Hostname: page-component-cd9895bd7-dk4vv Total loading time: 0 Render date: 2024-12-28T15:03:48.325Z Has data issue: false hasContentIssue false

Effect of the dietary fat quality on insulin sensitivity

Published online by Cambridge University Press:  08 April 2008

José E. Galgani*
Affiliation:
Laboratory of Energy Metabolism, Institute of Nutrition and Food Technology (INTA), University of Chile, Av El Líbano 5524, Macul, Santiago, Chile
Ricardo D. Uauy
Affiliation:
Laboratory of Energy Metabolism, Institute of Nutrition and Food Technology (INTA), University of Chile, Av El Líbano 5524, Macul, Santiago, Chile London School of Hygiene and Tropical Medicine, London, UK
Carolina A. Aguirre
Affiliation:
Laboratory of Energy Metabolism, Institute of Nutrition and Food Technology (INTA), University of Chile, Av El Líbano 5524, Macul, Santiago, Chile
Erik O. Díaz
Affiliation:
Laboratory of Energy Metabolism, Institute of Nutrition and Food Technology (INTA), University of Chile, Av El Líbano 5524, Macul, Santiago, Chile Department of Nutrition, Faculty of Medicine, University of Chile, Av El Líbano 5524, Macul, Santiago, Chile
*
*Corresponding author: Dr José Galgani, fax +562 293 1268, email jgalgani@inta.cl
Rights & Permissions [Opens in a new window]

Abstract

Recent evidence shows that specific fatty acids affect cell metabolism, modifying the balance between fatty acid oxidation and lipogenesis. These effects may have important implications in addressing the present epidemic of nutrition-related chronic disease. Intake of dietary saturated and n-6 PUFA have increased while n-3 fatty acid intake has decreased. Obesity, type 2 diabetes and insulin resistance are highly prevalent, and both are strongly related to disorders of lipid metabolism characterized by an increased plasma and intracellular fatty acid availability. Thus, it has been hypothesized that change in the quality of dietary fat supply is able to modify the degree of insulin sensitivity. Animal studies provide support for this notion. However, there is limited human data either from normal or diabetic subjects. This review aims to analyse human studies that address this question. To this purpose, the experimental design, dietary compliance, insulin-sensitivity method used and confounding variables are discussed in order to identify the role of dietary fat quality as a risk factor for insulin resistance. Most studies (twelve of fifteen) found no effect relating to fat quality on insulin sensitivity. However, multiple study design flaws limit the validity of this conclusion. In contrast, one of the better designed studies found that consumption of a high-saturated-fat diet decreased insulin sensitivity in comparison to a high-monounsaturated-fat diet. We conclude that the role of dietary fat quality on insulin sensitivity in human subjects should be further studied, using experimental designs that address the limitations of existing data sets.

Type
Review Article
Copyright
Copyright © The Authors 2008

Diet and physical activity patterns have changed drastically in both industrialized and developing countries together with a rapid increase in nutrition-related chronic diseases such as obesity, CVD and type 2 diabetes(1). Physical activity has decreased while total energy, fat and refined carbohydrate consumption have increased in virtually all age groups(1). By now most recognize that sustained changes in diet and physical activity, which promote better health, are difficult to achieve. Nutritionists have focused on dietary characteristics that could contribute to the adverse consequences of obesity, for instance fat quality that could be amenable to change, manipulating dietary ingredients or the fatty acid (FA) composition of the traditional fats consumed.

Fat ingested is a blend of different FA, no source is pure. The types of fat consumed are SFA, MUFA and PUFA. The latter are separated into two classes based on the presence of unsaturated bonds in positions n-6 or n-3. Simopoulos(Reference Simopoulos2) has described major time-related trends in total and SFA intake over the past two centuries; an increase in the total and in the SFA consumed, while the proportion of n-3:n-6 PUFA has decreased significantly. These changes have proven to be important in the risk of CVD(Reference Griel and Kris-Etherton3). Convincing evidence exists to support the notion that higher consumption of linoleic, oleic, and n-3 PUFA (α-linolenic, EPA and DHA) FA and lower intake of SFA (myristic and palmitic acids) and trans-FA reduce the risk of CVD. Differential capacity to modify plasma LDL-cholesterol, blood pressure, cardiac function, endothelial function and vascular reactivity, as well as different influence on platelet aggregation and inflammation are the cellular basis to explain the well-documented relationship between dietary fat quality and CVD(Reference Psota, Gebauer and Kris-Etherton4).

Incidence of type 2 diabetes also might be modified as a function of dietary FA quality, since several studies in animals have demonstrated a differential impairment in the degree of insulin sensitivity (IS) after feeding with SFA, n-6 PUFA or n-3 PUFA(Reference Storlien, Kraegen, Chisholm, Ford, Bruce and Pascoe5, Reference Jucker, Cline, Barucci and Shulman6). Impaired IS is a main risk factor for type 2 diabetes, hence strategies to prevent a reduction in IS may have a large impact on reducing populations affected with type 2 diabetes. In human subjects, several studies have been performed to evaluate the role of dietary FA quality on IS(Reference Vessby7Reference Riccardi, Giacco and Rivellese10) although currently more published studies report no effect of dietary fat quality on this variable. This review analyses human studies where the effects of dietary fat quality on IS have been evaluated. Special attention was given to the methodological aspects of each study. We conducted a literature search in PubMed for randomized clinical trials in human subjects published until 31 August 2007. These articles were identified with the following key words: fatty acid type and insulin. Other articles not identified after this first search were found using the Related Articles option available in Medline. Bibliographies of primary references were used to identify additional relevant studies.

Effect of fatty acid quality on insulin sensitivity

In human subjects, multiple epidemiological studies and intervention trials have assessed the role of dietary fat quality on IS. However, evidence to support a contrasting effect on IS was judged only as possible by the FAO/WHO expert group in a recent report on Diet, Nutrition and Prevention of Chronic Disease (1). Since the convincing and probable categories were required to establish a recommendation, the role of FA quality in ameliorating the risk of type 2 diabetes was not incorporated in the guidance. This section will review the descriptive and intervention human studies published to date and the multiple methodological issues that should be considered in the interpretation of the results.

