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Evaluating the roles of food matrix, lipid micronutrients and bioactives in controlling postprandial hypertriglyceridaemia and inflammation

Published online by Cambridge University Press:  07 November 2024

Ángela Bravo-Núñez
Affiliation:
Aix-Marseille University, INRAE, INSERM, C2VN, Marseille, France University of Valladolid, Valladolid, Spain
René Valéro
Affiliation:
Aix-Marseille University, INRAE, INSERM, C2VN, Marseille, France APHM, Department of Nutrition, Metabolic Diseases and Endocrinology, University Hospital La Conception, Marseille, France
Emmanuelle Reboul*
Affiliation:
Aix-Marseille University, INRAE, INSERM, C2VN, Marseille, France
*
*Corresponding author: Emmanuelle Reboul, email: [email protected]
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Abstract

Lipids play an important role in human nutrition. Although adequate lipid consumption is necessary for an optimal functioning of the human body, overconsumption of saturated fatty acids can lead to postprandial hypertriglyceridaemia, which triggers the development of atherosclerosis. Important parameters that impact postprandial lipaemia and inflammation are related to the matrix structure and the fat-soluble micronutrient profile of ingested foods/lipids, but the specific effect of these parameters should be further studied, as most of the available studies evaluate their effect at fasting state. This review specifically explores the effects of food structure and fat-soluble micronutrients, from either micronutrient-rich foods or supplements, on postprandial hypertriglyceridaemia and inflammation. The review also highlights the potential of emerging biomarkers such as miRNAs or circulating microvesicles, as an alternative to the widely use biomarkers (e.g. low-density lipoproteins or blood concentration of pro-inflammatory cytokines), to identify inflammation associated with postprandial hypertriglyceridaemia at early stages.

Type
Review Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of The Nutrition Society

Introduction

Lipids play an important role in human nutrition. They not only represent a high percentage of our caloric intake but are also a source of essential fatty acids and carriers of fat-soluble micronutrients (FSM) such as liposoluble vitamins and carotenoids. Although adequate lipid consumption is necessary for an optimal functioning of the human body, an overconsumption of saturated fatty acids can lead to postprandial hypertriglyceridaemia (overaccumulation of triacylglycerol-rich lipoproteins (TRL) in blood), which triggers the development of atherosclerosis. Indeed, a high TRL level in blood is the major pattern of lipid abnormality in many patients who are treated for atherosclerotic cardiovascular disease(Reference Libby1,Reference Nordestgaard2) . Postprandial hypertriglyceridaemia has been associated with increases in different biomarkers of metabolic health associated with atherosclerotic cardiovascular disease, such as oxidation rate of low-density lipoproteins (LDL)(Reference Borén, John Chapman and Krauss3Reference Matsuura, Hughes and Khamashta5) or blood concentration of pro-inflammatory cytokines(Reference Burdge and Calder6), two groups of biomarkers widely used by the research community. However, emerging biomarkers such as microRNAs (miRNA)(Reference Lopez, Bermudez and Montserrat-de la Paz7), circulating microvesicles(Reference Araujo, Silva and Guerra8) or changes in gene expression in blood cells associated with miRNA expression(Reference Lopez, Bermudez and Montserrat-de la Paz7,Reference Quintanilha, Pinto Ferreira and Ferreira9) have shown promising results.

The food matrices in which lipids are embedded are very diverse and are responsible for the modulation of fatty acid release during digestion, bioavailability and metabolic fate once absorbed(Reference Michalski, Genot and Gayet10). However, very little information is available regarding the specific effect of food structure on postprandial lipaemia. The available studies focused mainly on emulsion-based dairy products and have highlighted the impact of lipid emulsion structure on lipid absorption rate and lipid postprandial response(Reference Dias, Zhu and Thompson11,Reference Tan, Sun and Goh12) . Food compounds can also modulate postprandial lipaemia. Hydrosoluble micronutrients such as niacin (vitamin B3), minerals (zinc, copper, magnesium, calcium) and phytochemicals such as polyphenols have a positive effect on postprandial lipaemia, as previously reviewed by our research group(Reference Desmarchelier, Borel and Lairon13). Other reviews have also highlighted the effect of macro- and micronutrients on postprandial lipaemia(Reference Botelho Dias, Moughan and Wood14Reference Lairon and Defoort16), but none of them addressed the effect of fat-soluble vitamins and carotenoids. This may be related to the fact that fat-soluble vitamin- and carotenoid-specific effects on postprandial hypertriglyceridaemia and associated inflammation are still not well understood. The link between nutritional supplementation and fasting hypertriglyceridaemia has been reviewed elsewhere(Reference Schiano, Annunziata and Ciampaglia17), but, to date, no review linking FSM supplementation and postprandial hypertriglyceridaemia is available.

This review aims to cover this gap and brings up to date the state of the art regarding the effects of: (i) food structure and (ii) FSM, from either micronutrient-rich foods or supplements, on postprandial hypertriglyceridaemia. We will also discuss the potential of emerging biomarkers (miRNAs, circulating microvesicles) to determine the inflammatory state associated with postprandial hypertriglyceridaemia.

