LDL/HDL ratio even stronger. Also not included was the study by Almendingen at al. that compared the effects of diets containing partially hydrogenated fish oil (8.4% energy from trans fat), partially hydrogenated soy bean oil (6.6% energy from trans fat), or butter. The LDL/HDL cholesterol ratio was significantly higher on the partially hydrogenated fish oil diet (4.20) compared to both the partially hydrogenated soy bean oil diet (3.65) or the butter diet (3.85), that were not significantly different from each other. Thus, the Almendingen Study did not find an increase in the LDL/HDL ratio on partially hydrogenated soybean oil compared with butter. The lack of a high oleic or polyunsaturated diet prevented its inclusion in Figure 1, but the inclusion of these data does not materially change the estimated effect of trans fatty acids on the LDL/HDL ratio.

In addition to the studies summarized above, other dietary trials have compared the effects of butter and margarine on blood lipids. Because margarines are usually higher in cis polyunsaturated fat than butter, the specific effects of trans fat cannot be accurately estimated from these trials. A meta-analysis of these investigations, however, showed that replacement of butter with hard stick margarines -- that typically have contained 20-25% trans fat -- does not affect the total/HDL cholesterol ratio, whereas a reduction was obtained with low-trans tub margarine.16 These results confirm the deleterious effects of trans fat on blood lipids and indicate that these may offset the beneficial effects of polyunsaturated fat. Thus individuals who are replacing butter with margarine high in trans fat to reduce their risks of coronary disease may obtain no benefit or -- if trans fat has deleterious effects beyond those on LDL and HDL -- may even increase their risk.

In addition to increasing the LDL/HDL cholesterol ratio, trans fatty acids increase Lp(a) when substituted for saturated fat. A significant increase was reported in nine3, 8, 10, 12-15, 17 of ten trials. The null result was from an investigation that included only 14 subjects who consumed a diet with 3.7% energy from trans fat; the power of this study may have been to low to demonstrate an effect.11 High blood levels of Lp(a) have been associated in some studies with increased risk of CHD, independently of LDL or HDL cholesterol concentrations. However diet-induced variations in blood concentrations of Lp(a) are modest relative to the genetic differences, and their quantitative impact on risk of CHD remains to be established.

Yet another effect of trans fatty acids on blood lipids is that on fasting triglyceride levels. Already in 1961, the group of Ancel Keys noted that hydrogenated corn oil resulted in higher triglyceride levels than natural oils or butter.6 A triglyceride-raising effect was also consistently seen in seven recent studies that directly compared trans fatty acids with cis-unsaturated fatty acids;3, 7-9, 11, 14, 15 the increases ranged from 0.5 to 12 mg/dL, with an average of 1.5 mg/dL per 1% of energy intake. The effect on triglyceride levels of substituting saturated fatty acids for cis-unsaturated fatty acids is about zero.18 Thus, trans fatty acids increase triglyceride levels when compared with other fatty acids. Eliminating 2% of energy trans fatty acid from the diet would lower triglyceride levels by about 3 mg/dL; the relation between triglycerides and risk of CHD is still uncertain, but the resulting benefit is probably modest.

Potential effects of trans fat on LDL oxidation8, 19 and coagulation and fibrinolytic factors20-22 have also been investigated, but so far there is no conclusive evidence of adverse effects.

Epidemiological studies
One of the most influential studies on diet and CHD was the work of Keys23 who related the incidence of heart disease in 16 defined populations in seven countries to their intake of fat and cholesterol. The clear association that he found between percent of energy as saturated fat and CHD incidence and mortality has often been quoted as strong evidence that saturated fat increases the risk of CHD. The original investigations have now been complemented by collection and analyses of food composites representing the average intake of each cohort at baseline, so that the relation of CHD incidence and mortality to intake of trans fat and other specific nutrients could be examined.24 Whereas saturated fat intake was strongly correlated to CHD mortality (r=0.88; P < 0.0001), confirming the original results, a similar positive correlation was found between CHD mortality and trans fat intake (r=0.78; P < 0.0001). Interpretation of such comparisons of populations with widely different lifestyles is hazardous, but at the very least these data leave room for a major effect of trans fat on CHD risk.