Descriptive studies

In general, epidemiological studies report that dietary content of SFA is directly, and unsaturated fat is inversely, associated with the incidence of type 2 diabetes or impaired IS, respectively(Reference Hu, van Dam and Liu8, Reference Rivellese and Lilli9). For example, in a 14-year follow-up study conducted in women(Reference Salmeron, Hu, Manson, Stampfer, Colditz, Rimm and Willett11), an increase by 5 % of total energy intake as SFA or MUFA did not modify the relative risk of type 2 diabetes; however, the same relative increase as PUFA significantly reduced the relative risk to 0·63 (95 % CI 0·53, 0·76) once adjusted by relevant confounders. On the other hand, a cross-sectional study found no association between dietary FA quality with IS (by Minimal Model) after adjusting for critical confounders(Reference Mayer-Davis, Monaco, Hoen, Carmichael, Vitolins, Rewers, Haffner, Ayad, Bergman and Karter12).

Interpretation of these results is complicated further by the close correlation between dietary FA in specific foods. For example animal fat consumption increases both SFA and MUFA; even within the SFA the effect of palmitic and stearic acids may be different since the latter is rapidly converted to oleic acid(Reference Sampath and Ntambi13). Inaccurate dietary assessment methods and inadequate FA food composition provide added complexity to the analysis. This has led to the measurement of FA composition of tissues or plasma lipid fractions as potential improved markers of dietary exposure.

Folsom et al. (Reference Folsom, Ma, McGovern and Eckfeldt14) found that an increase in SFA in plasma phospholipids equivalent to the interquartile range elevated the odds for hyperinsulinaemia to 2·4-fold (95 % CI 1·7, 3·3), after adjusting for BMI and fasting glycaemia. On the other hand, Pelikánová et al. (Reference Pelikánová, Kazdova, Chvojkova and Base15) found a higher proportion of arachidonic acid in plasma phospholipids from type 2 diabetic compared to healthy subjects. In addition, in healthy individuals an inverse correlation between insulin-stimulated glucose disposal rate and serum phospholipid SFA:linoleic acid ratio was observed, which explained about one-third of the IS variance in this group.

Information of greater relevance may be obtained from skeletal muscle given its critical role in insulin-stimulated glucose uptake(Reference Baron, Brechtel, Wallace and Edelman16). Borkman et al. (Reference Borkman, Storlien, Pan, Jenkins, Chisholm and Campbell17) found in healthy subjects that the proportion of PUFA with twenty to twenty-two carbons in skeletal muscle phospholipids was directly associated to IS. On the other hand, Manco et al. (Reference Manco, Mingrone, Greco, Capristo, Gniuli, De Gaetano and Gasbarrini18) observed in muscle TAG from obese individuals, a lower degree of unsaturation in comparison to lean subjects. In addition, the combination of increased muscle TAG and palmitate content were the main determinants of impaired IS. These studies suggest that dietary fat quality may be a relevant factor in pathogenesis of insulin resistance (impaired IS) and type 2 diabetes. Results from controlled and intervention studies permit a more specific assessment of the effect of FA quality on IS.

Controlled and intervention studies

Using the previously described search criteria, we identified forty-one articles assessing the role of dietary fat quality on glucose metabolism. In general, these studies did not show a differential effect of dietary FA quality on IS; however, several methodological flaws may explain this conclusion. In order to select those studies to be included in our analysis, we evaluated the quality of experimental designs based on the approach used to evaluate IS (dependent variable), control of dietary fat quality (independent variable) and other confounding variables.

Dependent variable: insulin sensitivity

A key factor affecting data quality is the selection of the IS marker. Surrogate measurements of IS based on fasting glycaemia and insulinaemia (i.e., homeostasis model assessment) are not recommended for physiological or clinical studies since they explain no more than 40 % of the IS variance observed in a population, and < 13 % of the IS variance in normal-weight subjects(Reference Kim, Abbasi and Reaven19). Reference methods such as the euglycaemic–hyperinsulinaemic clamp(Reference DeFronzo, Tobin and Andres20), insulin suppression test(Reference Pei, Jones, Bhargava, Chen and Reaven21) and the frequently sampled intravenous glucose tolerance test with the Minimal Model(Reference Bergman22) are considered reliable approaches to determine the degree of IS. Achievement of a fully suppressed hepatic glucose production is critical for interpretation of IS data using insulin infusion methods; otherwise the degree of IS will be underestimated unless hepatic glucose production is concomitantly measured. In lean, non-diabetic individuals hepatic glucose production is fully suppressed at plasma insulin concentration of about 60 mU/ml (about 40 mU insulin/m2 per min or about 1 mU/kg body weight per min); however in type 2 diabetic subjects, the insulin dose needs to be increased at least 2-fold to observe a comparable effect(Reference Campbell, Mandarino and Gerich23, Reference Rizza, Mandarino and Gerich24).

Another relevant issue to assess dietary fat quality effect on IS relates to the reproducibility of the IS measurement and sample size required to demonstrate a significant effect. All reference methods for assessing IS have an intra-individual variation of about 15 %(Reference Pei, Jones, Bhargava, Chen and Reaven21, Reference Soop, Nygren, Brismar, Thorell and Ljungqvist25, Reference Ferrari, Alleman, Shaw, Riesen and Weidmann26), thus an average change in response to the dietary intervention equal or higher than this value (1 sd) might be considered as biologically relevant. Therefore, the sample size required to detect a difference (by at least 1 sd) between interventions is sixteen subjects, considering a type I error and power of 5 % and 80 %, respectively. Studies aiming to detect a difference between treatments lower than 1 sd will need higher sample size.