Postprandial hypertriglyceridaemia and inflammation: where are we now?

Cardiovascular diseases (CVD) are the dominant cause of death in the world(18). Residual cardiovascular risk, which is defined as the risk of cardiovascular events that persists despite achievement of treatment goals for low-density lipoprotein-cholesterol (LDL-C), blood pressure and glycaemia is largely associated with atherogenic dyslipidaemia (AD). AD is mainly characterised by fasting and postprandial hypertriglyceridaemia (postprandial hyperlipidaemia), low high-density lipoprotein-cholesterol (HDL-C) and increase of small and dense LDL. AD is often present in individuals at high cardiovascular risk such as persons with overweight or obesity, individuals suffering from type 2 diabetes and subjects suffering from metabolic syndrome who frequently share the same insulin-resistant state(Reference Aguiar, Alegria and Bonadonna19,Reference Ferrari, Aguiar and Alegria20) . The pathophysiology of AD is widely explained by the blood accumulation of TRL synthesised by the liver (very low-density lipoproteins, VLDL) and the intestine (chylomicrons). This accumulation has been attributed to the overproduction of both VLDL(Reference Adiels, Olofsson and Taskinen21) and chylomicrons(Reference Duez, Lamarche and Uffelman22) and a defective TRL removal process because of several associated mechanisms: reduction of lipoprotein lipase activity, changes in the apolipoprotein composition of TRL impairing particle clearance, and defect in the hepatic uptake of TRL and their remnants(Reference Vergès23). Elevated fasting and postprandial blood TRL concentrations, which are mainly related to the increase in chylomicron and VLDL production, are now considered a causal risk factor for low-grade inflammation, atherosclerotic CVD and all-cause mortality. Indeed, there are extensive epidemiological, genetic and biological data showing that the increase of TRL reflected by the fasting and postprandial blood triacylglycerol (TG) level and/or the measurement of remnant cholesterol (remnant cholesterol = total cholesterol − LDL-C − HDL-C) is a causal risk factor for atherosclerosis through direct and indirect mechanisms(Reference Nordestgaard24). TRL and its remnants can promote atherosclerosis via modulating inflammation, oxidative stress and formation of foam cells(Reference Zhang, Yin and Qiao25). In a multi-directional Mendelian randomisation human study, it has been shown that elevated non-fasting remnant cholesterol was causally associated with low-grade inflammation. Indeed, a 1-mmol/L-higher level of non-fasting remnant cholesterol was associated observationally with a 37% higher C-reactive protein (CRP) level and causally with a 28% higher level of ischaemic heart disease(Reference Varbo, Benn and Tybjærg-Hansen26). The potential inflammatory mechanisms for atherogenesis in hypertriglyceridaemia have been described in a recent review(Reference Peng and Wu27). In summary, circulating monocytes can take up TRL and their remnants and possibly non-esterified fatty acids (NEFA) to become foamy monocytes with an inflammatory phenotype (high level expression of tumour necrosis factor alpha (TNFα), interleukin-1β (IL-1β) and type I transmembrane protein CD11c). Foamy monocytes adhere firmly to vascular cell adhesion molecule 1(VCAM-1)/intercellular adhesion molecule 1(ICAM-1) expressed on activated endothelial cells and infiltrate into plaques, where foamy monocytes differentiate into foam macrophages, thereby contributing to atherosclerosis. Foamy monocytes can also possibly infiltrate other tissues and may therefore play a pivotal role in the development of inflammation in other tissues. TRL remnants and NEFA can also enter arterial walls directly, be engulfed by lesional macrophages and increase macrophage lipid accumulation, promoting foam macrophage formation and contributing to atherogenesis. Macrophages including foam macrophages secrete cytokines, which, along with those derived from foamy monocytes, can further increase inflammation in macrophages and other cells in plaques and promote atherosclerosis progression. TRL, their remnants and NEFA can interact with endothelial cells and induce endothelial cell inflammation and activation, with up-regulation of cytokines and adhesion molecules such as ICAM-1 and VCAM-1, which mediate monocyte adhesion and recruitment into atherosclerotic plaques. Finally, TRL remnants and NEFA also impair the balance of nitric oxide and reactive oxygen species (ROS) in endothelial cells, leading to endothelial dysfunction.

Given the damaging consequences of postprandial hyperlipaemia, mitigating nutritional strategies should be implemented in patients in addition to their usual medical treatment.