Several case-control or cross-sectional studies have also been conducted. In a case-control study in the Boston area, we found a strong and significant positive association between trans fat intake assessed using a FFQ and risk of acute myocardial infarction.25 The relative risk comparing the highest to the lowest quintile of trans fat intake was 2.4 (P for trend <0.0001); this association was entirely explained by trans intake from hydrogenated vegetable oil. Previously, Bolton-Smith et al. examined cross-sectionally the association between trans intake and undiagnosed CHD among participants in the Scottish Heart Study.26 Subjects were considered to have CHD if they had angina or possible MI according to the Rose chest pain questionnaire, or an electrocardiogram recording indication of ischemia.26 Trans intake, estimated by a FFQ, was positively correlated with the (LDL+VLDL)/HDL cholesterol ratio. The odds ratio for risk of CHD comparing the highest versus the lowest quintile of intake were elevated but not statistically significant (1.26 in women, and 1.08 in men). Positive associations between consumption of margarine and risk of acute myocardial infarction were found in a case-control study in Italy27 and one in Greece.28 Investigations in which tissue or plasma fatty acids composition was used as a biomarker of trans intake29-36 gave conflicting results. With one exception,33 however, these investigations were small, and the power too low to reliably detect an association. The only large study, the EURAMIC study,33 included 671 men with acute myocardial infarction in eight European countries. The overall analyses revealed no association between trans intake and risk of myocardial infarction (multivariate odds ratio comparing the top vs. the bottom quartile was 0.97). The two centers in Spain, where CHD rates are very low, however, had extremely low trans levels and little between-person variation compared to those from other countries, and thus provided little or no information on the relation between trans and CHD. After appropriately excluding these centers, the odds ratio in the third and fourth quartile increased to 1.53 (95% confidence interval: 1.02, 2.28) and 1.44 (0.94, 2.20) respectively. In addition, there was significant heterogeneity in the odds ratios between countries, from 0.2 in Spain and Moscow, to 5.0 in Finland and 5.4 in Norway. This heterogeneity may be due to different amounts, and sources of trans -- and therefore different isomers -- in different countries (for example in Spain, unlike in the other countries, most dietary trans fatty acids are from animal sources), or, more likely, to interaction with other dietary factors, or confounding by unmeasured or poorly measured covariates. Interpretation of the EURAMIC results is controversial, but in any case they do not provide strong evidence against the hypothesis that trans fatty acids increase the risk of CHD, and if anything add weight to the existence of a positive association.