Independent variable: quality of the fat intake

Considering the potential interaction among various dietary components, studies which modify dietary fat quality as the single variable of interest are required to assess the effect of fat quality on IS. This is more feasible in short-term (1–7 d) studies; however, given that the magnitude of FA effects on IS may be dependent on duration of exposure, the need for appropriate assessment of dietary compliance is increased. This limitation is usually ignored or underestimated in most studies. In order to assure dietary compliance in free-living people the following conditions should be met: (i) maintain stable energy balance; (ii) maintain a fixed macronutrient composition of dietary energy intake; (iii) monitor the achievement of the target fat intake of a given composition. A simple strategy to evaluate energy balance is the recording of body weight. This should not fluctuate if energy intake is matched by energy expenditure. However, some studies do not even report this simple body weight information. With respect to macronutrient distribution of energy and dietary fat intake, instructions are usually given to subjects on how to incorporate the dietary changes. However, instructions are often difficult to follow and in many cases total energy and/or macronutrient intake may change since subjects tend to maintain their ad libitum diet. For example, Summers et al. (Reference Summers, Fielding and Bradshaw27) provided dietary instructions to modify SFA and PUFA intake for 5 weeks, reinforcing participants on an individual basis over the study period. Upon analysis of food consumption records and body weight changes the data were highly suggestive of a systematic underreporting of energy intake by an average of 1674 kJ/d and of total fat intake by 40 g/d.

Some studies provide key food ingredients (main fat sources) or provide scales to quantify consumption of specific foods. These attempts to control dietary compliance are insufficient. Controlled food consumption under direct supervision in an outpatient setting is the preferred method to assure compliance.

In order to objectively verify dietary compliance in terms of FA quality, changes in plasma or blood cell FA composition have been used. To interpret results from this evaluation, the following considerations should be kept in mind. First, changes in tissue FA profile can occur within a range of dietary FA intakes. Therefore, at best this is qualitative indicator of changes in dietary fat. Second, FA compositional changes in blood may not fully reflect the relevant cellular or subcellular pools. Third, the change for serum and tissue phospholipids subclasses, TAG or cholesterol esters are time dependent according to turnover rates of the specific tissue pool and the metabolism of the given FA(Reference Mantzioris, Cleland, Gibson, Neumann, Demasi and James28Reference Andersson, Nälsén, Tengblad and Vessby30). Finally, we need to consider how the changes in FA profile expressed; in most cases they are measured as percentage of total FA injected in the gas chromatographer and not per unit of tissue weight or plasma volume. Since the dietary intervention may modify the total circulating or tissue fat content this may wrongly estimate the true change.

Confounding variables

Multiple confounders may obscure a true effect of FA on IS; these require a strict control, particularly when dietary changes are subtle or in small magnitude, as is often the case in long-term studies. Full control of multiple confounders is nearly impossible but we consider that the following factors are essential for a good study. Overall health and nutritional status, age, customary dietary patterns, alcohol consumption, physical activity level, gender, use of contraceptives, menstrual status and phase of the cycle when measurements are collected are the main confounding variables. Sub-clinical conditions such prediabetic state and hyperlipidaemia should also be assessed. Actually, several studies show an association between duration and quality of sleep and metabolic indices(Reference Spiegel, Knutson, Leproult, Tasali and Van Cauter31). In addition, IS changes are highly variable between subjects in response to the same nutritional stimulus (i.e., fat overload). Emerging evidence suggests that genetic polymorphisms are able to account in part for this variability(Reference López-Miranda, Pérez-Martínez, Marin, Fuentes, Delgado and Pérez-Jiménez32). Efforts to adequately account for the confounding effects should provide stronger data where more conclusive statements can arise.

Identifying the FA effect on IS may also depend on the appropriateness of the data analysis and statistical testing for covariates. For instance, as suggested by the KANWU multicenter study(Reference Vessby, Uusitupa and Hermansen33), after splitting the group by the median energy fat percentage, significant differences in IS according to fat quality (SFA v. MUFA) were observed. The net result for the MUFA effect was that the sub-group with low-fat intake had a 20 % enhanced IS relative to a SFA diet, whereas no MUFA-induced changes in IS were observed in the high-fat intake subgroup. Unfortunately, lack of inclusion of other relevant confounders (age, gender, nutritional status, degree of IS, menopausal status, geographic location) in the statistical model limit the application of this finding.

Study selection for analysis of effect of dietary fatty acid quality on insulin sensitivity in human subjects

Based on what has been presented in the previous section we attempted to categorize and select studies according to the quality of the experimental design. The criteria considered for study selection are shown in Table 1. Two authors (J. G. and E. D.) independently applied the criteria for study selection. Additional analysis included evaluation of strength and weakness of each study. We considered as points of strength well-powered studies (at least sixteen subjects in each group or intervention period), with a crossover design and inclusion of washout period; providing evidence of good or excellent dietary compliance, body weight stability and control for menstrual cycle as appropriate. Glucose disposal rate corrected for hepatic glucose production was considered as additional strength in studies in type 2 diabetic subjects.

Table 1 Criteria for selection of studies evaluating effect of dietary fatty acid quality on insulin sensitivity in human subjects

From the total number of identified studies (n 41), fifteen matched the proposed quality criteria. These studies are summarized separately for non-diabetic subjects(Reference Andersson, Nälsén, Tengblad and Vessby30, Reference Vessby, Uusitupa and Hermansen33Reference Toft, Bonaa, Ingebretsen, Nordaoy and Jenssen40) (Table 2) and type 2 diabetic subjects(Reference Summers, Fielding and Bradshaw27, Reference Borkman, Chisholm, Furler, Storlien, Kraegen, Simons and Chesterman41Reference Mostad, Bjerve, Bjorgaas, Lydersen and Grill45) (Table 3). Those studies not selected for the analysis and reason for exclusion are shown as supplementary material. Three out of the fifteen studies reported a differential effect on IS, showing decreased IS after SFA v. MUFA(Reference Vessby, Uusitupa and Hermansen33) or PUFA(Reference Summers, Fielding and Bradshaw27) diets; whereas increased insulin resistance after fish oil supplementation was observed in type 2 diabetic individuals(Reference Mostad, Bjerve, Bjorgaas, Lydersen and Grill45). Also, we observed that according to the strength and weakness analysis (Table shown as supplementary material), the best rated study is by Vessby et al. (Reference Vessby, Uusitupa and Hermansen33). This study reported a significant decrease in IS of 10 % after consuming a SFA-enriched diet for 12 weeks, whereas no change in IS was observed with the MUFA-enriched diet. Fish oil v. olive oil supplementation were additionally compared in this study; however, no differential effect on IS was found.