Effect of food structure and composition on postprandial hypertriglyceridaemia and/or inflammation

Postprandial hypertriglyceridaemia can be modulated by many factors, such as structure and composition of the meal/food consumed, lifestyle factors or biological factors(Reference Botelho Dias, Moughan and Wood14). The effect of food matrix on postprandial hypertriglyceridaemia, which can be defined as the nutrient and non-nutrient components of foods and their molecular relationships, is still not very well characterised(Reference Desmarchelier, Borel and Lairon13,Reference Acevedo-Fani and Singh28) . More particularly, food structure, that is, the organisation of food constituents, can be innate or built during food manufacturing. Food matrix/structure can impact food destructuring during digestion and, therefore, the release and transformation of macro- and micronutrients(Reference Shahidi and Pan29,Reference Golding and Wooster30) , which affects their in vivo absorption(Reference Margier, Antoine and Siriaco31). This part of the review thus summarises the latest insights on the relationships between food structure built during food manufacturing and postprandial hypertriglyceridaemia.

Effect of food structure with a focus on fat distribution

The first study that assessed the impact of food structure on postprandial hypertriglyceridaemia was that of Drouin-Chartier et al. (Reference Drouin-Chartier, Tremblay and Maltais-Giguère32). The authors showed that dairy fat from a soft cream cheese induced a higher TG response in the early postprandial phase compared with butter or with firm cheddar cheese. However, the measured absolute TG response for the intervention period (6 h) was similar for all products. Although the authors did not measure fat droplet size in their products, they suggested that TG could increase faster with the soft cream owing to the smaller fat droplet size of this product compared with butter or cheddar. However, this may not be the only reason, as discussed later. Hansson et al. (Reference Hansson, Holven and Øyri33) then reported different TG responses of four different dairy meals (butter, cheese, whipped cream and sour cream) containing the same fat content. The authors reported that the intake of sour cream induced a significantly higher serum TG response than all the other dairy meals. Like Drouin-Chartier et al.,(Reference Drouin-Chartier, Tremblay and Maltais-Giguère32), the authors attributed these differences to fat droplet sizes without reporting the related values. A limiting factor in this second study was that the different products were given with toast, which probably influenced the TG postprandial response. In both studies, the results could partially be influenced by food consistency (liquid, semi-liquid or solid), as it seems that liquid foods trigger higher TG response of foods with similar composition(Reference Dias, Zhu and Thompson11). Food structure, which also encompasses food consistency, affects gastric emptying(Reference Goyal, Guo and Mashimo34) and kinetics of lipid digestion, as proven by several in vitro studies(Reference Mulet-Cabero, Rigby and Brodkorb35,Reference Salt, Mandalari and Parker36) . However, these in vitro data sometimes conflict with the conclusion of in vivo studies. For example, Mulet-Cabero et al. (Reference Mulet-Cabero, Rigby and Brodkorb35) suggested that lipid digestion occurs faster for semi-solid foods than for liquid foods, because of a predicted faster gastric emptying of lipids. These data disagree with the in vivo TG responses to solid and liquid dairy matrices reported by Drouin-Chartier(Reference Drouin-Chartier, Tremblay and Maltais-Giguère32), Hansson et al. (Reference Hansson, Holven and Øyri33) and Diaz et al. (Reference Dias, Zhu and Thompson11). The comparison and validation of gastric behaviour of such in vitro and in vivo studies is difficult because the in vivo studies scarcely address the structural changes of food in the stomach and the composition of each gastric emptying. However, Kjølbæk et al. (Reference Kjølbæk, Schmidt and Rouy37) showed a higher TG response for a gel-based casein product than for a casein drink, supporting the hypothesis of Mulet-Cabero(Reference Mulet-Cabero, Rigby and Brodkorb35). Kjølbæk et al. (Reference Kjølbæk, Schmidt and Rouy37) suggested that these results could be due to the structure of each product, as the only difference between the two products was that the gel-based product was the result of the acid gelation of the drink. Differences in TG response could also be linked to the fact that casein loses its micellar structure at acid pH, which could affect the lipid digestion rate. However, in the same study, Kjølbæk et al. (Reference Kjølbæk, Schmidt and Rouy37) reported a similar TG response of two cheddar cheeses with the same nutritional profile but different structures (one solid, one semi-solid), in disagreement with the hypothesis of Mulet-Cabero(Reference Mulet-Cabero, Rigby and Brodkorb35). It seems that not only macrostructure of foods but also the fine structure of ingredients can affect the postprandial triglyceridaemia response via different digestion rates of lipids. This was illustrated recently in a study that showed a strong influence of the amylose content of starches on lipid digestion of starch-based gels: the higher the amylose content, the higher the lipid digestion per gram of oil(Reference Qazi, Ye and Acevedo-Fani38). Other in vitro studies have suggested that food processing can also affect lipid digestion(Reference Lopez, Cauty and Guyomarc’h39Reference Qazi, Ye and Acevedo-Fani41) via structural modification of macro- and micronutrients and, therefore, potential TG response, although validation with in vivo models is needed before health/nutrition-related conclusions can be made, as results may differ(Reference Berton-Carabin and Schroën42). More recently, Gleize et al. (Reference Gleize, Hiolle and Meunier43) conducted a study on twelve healthy subjects who received four starchy foods with similar compositions but different structures (custard, pudding, sponge cake and biscuit)(Reference Gleize, Hiolle and Meunier43). Results showed that custard TG response was significantly higher than pudding and biscuit TG responses. This could be linked to the lipid droplet size/structure of the products: biscuits displayed big fat “flakes” (18 000 μm) while custard was composed of very small droplets (30 μm)(Reference Gleize, Hiolle and Meunier43). Overall, the available studies suggest that solid food structure limits the TG response, perhaps because solid food structure may modify the accessibility of the lipid droplets to enzymes. Results of Salt et al. (Reference Salt, Mandalari and Parker36), who addressed both in vitro lipid digestion of muffins and free oil, support this conclusion. Gleize et al. (Reference Gleize, Hiolle and Meunier43) also showed that, despite TG postprandial concentrations being different for the four tested products, plasma TG peaked at 3 h for all products. This suggests that, although the food matrix could impact the accessibility of lipids to enzymes, it neither delayed fatty acid absorption by enterocytes nor their secretion into chylomicrons.