The strongest epidemiological evidence relating dietary factors to risk of CHD is provided by prospective investigations. The relation between trans fatty acids intake and risk of coronary disease has now been reported from three large cohort studies, the Health Professionals Follow-up Study (HPFS),37 the Alpha-Tocopherol Beta-Carotene study (ATBC)38 and the Nurses Health Study (NHS)39. In these studies, trans fat consumption was assessed using detailed food frequency questionnaires (FFQ) that were validated by comparison with adipose composition40, 41 or several days of diet records.42 In addition, the relation between margarine intake and risk of CHD has been reported from the Framingham cohort.43 The results of each of these investigations support an adverse effect of trans fatty acids. The relative risk of coronary heart disease for a 2% increase in trans fatty acids intake was 1.36 (95% confidence interval: 1.03, 1.81) in the HPFS, 1.14 ( 0.96, 1.35) in the ATBC, and 1.93 (1.43, 2.61) in the NHS. The higher relative risk in the NHS may be related to the fact that this investigation took advantage of up to four repeated dietary measurements during the follow-up, thereby reducing the error in assessing trans consumption; in analyses using only the baseline dietary measure, the corresponding relative risk was 1.62. In all cohorts, these relative risks were considerably higher than those for saturated fat. For example, in the NHS replacing 5 percent of energy from saturated fat with energy from unsaturated fat was associated with a 42 percent lower risk, whereas replacing 2 percent of energy from trans unsaturated fat with energy from unhydrogenated, unsaturated fats was associated with a 53 percent lower risk. These studies have been criticized on the grounds that measurements of trans intake were unreliable;5 however, errors in measuring trans fatty acids intake can only have led to underestimation of the association with CHD risk.44 Also, it has been suggested that the observed associations resulted from a shift from butter to margarine among subjects at high risk of CHD.45 If so, the association between trans intake and risk of CHD should be weaker among subjects with stable margarine consumption, and should be stronger during the first few years of follow-up. In fact, the opposite was true in the Nurses Health Study,46 where exclusion of women who changed their diet before the beginning of the study strengthened the association,46 and in the Framingham cohort, where the positive association between margarine consumption and CHD risk was strengthened after excluding the first ten years of follow-up.43 Moreover, high consumption of trans (or margarine) was not related to other dietary behaviors perceived as healthy for the heart, such as a preference for skim rather than whole milk43 and high-trans foods that are hardly perceived as healthy, such as cookies, were also positively associated with risk of CHD in the Nurses Health Study.46 Thus there appear to be no likely alternative to the hypothesis that high trans intake increases the risk of CHD. Although confounding by unmeasured or poorly measured risk factors cannot be excluded, as is usually the case in observational studies, we lack a credible hypothesis of what such confounder(s) could be, as these associations were controlled for an extensive number of other dietary and lifestyle risk factors. In the Health Professionals Follow-up Study, adjustment for dietary fiber attenuated the relation of trans to risk of CHD, however no attenuation occurred in the other two cohorts38 (Hu, personal communication). In summary, prospective studies provide strong evidence that trans fatty acids consumption increases substantially the risk of CHD.

Quantitative estimates of risk
Independent estimates of the effect of trans fat can be obtained by combining the effects of trans on blood lipids and the relationship between lipids and coronary heart disease risk, or from the results of cohort studies. We have used these different methods to estimate the number of deaths that may be due to consumption of trans fatty acids from partially hydrogenated fat in the amount of 2% energy (approximately the U.S. average).

The first approach uses only the effect of trans fats on blood lipids, and ignores the associations observed in epidemiological studies. As shown above (Figure 1), replacing 2% energy from cis unsaturated fat with an isocaloric amount of trans fat causes a 0.13 increase in the LDL/HDL cholesterol ratio (we used this because the effect of trans on the total/HDL cholesterol ratio that we used in the past was not provided in one of the new studies). Since a change in one unit in the total/HDL cholesterol ratio has been associated with a 53% change in the CHD risk,47 we estimated a relative risk of 1.07 (1 + 0.53 x 0.13) for a 2% increase in trans fat (the use of LDL/HDL ratio instead of total/HDL cholesterol ratio has trivial effects), corresponding to an attributable risk of 6.5% (0.07 divided by 1.07). The effect of saturated fat on the LDL/HDL ratio is about half that of trans fat, so that the same attributable risk would be estimated for a 4% of energy increase from saturated fat. These are likely to be underestimates of the true effect, because the lipid-CHD relation that we used has not been corrected for the attenuation caused by within-person variation in lipid measurements. Also, the estimate for trans fat does not take into account adverse effects on triglycerides or Lp(a). In the metabolic studies, cis unsaturated fats replaced trans fat as would be the case if the original oils were simply not partially hydrogenated. Because unsaturated fats themselves have beneficial effects on blood lipids, the benefits of eliminating trans or saturated fats would be less if they were replaced by carbohydrate.

The second approach calculates risk directly from the strength of the association between trans fat and CHD as observed in epidemiological studies. A pooled estimate of the results reported in the prospective studies (ATBC, HPFS, and NHS) gives a relative risk of 1.31 (1.15, 1.49) for an increase in trans consumption of 2% of energy. Assuming that this relation is causal, the attributable risk would be 24%, or over 100,000 coronary deaths per year. Moreover, according to the results of the HPFS and NHS, it would require a 10% of energy reduction in saturated fat intake to obtain a benefit comparable to that of eliminating trans fat from the U.S. diet. No benefit of reducing saturated fat intake would be predicted by the results of the ATBC.