Table 2 Effect of dietary fat quality intervention on insulin sensitivity in non-type 2 diabetic subjects

IS, insulin sensitivity; FSIVGTT with MinMod, frequently sampled intravascular glucose tolerance test with Minimal Model.

* IS units are different in each study and these have been not included in the table.

Table 3 Effect of dietary fat quality intervention on insulin sensitivity in type 2 diabetic subjects

IS, insulin sensitivity; HGP, hepatic glucose production.

* IS units are different in each study and these have been not included in the table.

Potential mechanisms involved in fatty acid quality-dependent insulin resistance

In human subjects, using vegetable fat (safflower or soyabean) emulsions infused intravenously(Reference Dresner, Laurent and Marcucci46Reference Roden, Price, Perseghin, Petersen, Rothman, Cline and Shulman48) or hyperenergetic, high-SFA diets it is possible to impair IS within few days or even hours(Reference Bachman, Dahl and Brechtel49, Reference Stettler, Ith, Acheson, Decombaz, Boesch, Tappy and Binnert50). In both conditions, intramyocellular lipid content is increased which is causally related to impaired IS(Reference Roden51, Reference Morino, Petersen and Shulman52), since specific lipid species (i.e., diacylglycerols or ceramides) can activate specific serine kinases(Reference Li, Soos, Li, Wu, DeGennaro, Sun, Littman, Birnbaum and Polakiewicz53Reference Özcan, Cao, Yilmaz, Lee, Iwakoshi, Özdelen, Tuncman, Görgün, Glimcher and Hotamisligil56). These kinases increase serine-phosphorylation of critical insulin signaling proteins (i.e., insulin receptor substrate 1) which reduce insulin-dependent GLUT-4 translocation and finally glucose uptake(Reference Morino, Petersen and Shulman52). Specific FA probably induce these changes at different levels of cell function. Change in FA cell membrane composition is one of the most recurrent mechanisms. FA can modify membrane function by changing overall membrane fluidity, affecting membrane thickness/volume, modifying lipid phase properties, inducing changes in the membrane microenvironment, or by interactions of specific lipid components with membrane proteins(Reference Salem, Shingu, Kim, Hullin, Bougnoux and Karanian57, Reference Slater, Kelly, Yeager, Larkin, Ho and Stubbs58). However, the limited evidence to support this idea is based on weak associations between specific membrane FA profile and the IS data derived from cross-sectional studies in subjects with different metabolic states and poorly characterized diets(Reference Borkman, Storlien, Pan, Jenkins, Chisholm and Campbell17, Reference Clore, Harris, Li, Azzam, Gill, Zuelzer, Rizzo and Blackard59Reference Vessby, Tengblad and Lithell61). On the other hand, FA may affect intracellular lipid balance based on its differential individual FA oxidation rate(Reference Leyton, Drury and Crawford62Reference Jones, Stolinski and Smith65) and ability to modify the binding of the regulatory proteins (i.e., PPAR) to DNA response elements involved in lipid metabolism(Reference Sampath and Ntambi66Reference Jump68). In animals, Pan et al. (Reference Pan and Storlien69) demonstrated differential 24 h [1-14C]α-linolenic oxidation rate and 14C muscle incorporation in rats fed for 1 month with SFA, MUFA, and n-6 PUFA diets. The highest 24 h 14CO2 recovery was found in the safflower-fed group, followed by the olive oil and lard diet; whereas skeletal muscle 14C incorporation followed the inverse order. Finally, FA may differentially affect inflammatory pathways(Reference Mayer, Meyer, Reinholz-Muhly, Maus, Merfels, Lohmeyer, Grimminger and Seeger70), which are tightly related to impaired IS. For example, toll-like receptor (TLR)-4-deficient mice (TLR-4 is important for mediating innate immune response to bacterial pathogens) have a much lower reduction of IS after infusing a lipid emulsion compared to wild-type animals(Reference Shi, Kokoeva, Inouye, Tzameli, Yin and Flier71). Interestingly, increased TLR-4-mediated cytokine generation was observed after SFA (palmitic acid), but not n-3 PUFA supplementation.

Discussion and conclusions

Human studies have failed to demonstrate a consistent differential effect of dietary fat quality on IS, which contrasts with observation from animal studies, where n-6 PUFA in comparison to n-3 PUFA decrease IS(Reference Storlien, Kraegen, Chisholm, Ford, Bruce and Pascoe5, Reference Jucker, Cline, Barucci and Shulman6). Several factors might explain this disparate finding. Perhaps the simplest explanation involves the differences in the fish oil and n-6 PUFA dose used in animals as compared to human studies. In human subjects, the maximal fish oil dose studied does not exceed 20 g/d (about 0·25 g/kg body weight per d)(Reference Mostad, Bjerve, Bjorgaas, Lydersen and Grill45) whereas studies in rats used 3·4 g(Reference Storlien, Kraegen, Chisholm, Ford, Bruce and Pascoe5) and 20 g(Reference Jucker, Cline, Barucci and Shulman6) fish oil/kg body weight per d. After correcting these doses for differences in metabolic rate, the fish oil administered to rats is between three and twenty times greater than the maximal dose used in human subjects. This is obtained after applying a scaling factor of 0·75; acceptable for comparisons among mammalian species with different body mass(Reference Banavar, Damuth, Maritan and Rinaldo72). Then, for an 80 kg human subject an approximately 4-fold lower metabolic rate than that of a 0·35 kg rat on a per kg basis is calculated; the equivalent dose of 0·25 g fish oil/kg per d in a human subject corresponds to 1 g/kg per d for the rat. When the same estimation is done for n-6 PUFA, the doses used in human subjects and rats are much closer, since large amount of n-6 PUFA are present in most Western diets.