As mentioned above, it is widely accepted that the TG postprandial response is influenced not only by the type/amount of fat but also by droplet size distribution(Reference Acevedo-Fani and Singh28), which is known to change during the digestion process(Reference Armand, Borel and Pasquier44) and impact lipid digestion, as reviewed elsewhere(Reference Golding and Wooster30,Reference Singh, Ye and Horne45) . However, information regarding the specific effect of droplet size on postprandial hypertriglyceridaemia is still scarce. Vors et al. (Reference Vors, Pineau and Gabert46) evaluated the effect of droplet size of milk and reported higher postprandial chylomicrons, apolipoprotein B-48 and TG concentrations with smaller droplet sizes. However, emulsions were administered together with other food matrices, entangling the extrapolation of the results to droplet size effect only. Similar observations with the same limitations were reported by Tan et al. (Reference Tan, Sun and Goh12), Laugerette et al. (Reference Laugerette, Vors and Géloën47) and Garaiova et al. (Reference Garaiova, Guschina and Plummer48). In a recent study, Howard et al. (Reference Howard, Attenbourgh and O’Mahoney49) tried to overcome this gap by evaluating the effect of two standardised emulsified high-fat meals only differing in fat droplet size on postprandial hypertriglyceridaemia. No other food was given together with the emulsions. They reported a droplet-size-dependent increase of TG concentrations over time, with the increase being more important with fine emulsions than with coarse emulsions. This was in agreement with the observations of the above-mentioned studies that administered emulsions with other foods(Reference Tan, Sun and Goh12,Reference Drouin-Chartier, Tremblay and Maltais-Giguère32,Reference Vors, Pineau and Gabert46Reference Garaiova, Guschina and Plummer48) . Howard et al. (Reference Howard, Attenbourgh and O’Mahoney49) showed that a high-fat meal with a smaller lipid droplet size induces a sustained pro-vascular inflammatory and pro-thrombotic milieu, whereas a large lipid droplet size attenuates the rise in vascular inflammatory and thrombotic parameters similarly to a meal with negligible fat content. As this is the first human study evaluating the isolated effect of fat droplet size on vascular inflammation, the results should be considered carefully. Another study showed that emulsion droplet size affected gastrointestinal hormone release and that evenly dispersed, stable, small-emulsion droplets within the stomach lead to prolonged gastric distension and accelerated fat sensing. This prolonged feelings of satiation, which can be seen as something beneficial(Reference Steingoetter, Buetikofer and Curcic50).

There may be situations where having a small lipid droplet size to provide a fast delivery of lipids/FSM to the body may be beneficial to health, in case of specific supplementations for subgroups of the population such as elderly. Based on the protective effect of FSM, and considering that emulsions with small droplet sizes enhance FSM bioaccessibility/bioavailability(Reference Gleize, Hiolle and Meunier43,Reference Tan and McClements51) , FSM may help to tackle the potential negative effect of fine emulsions on postprandial hypertriglyceridaemia (see below).

Effects of emulsifiers

Polysorbates and carboxymethylcelluloses, two emulsifiers commonly used by the food industry and research community, were shown to have a detrimental effect on health(Reference Bancil, Sandall and Rossi52Reference Viennois and Chassaing54), although their effect on postprandial hypertriglyceridaemia has not yet been deeply considered. In an in vivo study in rats, Nassara et al. (Reference Nassra, Bourgeois and Subirade55) compared the effect of water-in-oil emulsions on postprandial hypertriglyceridaemia. The different emulsions presented similar droplet sizes (9–10 µm) but were stabilised either with synthetic emulsifiers (polyoxyethylene sorbitan monooleate, also known as Tween80, or sodium stearoyl-2-lactylate) or protein-based emulsifiers (sodium caseinate or β-lactoglobulin). The authors concluded that the use of proteins to emulsify lipids has the potential to decrease lipid postprandial response compared with synthetic emulsifiers. The effect of casein and whey proteins – two protein-based emulsifiers – on postprandial hypertriglyceridaemia has also been evaluated by Mariotti et al. (Reference Mariotti, Valette and Lopez56). The authors concluded that the type of milk protein did not affect postprandial plasma glucose, amino acids, insulin or NEFA, but reported that caseins markedly reduced postprandial TG and plasma chylomicrons. No significant differences between the meals regarding postprandial oxidative stress, endothelial function or low-grade inflammation were found. In a different study, Keogh et al. (Reference Keogh, Wooster and Golding57) evaluated the effect of emulsions stabilised with egg lecithin, sodium sterol lactylate, sodium caseinate/monoglyceride and Tween80 on postprandial hypertriglyceridaemia. The interpretation of their results is difficult, as the authors did not report emulsion droplet size and, therefore, it is unclear if reported differences between emulsions are related to droplet size or to the used emulsifier. Authors reported in vitro fatty acid release rate, and emulsions with the highest digestibility rate were not always the emulsions with the greatest impact on TG postprandial concentrations(Reference Keogh, Wooster and Golding57). This suggests that both droplet size and emulsifiers are important parameters to take into consideration when evaluating the impact of food emulsions on postprandial hypertriglyceridaemia.