Our first approach, using data from metabolic studies obtained above, assumes that the adverse effects of trans are entirely mediated by their effects on blood levels of LDL and HDL; whereas, the second approach, using results of epidemiological studies, suggests that the increase in risk of CHD caused by trans fat is higher than predicted by effects on blood lipids alone. Ignoring this possibility could cause a substantial underestimation of the adverse effects of trans fat.

Conclusion
Five years ago evidence was strong that trans fat had deleterious impacts on blood lipids; ensuing studies have confirmed these metabolic findings and strengthened epidemiologic support for an important adverse effect on risk of coronary heart disease. These data highlight the need for rapid implementation of labeling requirements that include fast foods. Because partially hydrogenated fats can be eliminated from the food supply by changes in processing that do not require major efforts in education and behavioral modification, these changes would be an extremely efficient and rapid method for substantially reducing rates of coronary disease.

Acknowledgment
We would like to thank Jill Arnold for her expert assistance with this review.

References

1. Katan MB, Mensink RP, Zock PL. Trans fatty acids and their effect on lipoproteins in humans. Annu Rev Nutr 1995; 15:473-493.

2. Booyens J, Louwrens CC, Katzeff IE. The role of unnatural dietary trans and cis unsaturated fatty acids in the epidemiology of coronary artery disease. Med Hypotheses 1988; 25:175-182.

3. Mensink RPM, Katan MB. Effect of dietary trans fatty acids on high-density and low-density lipoprotein cholesterol levels in healthy subjects. N Engl J Med 1990; 323:439-45.

4. Willett WC, Ascherio A. Trans fatty acids: Are the effects only marginal? Am J Public Health 1994; 84:722-724.

5. Expert Panel on Trans Fatty Acids and Coronary Heart Disease. Trans fatty acids and coronary heart disease risk. Am J Clin Nutr 1995; 62:655S-708S.

6. Anderson JT, Grande F, Keys A. Hydrogenated fats in the diet and lipids in the serum of man. J Nutr 1961; 75:388-394.

7. Zock PL, Katan MB. Hydrogenation alternatives: effects of trans fatty acids and stearic acid versus linoleic acid on serum lipids and lipoproteins in humans. J Lipid Res 1992; 33:399-410.

8. Nestel P, Noakes M, Belling Bea. Plasma lipoprotein and Lp[a] changes with substitution of elaidic acid for oleic acid in the diet. J Lipid Res 1992; 33:1029-1036.

9. Judd JT, Clevidence BA, Muesing RA, Wittes J, Sunkin ME, Podczasy JJ. Dietary trans fatty acids: effects of plasma lipids and lipoproteins on healthy men and women. Am J Clin Nutr 1994; 59:861-868.

10. Judd J, Baer D, Clevidence B, et al. Blood lipid and lipoprotein modifying effects of trans monounsaturated fatty acids compared to carbohydrate, oleic acid, stearic acid, and C 12:0-16:0 saturated fatty acids in men fed controlled diets (abstract). FASEB J 1998; 12:1339.

11. Lichtenstein AH, Ausman LM, Carrasco W, Jenner JL, Ordovas JM, Schaefer EJ. Hydrogenation impairs the hypolipidemic effect of corn oil in humans. Hydrogenation, trans fatty acids, and plasma lipids. Aterioscler Thromb 1993; 13:154-161.

12. Almendingen K, Jordal O, Kierulf P, Sandstad B, Pedersen JI. Effects of partially hydrogenated fish oil, partially hydrogenated soybean oil, and butter on serum lipoproteins and Lp[a] in men. J Lipid Res 1995; 36:1370-1384.

13. Aro A, Jauhiainen M, Partanen R, Salminen I, Mutanen M. Stearic acid, trans fatty acids, and dairy fat: effects on serum and lipoprotein lipids, apolipoproteins, lipoprotein(a), and lipid transfer proteins in healthy subjects. Am J Clin Nutr 1997; 65:1419-1426.