In addition, the effect of fish oil on IS has been mainly assessed in individuals with type 2 diabetes (Table 3). Perhaps at this stage of metabolic impairment, glucose homeostasis may not be capable of an improvement even when a large dose of fish oil is provided. In non-diabetic individuals the effects of fish oil on IS has been scarcely evaluated. In a well-powered long-term study, diets enriched in SFA or MUFA were compared(Reference Vessby, Uusitupa and Hermansen33). Additionally, each diet was supplemented with fish oil or olive oil (placebo). As commented before, significant differences in IS between SFA and MUFA diets were found; however fish oil supplementation did not modify IS (see Table 2).

The potential protective effect of n-3 PUFA on IS in human subjects might require higher fish-oil doses associated with lower n-6 PUFA content. Studies in a healthy and diabetic population using diets with low absolute amounts of n-6 PUFA should be preferred in order to adequately test the potential effect of fish oil on IS. Fat sources such as linseed oil, which are rich in α-linolenic acid (>55 % of total FA) can be used to reduce amount of n-6 FA with the aim to achieve a dietary n-6 : n-3 PUFA ratio lower than 4:1 but as close to 1:1 as possible. This n-6:n-3 PUFA ratio is similar to that observed in traditional Asian diets considering the use of both marine and land sources of n-3 PUFA.

There is also a need to distinguish between fish oil and highly-unsaturated n-3 FA (EPA and DHA), since the amount of EPA and DHA commonly present in fish oil is about one third of the total FA content and the relative balance between EPA and DHA may also vary. To the best of our knowledge only one study has assessed the effect of EPA and DHA on IS separately(Reference Woodman, Mori, Burke, Puddey, Watts and Beilin73); however, the lack of a reliable marker of IS in this study does not permit an adequate conclusion.

The time to respond in terms of IS to the intervention may also be critical in explaining the lack of differential effect of fat quality on IS in human subjects. From the available data it is unclear what is the required time to increase the chances of finding a differential effect on IS relating to the FA quality. At present, well-supported effects have been demonstrated after 12 weeks of intervention(Reference Vessby, Uusitupa and Hermansen33), suggesting that changes in plasma and/or sub-cellular FA composition might be critical. On the other hand, it is well known that even after short-time periods, SFA-enriched diets (days)(Reference Bachman, Dahl and Brechtel49, Reference Stettler, Ith, Acheson, Decombaz, Boesch, Tappy and Binnert50) or vegetable fat-based lipid infusions (hours)(Reference Dresner, Laurent and Marcucci46Reference Roden, Price, Perseghin, Petersen, Rothman, Cline and Shulman48) are able to reduce insulin action in human subjects. To date, only two studies have assessed the short-term effect of FA quality on IS; however, small sample sizes(Reference Fasching, Ratheiser, Schneeweiss, Rohac, Nowotny and Waldhäusl35) or inappropriate assessment of IS(Reference Fuehrlein, Rutenberg, Silver, Warren, Theriaque, Duncan, Stacpoole and Brantly74) do not permit firm conclusions to be drawn. Thus, a well-powered, controlled short-term intervention should not be excluded as a suitable approach to assess dietary fat quality effect on IS in human subjects.

Finally, the realization that not all fats are the same is by no means new; however, we are just beginning to unravel the physiologic and possibly therapeutic effects of specific FA. These nutrients should no longer be considered solely as a source of energy but should rather be acknowledged as potent regulators of intermediary metabolism, and possible contributors to the regulation of glucose homeostasis in both type 2 diabetic and non-diabetic individuals.

Acknowledgements

The study was funded by a grant from the National Commission of Science and Technology (Conicyt), Chile (to E. D. and R. U.; Fondecyt 1040902). J. G. and C. A. were funded with doctoral fellowships from the National Commission of Science and Technology (Conicyt), Chile. None of the authors had any personal or financial conflicts of interest.