Effects of FSM on postprandial hypertriglyceridaemia and/or inflammation

The specific effects of each FSM on postprandial hypertriglyceridaemia are challenging to address, as FSM are generally not consumed individually. Moreover, the use of individual FSM is somehow controversial and not common in research, because it ignores the potential interactions between nutrients within the food matrix. This matrix effect is widely acknowledged for FSM bioavailability, something out of the scope of this review but reviewed elsewhere (e.g. Chungchunlam and Moughan(Reference Chungchunlam and Moughan58) and Dima et al. (Reference Dima, Assadpour and Dima59)). In this section, we cover the effects that different FSM can have on postprandial hypertriglyceridaemia and inflammation when ingested in food matrices or supplements, acknowledging that the food matrix itself and its effect on lipid digestion can affect postprandial hypertriglyceridaemia. The available literature is focused on foods rich in FSM from plant-based sources. In the future, the research community should also address the impact of foods rich in FSM from animal sources on postprandial hypertriglyceridaemia.

Effects of FSM-rich foods

A meta-analysis encompassing the effect of a wide range of foods/food components (sugars, fibre-rich foods, alcohol, fats, proteins, alcohol and more), some of them containing FSM, on postprandial TG response can be found in the literature(Reference Lee, Low and Chen60), although the specific effect of FSM was not assessed. Some studies indicate a relationship between FSM and TG postprandial response. Available information is summarised in Table 1. For instance, Gomez-Marin et al. (Reference Gomez-Marin, Gomez-Delgado and Lopez-Moreno65) showed that long-term consumption of a Mediterranean diet, known to be rich in FSM, improves to a greater extent the postprandial TG levels in individuals with type 2 diabetes than just following a low-fat diet. Here, we addressed the linkage between FSM-rich foods, notably tomato meals(Reference Arranz, Martínez-Huélamo and Vallverdu-Queralt66,Reference Burton-Freeman, Talbot and Park67) , legumes(Reference Bourdon, Olson and Backus68Reference Tan, Siow and Peh72), nuts(Reference Berry, Tydeman and Lewis73Reference Salas-Salvadó, Guasch-Ferré and Bulló79), orange juice(Reference Berryman, Grieger and West74,Reference Cerletti, Gianfagna and Tamburrelli80Reference Sahar, Ur Rahman and Ishaq83) or certain diets(Reference Gomez-Marin, Gomez-Delgado and Lopez-Moreno65,Reference Muñoz-Perez, Gonzalez-Correa and Astudillo-Muñoz84) (Table 2) and postprandial hypertriglyceridaemia.

Table 1. Summary of relevant studies regarding the effect of fat-soluble micronutrients from supplements on postprandial hypertriglyceridaemia and/or inflammation

Effects of tomato products

Tomatoes are particularly rich in carotenoids (mainly lycopene, but also β-carotene and lutein) and contain a significant amount of vitamin E(Reference Abushita, Hebshi and Daood85,Reference García-Closas, Berenguer and Tormo86) .

A study by Burton-Freeman et al. (Reference Burton-Freeman, Talbot and Park67) reported that a high-fat meal containing tomato paste significantly attenuated LDL oxidation and interleukin 6 (IL-6), showing a decrease in inflammation, although total postprandial TG concentrations were increased compared with a high-fat meal with equivalent calories and macronutrient content. Arranz et al. (Reference Arranz, Martínez-Huélamo and Vallverdu-Queralt66), who assessed the effect of tomato juice on postprandial hypertriglyceridaemia, reported a beneficial effect of tomato on postprandial hypertriglyceridaemia. These authors showed that consumption of tomato juice together with olive oil increased the carotenoid levels in blood (mainly β-carotene and lycopene) and reduced the concentration of commonly used postprandial hypertriglyceridaemia biomarkers, such as TG, total cholesterol and LDL- or HDL-cholesterol concentrations. In fact, two meta-analyses(Reference Cheng, Koutsidis and Lodge87,Reference Wang, Li and Zhao88) have reported that tomato supplementation has significant beneficial effects on IL-6, blood lipids, blood pressure, endothelial function and short-term changes in CRP levels, although it is not clear when the authors of these two meta-analyses refer to values at fasting or postprandial state.