14. Sundram K, Ismail A, Hayes KC, Jeyamalar R, Pathmanathan R. Trans (elaidic) fatty acids adversely affect the lipoprotein profile relative to specific saturated fatty acids in humans. J Nutr 1997; 127:514S-520S.

15. Lichtenstein AH, Ausman LM, Jalbert SM, Schaefer EJ. Effects of different forms of dietary hydrogenated fats on serum lipoprotein cholesterol levels in moderately hypercholesterolemic female and male subjects. N Engl J Med 1999.

16. Zock PL, Katan MB. Butter, margarine and serum lipoproteins. Atherosclerosis 1997; 131:7-16.

17. Clevidence BA, Judd JT, Schaefer EJ, et al. Plasma lipoprotein (a) levels in men and women consuming diets enriched in saturated, Cis-, or Trans-monounsaturated fatty acids. Arterioscler Thromb Vasc Biol 1997; 17:1657-1661.

18. Mensink RP, Katan MB. Effect of dietary fatty acids on serum lipids and lipoproteins: a meta-analysis of 27 trials. Arteriosclerosis and Thrombosis 1992; 12:911-919.

19. Cuchel M, Schwab US, Jones PJ, et al. Impact of hydrogenated fat consumption on endogenous cholesterol synthesis and susceptibility of low-density lipoprotein to oxidation in moderately hypercholesterolemic individuals. Metabolism 1996; 45:241-247.

20. Chardigny JM, Sébédio JL, Juaneda P, Vatele JM, Grandgirard A. Effects of trans N-3 polyunsaturated fatty acids on human platelet aggregation. Nutr Res 1995; 15:1463-1471.

21. Almendingen K, Seljeflot I, Sandstad B, Pedersen JI. Effects of partially hydrogenated fish oil, partially hydrogenated soybean oil, and butter on hemostatic variables in men. Arterioscler Thromb Vasc Biol 1996; 16:375-380.

22. Mutanen M, Aro A. Coagulation and fibrinolysis factors in healthy subjects consuming high stearic or trans fatty acid diets. Thromb Haemost 1997; 77:99-104.

23. Keys A. Seven Countries: A multivariate analysis of death and coronary heart disease. Cambridge, MA: Harvard University Press, 1980.

24. Kromhout D, Menotti A, Bloemberg B, et al. Dietary saturated and trans fatty acids and cholesterol and 25-year mortality from coronary heart disease: The Seven Countries Study. Prev Med 1995; 24:308-315.

25. Ascherio A, Hennekens CH, Buring JE, Master C, Stampfer MJ, Willett WC. Trans fatty acids intake and risk of myocardial infarction. Circulation 1994; 89:94-101.

26. Bolton-Smith C, Woodward M, Fenton S, Brown CA. Does dietary trans fatty acid intake relate to the prevalence of coronary heart disease in Scotland? Eur Heart J 1996; 17:837-845.

27. Tavani A, Negri E, D'Avanzo B, La Vecchia C. Margarine intake and risk of nonfatal acute myocardial infarction in Italian women. Eur J Clin Nutr 1997; 51:30-32.

28. Tzonou A, Kalandidi A, Trichopoulou A, et al. Diet and coronary heart disease: A case-control study in Athens, Greece. Epidemiology 1993; 4:511-516.

29. Thomas LH, Winter JA, Scott RG. Concentration of 18:1 and 16:1 transunsaturated fatty acids in the adipose body tissue of decedents dying of ischaemic heart disease compared with controls: analysis by gas liquid chromatography. J Epidemiol Community Health 1983; 37:16-21.

30. Thomas LH, Winter JA, Scott RC. Concentration of transunsaturated fatty acids in the adipose body tissue of decedents dying of ischaemic heart disease compared with controls. J Epidemiol Community Health 1983; 37:22-24.

31. Siguel EN, Lerman RH. Trans-fatty acid patterns in patients with angiographically documented coronary artery disease. Am J Cardiol 1993; 71:916-920.