References

1 World Health Organization (2003) Diet, Nutrition and the Prevention of Chronic Diseases. Joint WHO/FAO Expert Consultation. WHO Technical Report Series no. 916. Geneva: WHO.Google Scholar
2 Simopoulos, A (2003) Importance of the ratio of omega-6/omega-3 essential fatty acids: evolutionary aspects. World Rev Nutr Diet 92, 122.CrossRefGoogle ScholarPubMed
3 Griel, AE & Kris-Etherton, PM (2006) Beyond saturated fat: the importance of the dietary fatty acid profile on cardiovascular disease. Nutr Rev 64, 257262.CrossRefGoogle ScholarPubMed
4 Psota, TL, Gebauer, SK & Kris-Etherton, P (2006) Dietary omega-3 fatty acid intake and cardiovascular risk. Am J Cardiol 98, 3i18i.CrossRefGoogle ScholarPubMed
5 Storlien, LH, Kraegen, EW, Chisholm, DJ, Ford, GL, Bruce, DG & Pascoe, WS (1987) Fish oil prevents insulin resistance induced by high-fat feeding in rats. Science 237, 885888.CrossRefGoogle ScholarPubMed
6 Jucker, B, Cline, G, Barucci, N & Shulman, G (1999) Differential effects of safflower oil versus fish oil feeding on insulin-stimulated glycogen synthesis, glycolysis, and pyruvate dehydrogenase flux in skeletal muscle. Diabetes 48, 134140.CrossRefGoogle ScholarPubMed
7 Vessby, B (2000) Dietary fat and insulin action in humans. Br J Nutr 83, Suppl. 1, S91S96.CrossRefGoogle ScholarPubMed
8 Hu, F, van Dam, R & Liu, S (2001) Diet and risk of type II diabetes: the role of types of fat and carbohydrate. Diabetologia 44, 805817.CrossRefGoogle ScholarPubMed
9 Rivellese, A & Lilli, S (2003) Quality of dietary fatty acids, insulin sensitivity and type 2 diabetes. Biomed Pharmacother 57, 8487.CrossRefGoogle ScholarPubMed
10 Riccardi, G, Giacco, R & Rivellese, A (2004) Dietary fat, insulin sensitivity and the metabolic syndrome. Clin Nutr 23, 447456.CrossRefGoogle ScholarPubMed
11 Salmeron, J, Hu, FB, Manson, JE, Stampfer, MJ, Colditz, GA, Rimm, EB & Willett, WC (2001) Dietary fat intake and risk of type 2 diabetes in women. Am J Clin Nutr 73, 10191027.CrossRefGoogle ScholarPubMed
12 Mayer-Davis, EJ, Monaco, JH, Hoen, HM, Carmichael, S, Vitolins, MZ, Rewers, MJ, Haffner, SM, Ayad, MF, Bergman, RN & Karter, AJ (1997) Dietary fat and insulin sensitivity in a triethnic population: the role of obesity. The Insulin Resistance Atherosclerosis Study (IRAS). Am J Clin Nutr 65, 7987.CrossRefGoogle Scholar
13 Sampath, H & Ntambi, JM (2005) The fate and intermediary metabolism of stearic acid. Lipids 40, 11871191.CrossRefGoogle ScholarPubMed
14 Folsom, A, Ma, J, McGovern, P & Eckfeldt, J (1996) Relation between plasma phospholipid saturated fatty acids and hyperinsulinemia. Metabolism 45(2), 223228.CrossRefGoogle ScholarPubMed
15 Pelikánová, T, Kazdova, L, Chvojkova, S & Base, J (2001) Serum phospholipid fatty acid composition and insulin action in type 2 diabetic patients. Metabolism 50, 14721478.Google ScholarPubMed
16 Baron, A, Brechtel, G, Wallace, P & Edelman, S (1988) Rates and tissue sites of non-insulin and insulin-mediated glucose uptake in humans. Am J Physiol 255, E769E774.Google ScholarPubMed
17 Borkman, M, Storlien, LH, Pan, DA, Jenkins, AB, Chisholm, DJ & Campbell, LV (1993) The relation between insulin sensitivity and the fatty acid composition of the skeletal muscle phospholipids. N Engl J Med 328, 238244.CrossRefGoogle ScholarPubMed
18 Manco, M, Mingrone, G, Greco, AV, Capristo, E, Gniuli, D, De Gaetano, A & Gasbarrini, G (2000) Insulin resistance directly correlated with increased saturated fatty acids in skeletal muscle triglycerides. Metabolism 49, 220224.CrossRefGoogle ScholarPubMed
19 Kim, S, Abbasi, F & Reaven, G (2004) Impact of degree of obesity on surrogate estimates of insulin resistance. Diabetes Care 27, 19982002.CrossRefGoogle ScholarPubMed
20 DeFronzo, R, Tobin, J & Andres, R (1979) Glucose clamp technique, a method for quantifying insulin secretion and resistance. Am J Physiol 237, 214223.Google ScholarPubMed
21 Pei, D, Jones, C, Bhargava, R, Chen, Y & Reaven, G (1994) Evaluation of octreotide to assess insulin-mediated glucose disposal by the insulin suppression test. Diabetologia 37, 843845.CrossRefGoogle ScholarPubMed
22 Bergman, R (1989) Toward physiological understanding of glucose tolerance. Minimal model approach. Diabetes 38, 15121527.CrossRefGoogle ScholarPubMed
23 Campbell, P, Mandarino, L & Gerich, J (1988) Quantification of the relative impairment in actions of insulin on hepatic glucose production and peripheral glucose uptake in non-insulin-dependent diabetes mellitus. Metabolism 37, 1521.CrossRefGoogle ScholarPubMed
24 Rizza, R, Mandarino, L & Gerich, J (1981) Dose–response characteristics for effects of insulin on production and utilization of glucose in man. Am J Physiol 240, E630E639.Google ScholarPubMed
25 Soop, M, Nygren, J, Brismar, K, Thorell, A & Ljungqvist, O (2000) The hyperinsulinaemic euglycaemic glucose clamp: reproducibility and metabolic effects of prolonged insulin infusion in healthy subjects. Clin Sci 98, 367374.CrossRefGoogle ScholarPubMed
26 Ferrari, P, Alleman, Y, Shaw, S, Riesen, W & Weidmann, P (1991) Reproducibility of insulin sensitivity measured by the minimal model method. Diabetologia 34, 527530.CrossRefGoogle ScholarPubMed
27 Summers, L, Fielding, B & Bradshaw, H (2002) Substituting dietary saturated fat with polyunsaturated fat changes abdominal fat distribution and improves insulin sensitivity. Diabetologia 45, 369377.CrossRefGoogle ScholarPubMed
28 Mantzioris, E, Cleland, L, Gibson, R, Neumann, M, Demasi, M & James, M (2000) Biochemical effects of a diet containing foods enriched with n-3 fatty acids. Am J Clin Nutr 72, 4248.CrossRefGoogle ScholarPubMed