Effects of legumes

The results of Nilsson et al. (Reference Nilsson, Johansson and Ekström69) suggested that consumption of 101 g (weight before cooking) of legumes (beans) as a starter for dinner can regulate the inflammation response of the first meal during the following day in comparison with the consumption of 89 g of white bread. Indeed, they reported a significant decrease in IL-6 and interleukin 18 (IL-18), as well as in blood glucose and insulin at postprandial state (between 30 and 180 or 30 and 120 min for glucose and insulin, respectively). Although the FSM content of the legumes used in this study was not addressed, it is known that beans do contain FSM (e.g. α-, β- and γ-tocopherols: 4–17 mg/100 g(Reference Campos-Vega, Loarca-Piña and Oomah89,Reference Ryan, Galvin and O’Connor90) ). We hypothesise that not only fibre but also FSM could play a role in regulating this inflammation response. Other studies did not report a significant decrease in commonly used biomarkers, such as interleukins or TG(Reference Bourdon, Olson and Backus68,Reference Reverri, Randolph and Steinberg71,Reference Tan, Siow and Peh72) , or reported a decrease only for certain bean varieties(Reference Olmedilla-Alonso, Pedrosa and Cuadrado70). However, studies with a lack of decrease in hypertriglyceridaemia biomarkers did show a protective effect against postprandial metabolic stress (decrease of postprandial insulin/enhanced cholecystokinin response associated with reductions of plasma glucose and insulin concentrations in diabetic patients) (see Table 2 for detailed information)(Reference Bourdon, Olson and Backus68,Reference Olmedilla-Alonso, Pedrosa and Cuadrado70Reference Tan, Siow and Peh72) . As previously stated, legume effects can largely be attributed to their high content in fibre, and the beneficial effect of FSM from legumes is a hypothesis that should be validated. However, Reverri et al. (Reference Reverri, Randolph and Steinberg71) showed that, compared with fibre-matched or micronutrient-matched meals, the bean meals were more efficient in modulating insulin response, likely highlighting a synergic effect between fibre and micronutrients, supporting our hypothesis.

Table 2. Summary of relevant studies regarding the effect of foods containing fat-soluble micronutrients on postprandial hypertriglyceridaemia and/or inflammation

* Although FSM content was not reported, legumes are known to contain vitamin E (α-, β- and γ-tocopherols: 4–17 mg/100 g dry weight(Reference Campos-Vega, Loarca-Piña and Oomah89,Reference Ryan, Galvin and O’Connor90) ).

Although FSM content was not reported, walnuts are known to contain vitamin E and carotenoids (vitamin E: 43 mg/100 g dry weight, carotene: 0.03 mg/100 g dry weight(Reference Ni, Zhang and Chen117)).

Although FSM content was not reported, almonds are known to contain vitamin E (mainly α-tocopherol: 20–80 mg/100 g dry weight(Reference Barreca, Nabavi and Sureda92,Reference Yada, Lapsley and Huang93) ). All values are for orientation.

It is important to note that observations of these studies cannot be attributed only to the effect of fat-soluble micronutrients, as these foods/meals contain other compounds with a potential beneficial effect on the measured biomarkers (e.g. fibre).

Effects of nuts

Beneficial effects of walnuts at postprandial state have been reported by several authors(Reference Berryman, Grieger and West74,Reference Cortés, Núñez and Cofán75,Reference Haddad, Gaban-Chong and Oda77,Reference Ros, Núñez and Pérez-Heras78) . This may be partly due to the presence of vitamin E in nuts. Ros et al. (Reference Ros, Núñez and Pérez-Heras78) reported that replacing monounsaturated fat with walnuts in a Mediterranean diet improves endothelium-dependent vasodilation in subjects with hypercholesterolaemia. In agreement with these results, Cortés et al. (Reference Cortés, Núñez and Cofán75) showed that walnuts reversed the impairment of endothelial function associated with the consumption of a high-fat meal. In a later study, Berryman et al. (Reference Berryman, Grieger and West74) evaluated the isolated effect of walnuts and walnuts components (meat, skin and oil) on postprandial lipaemia. They observed lower postprandial triglyceridaemia for walnut meat and skin than for whole walnut or oil. Since authors did not use a control (e.g. control oil), they could only conclude that certain parts of walnuts have a positive effect on postprandial lipaemia, but when comparing the results of Berryman et al. (Reference Berryman, Grieger and West74) with those of other studies, it seems that, if they had included a control, they would have also observed an improvement with whole walnut and walnut oil. Haddad et al. (Reference Haddad, Gaban-Chong and Oda77) reported a reduction of oxidised LDL at the postprandial state when comparing a walnut meal against a control meal that contained refined oil.