32. Roberts TL, Wood DA, Riemersma RA, Gallagher PJ, Lampe FC. Trans isomers of oleic and linoleic acids in adipose tissue and sudden cardiac death. Lancet 1995; 345:278-282.

33. Aro A, Kardinaal AF, Salminen I, et al. Adipose tissue isomeric trans fatty acids and risk of myocardial infarction in nine countries: the EURAMIC study. Lancet 1995; 345:273-278.

34. Hodgson JM, Wahlqvist ML, Boxall JA, Balazs ND. Platelet trans fatty acids in relation to angiographically assessed coronary artery disease. Atherosclerosis 1996; 120:147-154.

35. van de Vijver LPL, van Poppel G, van Houwelingen A, Kruyssen DAC, Hornstra G. Trans unsaturated fatty acids in plasma phospholipids and coronary heart disease: a case-control study. Atherosclerosis 1996; 126:155-161.

36. Watts GF, Jackson P, Burke V, Lewis B. Dietary fatty acids and progression of coronary artery disease in men. Am J Clin Nutr 1996; 64:202-209.

37. Ascherio A, Rimm EB, Giovannucci EL, Spiegelman D, Stampfer MJ, Willett WC. Dietary fat and risk of coronary heart disease in men: cohort follow up study in the United States. BMJ 1996; 313:84-90.

38. Pietinen P, Ascherio A, Korhonen P, et al. Intake of fatty acids and risk of coronary heart disease in a cohort of Finnish men: The ATBC Study. Am J Epidemiol 1997; 145:876-887.

39. Hu FB, Stampfer MJ, Manson JE, et al. Dietary fat intake and the risk of coronary heart disease in women. N Engl J Med 1997; 337:1491-1499.

40. London SJ, Sacks FM, Caesar J, Stampfer MJ, Siguel E, Willett WC. Fatty acid composition of subcutaneous adipose tissue and diet in post-menopausal US women. Am J Clin Nutr 1991; 54:340-345.

41. Hunter DJ, Rimm EB, Sacks FM, et al. Comparison of measures of fatty acid intake by subcutaneous fat aspirate, food frequency questionnaire, and diet records in a free-living population of US men. Am J Epidemiol 1992; 135:418-427.

42. Pietinen P, Hartman AM, Haapa E, et al. Reproducibility and validity of dietary assessment instruments II. A qualitative food-frequency questionnaire. Am J Epidemiol 1988; 128:667-676.

43. Gillman MW, Cupples LA, Gagnon D, Millen BE, Ellison RC, Castelli WP. Margarine intake and subsequent coronary heart disease in men. Epidemiology 1997; 8:144-149.

44. Greenland S. The effect of misclassification in the presence of covariates. Am J Epidemiol 1980; 112:564-569.

45. Shapiro S. Do trans fatty acids increase the risk of coronary heart disease? A critique of the epidemiologic evidence. Am J Clin Nutr 1997; 66(suppl):1011S-1017S.

46. Willett WC, Stampfer MJ, Manson JE, et al. Intake of trans fatty acids and risk of coronary heart disease among women. Lancet 1993; 341:581-585.

47. Stampfer MJ, Sacks FM, Salvini S, Willett WC, Hennekens CH. A prospective study of cholesterol, apolipoproteins, and the risk of myocardial infarction. N Engl J Med 1991; 325:373-81.

48. Katan MB. Exit trans fatty acids (Invited Commentary). Lancet 1995; 346:1245-1246.

49. Hunter JE, Applewhite TH. Reassessment of trans fatty acid availability in the U.S. diet. Am J Clin Nutr 1991; 54:363-369.

50. Litin L, Sacks F. Trans-fatty-acid content of common foods. N Engl J Med 1993; 329:1969-1970.

  For further information contact:

Robin Herman, Assistant Dean for Communications, HSPH


Phone: (617) 432-4752
Email:
rherman@hsph.harvard.edu

Copyright, 1999,  President and Fellows of Harvard College
Last Updated: November 15, 1999 
You are visitor number: 162630 since November 15, 1999.