29 Zuijdgeest-van Leeuwen, S, Dagnelie, P, Rietveld, T, van den Berg, W & Wilson, J (1999) Incorporation and washout of orally administered n-3 fatty acid ethyl esters in different plasma lipid fractions. Br J Nutr 82, 481488.CrossRefGoogle ScholarPubMed
30 Andersson, A, Nälsén, C, Tengblad, S & Vessby, B (2002) Fatty acid composition of skeletal muscle reflects dietary fat composition in humans. Am J Clin Nutr 76, 2221229.CrossRefGoogle ScholarPubMed
31 Spiegel, K, Knutson, K, Leproult, R, Tasali, E & Van Cauter, E (2005) Sleep loss: a novel risk factor for insulin resistance and Type 2 diabetes. J Appl Physiol 99, 20082019.CrossRefGoogle Scholar
32 López-Miranda, J, Pérez-Martínez, P, Marin, C, Fuentes, F, Delgado, J & Pérez-Jiménez, F (2007) Dietary fat, genes and insulin sensitivity. J Mol Med 85, 209222.CrossRefGoogle ScholarPubMed
33 Vessby, B, Uusitupa, M, Hermansen, K, et al. (2001) Substituting dietary saturated for monounsaturated fat impairs insulin sensitivity in healthy men and women: the KANWU study. Diabetologia 44, 312319.CrossRefGoogle ScholarPubMed
34 Schawb, U, Niskanen, L, Maliranta, H, Savolainen, M, Kesäniemi, A & Uusitupa, M (1995) Lauric and palmitic acid-enriched diets have minimal impact on serum lipid and lipoprotein concentrations and glucose metabolism in healthy young women. J Nutr 125, 466473.Google Scholar
35 Fasching, P, Ratheiser, K, Schneeweiss, B, Rohac, M, Nowotny, P & Waldhäusl, W (1996) No effect of short-term dietary supplementation of saturated and poly- and mono-unsaturated fatty acids on insulin secretion and sensitivity in healthy men. Ann Nutr Metab 40, 116122.CrossRefGoogle Scholar
36 Louheranta, A, Turpeinen, A, Schwab, U, Vidgren, H, Parviainen, M & Uusitupa, M (1998) A high-stearic acid diet does not impair glucose tolerance and insulin sensitivity in healthy women. Metabolism 5, 529534.CrossRefGoogle Scholar
37 Louheranta, A, Turpeinen, A, Vidgren, H, Schwab, U & Uusitupa, M (1999) A high-trans fatty acid diet and insulin sensitivity in young healthy women. Metabolism 48, 870875.CrossRefGoogle ScholarPubMed
38 Lovejoy, S, Smith, S, Champagne, C, Most, M, Lefevre, M, DeLany, J, Denkins, Y, Rood, J, Veldhuis, J & Bray, G (2002) Effects of diets enriched in saturated (palmitic), monounsaturated (oleic), or trans (elaidic) fatty acids on insulin sensitivity and substrate oxidation in healthy adults. Diabetes Care 25, 12831288.CrossRefGoogle ScholarPubMed
39 Brady, LM, Lovegrove, SS, Lesauvage, SV, Gower, BA, Minihane, AM, Williams, CM & Lovegrove, JA (2004) Increased n-6 polyunsaturated fatty acids do not attenuate the effects of long-chain n-3 polyunsaturated fatty acids on insulin sensitivity or triacylglycerol reduction in Indian Asians. Am J Clin Nutr 79, 983991.CrossRefGoogle ScholarPubMed
40 Toft, I, Bonaa, K, Ingebretsen, O, Nordaoy, A & Jenssen, T (1995) Effects of n-3 polyunsaturated fatty acids on glucose homeostasis and blood pressure in essential hypertension. Ann Intern Med 123, 911918.CrossRefGoogle ScholarPubMed
41 Borkman, M, Chisholm, DJ, Furler, SM, Storlien, LH, Kraegen, EW, Simons, LA & Chesterman, CN (1989) Effects of fish oil supplementation on glucose and lipid metabolism in NIDDM. Diabetes 38, 13141319.CrossRefGoogle ScholarPubMed
42 Luo, J, Rizkalla, S, Vidal, H, et al. (1998) Moderate intake of n-3 fatty acids for 2 months has no detrimental effect on glucose metabolism and could ameliorate the lipid profile in type 2 diabetic men. Results of a controlled study. Diabetes Care 21, 717724.CrossRefGoogle ScholarPubMed
43 Boberg, M, Pollare, T, Siegbahn, A & Vessby, B (1992) Supplementation with ϖ-3 fatty acids reduces triglycerides, but increases PAI-1 in non-insulin dependent diabetic patients. Eur J Clin Invest 22, 645650.CrossRefGoogle Scholar
44 Rivellese, AA, Maffettone, A, Iovine, C, Di-Marino, L, Annuzzi, G, Mancini, M & Riccardi, G (1996) Long-term effects of fish oil on insulin resistance and plasma lipoproteins in NIDDM patients with hypertriglyceridemia. Diabetes Care 19, 12071213.CrossRefGoogle ScholarPubMed
45 Mostad, I, Bjerve, K, Bjorgaas, M, Lydersen, S & Grill, V (2006) Effects of n-3 fatty acids in subjects with type 2 diabetes: reduction of insulin sensitivity and time-dependent alteration from carbohydrate to fat oxidation. Am J Clin Nutr 48, 540550.CrossRefGoogle Scholar
46 Dresner, A, Laurent, D, Marcucci, M, et al. (1999) Effects of free fatty acids on glucose transport and IRS-1-associated phosphatidylinositol 3-kinase activity. J Clin Invest 103, 253259.CrossRefGoogle ScholarPubMed
47 Boden, G, Lebed, B, Schatz, M, Homko, C & Lemieux, S (2001) Effects of acute changes of plasma free fatty acids on intramyocellular fat content and insulin resistance in healthy subjects. Diabetes 50, 16121617.CrossRefGoogle ScholarPubMed
48 Roden, M, Price, TB, Perseghin, G, Petersen, KF, Rothman, DL, Cline, GW & Shulman, GI (1996) Mechanism of free fatty acid-induced insulin resistance in humans. J Clin Invest 97, 28592865.CrossRefGoogle ScholarPubMed
49 Bachman, O, Dahl, D, Brechtel, K, et al. (2001) Effects of intravenoeus and dietary lipid challenge on intramyocellular lipid content and the relation with insulin sensitivity in humans. Diabetes 50, 25792584.CrossRefGoogle Scholar
50 Stettler, R, Ith, M, Acheson, KJ, Decombaz, J, Boesch, C, Tappy, L & Binnert, C (2005) Interaction between dietary lipids and physical acitivity on insulin sensitivity and on intramyocellular lipids in healthy men. Diabetes Care 28, 14041409.CrossRefGoogle Scholar
51 Roden, M (2005) Muscle triglycerides and mitochondrial function: mechanisms for the development of type 2 diabetes. Int J Obes 29, Suppl. 2, S111S115.CrossRefGoogle ScholarPubMed