Beneficial effects of other nuts on postprandial hypertriglyceridaemia have also been reported. For example, Berry et al. (Reference Berry, Tydeman and Lewis73) reported that the postprandial increase in plasma TG was significantly lower after a meal containing whole almond particles than after a meal containing defatted almond flour + almond oil or sunflower oil. The authors linked their observations to the different bioaccessibility of lipids in their almond samples (regulated by the structure and its digestion). In an in vitro study, the effect of almond structure on lipid digestion has been demonstrated: authors showed a higher lipid release for smaller particles than for larger particles of almonds, due to the greater proportion of disrupted cells(Reference Grundy, Wilde and Butterworth91). The differences observed by Berry et al. (Reference Berry, Tydeman and Lewis73) among samples may also be influenced by the vitamin E content of the almond meals. We hypothesise this because, although not significant, postprandial increase in plasma TG seems to be mitigated when comparing the meals containing defatted almond flour + almond oil with the one containing sunflower oil. This suggests a protective effect of vitamin E, as reported elsewhere(Reference Barreca, Nabavi and Sureda92,Reference Yada, Lapsley and Huang93) . The protective effect of hazelnuts in combination with a high-fat diet has also been reported by Di Renzo et al. (Reference Di Renzo, Merra and Botta76). These authors observed a decreased low-density lipoprotein oxidation after a high-fat meal when this meal included hazelnuts.

Effects of orange juice

The beneficial effects of orange juice on postprandial hypertriglyceridaemia were first suggested by Cerletti et al. (Reference Cerletti, Gianfagna and Tamburrelli80). These authors observed a significant decrease in TG concentration after a test meal just by changing water from control meal for red orange juice, with TG decrease being not significant for blond orange juice. Another study suggested that the consumption of orange juice helps to reduce the increase of the inflammatory cytokine interleukin 17A (IL-17A) after a high-fat meal high in saturated fatty acids, but not for other tested cytokines(Reference Rocha, Lopes and Da Silva82). A recent study compared orange juice with fermented orange juice and concluded that fermented orange juice has also a beneficial effect on postprandial hypertriglyceridaemia(Reference Escudero-López, Cerrillo and Ortega81), although no control was included in the study, limiting the extrapolation of their results.

Effect of supplements

Extensive evidence has demonstrated that antioxidants such as vitamin E or carotenoids (but also vitamin C and polyphenols) have protective effects in preventing cardiovascular diseases(Reference Wang, Chun and Song94). Some authors have reported specific beneficial effects of FSM (Table 1) and foods/meals containing FSM (Table 2) during the postprandial state. For example, a study by Deplanque et al. (Reference Deplanque, Muscente-Paque and Chappuis61) in a randomised, double-blind, parallel-group, placebo-controlled study, with 146 healthy normal-weight subjects reported that consumption of a mix of phytonutrients for a period of 2 weeks (a mixture of lycopene and phytosterols: 15 mg of each), phytoene and phytofluene (4 mg total) and β-carotene (0·5 mg)) was enough to increase plasma levels of lycopene, phytofluene and phytoene after a high-fat meal (postprandial state, 8 h after food intake) and decreased oxidised LDL concentration in comparison with the control group. These authors did not observe significant differences in glucose, insulin and TG levels during the postprandial state (8 h after food intake, except for insulin that was measured 2 h after food intake), although values were lower for the supplemented group.

Some information about the effect of vitamin E in postprandial hypertriglyceridaemia can also be found in the literature. Bae et al. (Reference Bae, Schwemmer and Lee62) reported that vitamin E supplementation of a high-fat meal did not reduce serum TG concentration, although they observed protective effects of vitamin E on endothelial function when measuring brachial artery vasodilation during the postprandial period (changed from 13·3% to 6·6% (p ≤ 0·05), 7·1% (p ≤ 0·05) or 13·2% at 2, 4 or 6 h after eating a high-fat meal). In later studies, Neri et al. (Reference Neri, Calvagno and Mauceri63) and Hejazi et al. (Reference Hejazi, Dabbaghmanesh and Mazloom64) reported that serum TG profile at postprandial state was not significantly modified after vitamin E supplementation; even though Neri et al. (Reference Neri, Calvagno and Mauceri63) supplementation also contained vitamin C. However, Hejazi et al. (Reference Hejazi, Dabbaghmanesh and Mazloom64) observed a decrease in malondialdehyde levels (a lipid peroxidation marker) in the postprandial state (2 h after food intake) in comparison with the placebo group. Neri et al. (Reference Neri, Calvagno and Mauceri63) also reported that, even though no effect on lipid profile was found, vitamin E treatment in healthy subjects and subjects with impaired glucose tolerance induced a significant postprandial improvement in redox balance parameters, serum CRP and VCAM-1 levels. No other study focusing on the effect of single FSM is available.

Overall, published data suggest that the presence of FSM in foods tends to decrease postprandial hypertriglyceridaemia and/or inflammation. However, available studies are still limited and therefore should be considered carefully. More research is needed to fully understand the mechanisms underlying FSM effects in this context.