52 Morino, K, Petersen, K & Shulman, G (2006) Molecular mechanisms of insulin resistance in humans and their potential links with mitochondrial dysfunction. Diabetes 55, Suppl. 2, S9S15.CrossRefGoogle ScholarPubMed
53 Li, Y, Soos, T, Li, X, Wu, J, DeGennaro, M, Sun, X, Littman, D, Birnbaum, M & Polakiewicz, R (2004) Protein kinase C (inhibits insulin signling by phosphorylating IRS1 at Ser1101. J Biol Chem 279, 4530445307.CrossRefGoogle Scholar
54 Kim, J, Fillmore, J, Sunshine, M, et al. (2004) PKC-θ knockout mice are protected from fat-induced insulin resistance. J Clin Invest 114, 823827.CrossRefGoogle Scholar
55 Yuan, M, Konstantopoulos, N, Lee, J, Hansen, L, Li, ZW, Karin, M & Shoelson, S (2001) Reversal of obesity- and diet-induced insulin resistance with salicylates or targeted disruption of Iκκβ. Nature 293, 16731677.Google ScholarPubMed
56 Özcan, U, Cao, Q, Yilmaz, E, Lee, A, Iwakoshi, N, Özdelen, E, Tuncman, G, Görgün, C, Glimcher, L & Hotamisligil, G (2004) Endoplasmic reticulum stress links obesity, insulin action, and type 2 diabetes. Science 306, 457461.CrossRefGoogle ScholarPubMed
57 Salem, N Jr, Shingu, T, Kim, HY, Hullin, F, Bougnoux, P & Karanian, JW (1998) Specialization in membrane structure and metabolism with respect to polyunsaturated lipids. Prog Clin Biol Res 282, 319333.Google Scholar
58 Slater, SJ, Kelly, MB, Yeager, MD, Larkin, J, Ho, C & Stubbs, CD (1996) Polyunsaturation in cell membranes and lipid bilayers and its effects on membrane proteins. Lipids 31, Suppl., S189S192.CrossRefGoogle ScholarPubMed
59 Clore, JN, Harris, PA, Li, J, Azzam, A, Gill, R, Zuelzer, W, Rizzo, WB & Blackard, WG (2000) Changes in phosphatidylcholine fatty acid composition are associated with altered skeletal muscle insulin responsiveness in normal man. Metabolism 49, 232238.CrossRefGoogle ScholarPubMed
60 Pan, DA, Lillioja, S, Milner, MR, Kriketos, AD, Baur, LA, Bogardus, C & Storlien, LH (1995) Skeletal muscle membrane lipid composition is related to adiposity and insulin action. J Clin Invest 96, 28022808.CrossRefGoogle ScholarPubMed
61 Vessby, B, Tengblad, S & Lithell, H (1994) Insulin sensitivity is related to the fatty acid composition of serum lipids and skeletal muscle phospholipids in 70-year-old men. Diabetologia 37, 10441050.CrossRefGoogle Scholar
62 Leyton, J, Drury, P & Crawford, M (1987) Differential oxidation of saturated and unsaturated fatty acids in vivo in the rat. Br J Nutr 57, 383393.CrossRefGoogle ScholarPubMed
63 DeLany, JP, Windhauser, MM, Champagne, CM & Bray, GA (2000) Differential oxidation of individual dietary fatty acids in humans. Am J Clin Nutr 72, 905911.CrossRefGoogle ScholarPubMed
64 McCloy, U, Ryan, M, Pencharz, P, Ross, R & Cunnane, S (2004) A comparison of the metabolism of eighteen-carbon 13C-unsaturated fatty acids in healthy women. J Lip Res 45, 474485.CrossRefGoogle Scholar
65 Jones, A, Stolinski, M & Smith, R (1999) Effect of fatty acid chain length and saturation on the gastrointestinal handling and metabolic disposal of dietary fatty acids in women. Br J Nutr 81, 3743.CrossRefGoogle ScholarPubMed
66 Sampath, H & Ntambi, J (2005) Polyunsaturated fatty acid regulation of genes of lipid metabolism. Ann Rev Nutr 25, 317340.CrossRefGoogle ScholarPubMed
67 Duplus, E & Forest, C (2002) Is there a single mechanism for fatty acid regulation of gene expression? Biochem Pharm 64, 893901.CrossRefGoogle Scholar
68 Jump, D (2002) The biochemistry of n-3 polyunsaturated fatty acids. J Biol Chem 277, 87558758.CrossRefGoogle ScholarPubMed
69 Pan, D & Storlien, L (1993) Dietary lipid profile is a determinant of tissue phospholipid fatty acid composition and rate of weight gain in rats. J Nutr 123, 512519.CrossRefGoogle ScholarPubMed
70 Mayer, K, Meyer, S, Reinholz-Muhly, M, Maus, U, Merfels, M, Lohmeyer, J, Grimminger, F & Seeger, W (2003) Short-time infusion of fish oil-based lipid emulsions, approved for parenteral nutrition, reduces monocyte proinflammatory cytokine generation and adhesive interaction with endothelium in humans. J Immunol 171, 48374843.CrossRefGoogle ScholarPubMed
71 Shi, H, Kokoeva, M, Inouye, K, Tzameli, I, Yin, H & Flier, J (2006) TLR4 links innate immunity and fatty acid-induced insulin resistance. J Clin Invest 116, 30153025.CrossRefGoogle ScholarPubMed
72 Banavar, J, Damuth, J, Maritan, A & Rinaldo, A (2002) Supply–demand balance and metabolic scaling. PNAS 99, 1050610509.CrossRefGoogle ScholarPubMed
73 Woodman, RJ, Mori, TA, Burke, V, Puddey, IB, Watts, GF & Beilin, LJ (2002) Effects of purified eicosapentaenoic and docosahexaenoic acids on glycemic control, blood pressure, and serum lipids in type 2 diabetic patients with treated hypertension. Am J Clin Nutr 76, 10071015.CrossRefGoogle ScholarPubMed
74 Fuehrlein, BS, Rutenberg, MS, Silver, JN, Warren, MW, Theriaque, DW, Duncan, GE, Stacpoole, PW & Brantly, ML (2004) Differential metabolic effects of saturated versus polyunsaturated fats in ketogenic diets. J Clin Endocrinol Metab 89, 16411645.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Criteria for selection of studies evaluating effect of dietary fatty acid quality on insulin sensitivity in human subjects

Figure 1

Table 2 Effect of dietary fat quality intervention on insulin sensitivity in non-type 2 diabetic subjects

Figure 2

Table 3 Effect of dietary fat quality intervention on insulin sensitivity in type 2 diabetic subjects

Supplementary material: File

Galgani supplementary material

Galgani supplementary material

Download Galgani supplementary material(File)
File 101.9 KB