Novel biomarkers to determine the effect of liposoluble vitamins on postprandial hypertriglyceridaemia and inflammation

Postprandial hypertriglyceridaemia and inflammation can be assessed by measuring different biomarkers, the most popular ones being TG and cholesterol levels, oxidised LDL, CRP and cytokines, as shown by the previous studies cited in this literature review. However, it is important to identify and study the potential of novel biomarkers, as the above-mentioned traditional biomarkers have shown limitations in identifying inflammation at early stages(Reference Toriola, Cheng and Neuhouser95,Reference Sakurai and Saruta96) . In this part of the review, we focus on the potential of miRNAs and circulating microvesicles as emerging biomarkers for postprandial hypertriglyceridaemia and inflammation.

miRNAs

miRNAs are a class of gene expression regulators(Reference Catalanotto, Cogoni and Zardo97) that can potentially be interesting biomarkers to evaluate postprandial hypertriglyceridaemia after a high-fat meal. Indeed, monocytes can interact with postprandial TRL before they migrate to the endothelium(Reference Peng and Wu27,Reference Varela, Ortega and Bermudez98) , affecting the transcription of genes involved in lipid homoeostasis and inflammation. Measurement of miRNAs can be used for early detection of asymptomatic and symptomatic diseases(Reference Navickas, Gal and Laucevičius99 Reference Karkeni, Bonnet and Marcotorchino,100), including cardiovascular ones. Certain miRNAs likely modulate cholesterol efflux and reverse cholesterol transport in mammals, as reviewed by Dávalos and Fernández-Hernando(Reference Dávalos and Fernández-Hernando101). In a study in rainbow trout, Zhu et al. (Reference Zhu, Corraze and Plagnes-Juan102) evaluated the different expression of miRNAs known to be involved in cholesterol metabolism when feeding the animals with either a vegetable- or marine-based diet, to address whether miRNAs can be used as biomarkers to determine postprandial hypertriglyceridaemia. These authors reported that a plant-based diet significantly reduced the expression of miR-223, probably a consequence of the absence of dietary cholesterol, in agreement with data obtained in mice(Reference Vickers, Landstreet and Levin103) or in humans(Reference Talbot, Mensink and Smolders104). However, authors also observed discrepancies for other miRNAs, suggesting that there is a limitation regarding the extrapolation of results between different species(Reference Zhu, Corraze and Plagnes-Juan102).

The potential use of miRNAs as a biomarker to determine hypertriglyceridaemia/inflammation has been suggested by several studies(Reference Lopez, Bermudez and Montserrat-de la Paz7,Reference Ortega, Cardona-Alvarado and Mercader105) , with different focuses on how to use miRNAs as biomarkers. miRNAs can potentially be used to evaluate differences between healthy and metabolically disturbed/intervened individuals at a fasting state (lipaemia)(Reference Ortega, Cardona-Alvarado and Mercader105,Reference Ortega, Mercader and Catalán106) or to evaluate the differences in the same individuals but at a different state (fasting versus postprandial state)(Reference Lopez, Bermudez and Montserrat-de la Paz7,Reference Quintanilha, Pinto Ferreira and Ferreira9,Reference Daimiel, Micó and Valls107,Reference Mantilla-Escalante, de las Hazas and Gil-Zamorano108) . Table 3 summarises the main results of these studies. The circulating miRNA profile of adults with obesity performed by Ortega et al. (Reference Ortega, Mercader and Catalán106) suggested that the miRNA profile in plasma was different when comparing obese with non-obese subjects at fasting state. According to these results Reference Ortega, Mercader and Catalán , patients with morbid obesity showed a significant increase in the levels of the miRNAs miR-140-5p, miR-142-3p and miR-222 and a significant decrease in the levels of miR-532-5p, miR-125b, miR-130b, miR-221, miR-15a, miR-423-5p and miR-520c-3p, compared with healthy individuals at fasting state. In a later study by the same research group(Reference Ortega, Cardona-Alvarado and Mercader105), a comparison of miRNA levels of sedentary individuals before and after 8 weeks of a normocaloric diet enriched with 30 g of nuts was performed. As in their previous study, Reference Ortega, Cardona-Alvarado and Mercader authors observed differences between miRNA profiles before and after the diet intervention. Interestingly, they reported a decrease in mi-R221, which is somehow contradictory with the results of their previous study (mi-R221 concentration being lower in obese than in healthy individuals), which highlights the different regulation of this miRNA in plasma in healthy versus obese/metabolically compromised subjects.

Table 3. Relevant human studies regarding the expression of miRNAs related to postprandial hypertriglyceridaemia/inflammation

Lopez et al. (Reference Lopez, Bermudez and Montserrat-de la Paz7) also evaluated differential miRNA expression between fasting and postprandial states (2 h after food consumption) in peripheral blood mononuclear cells (PBMCs) of healthy humans. Compared with miRNA expression signature at fast (and when following the inclusion criteria of >1·2-fold under- or overexpression and statistical difference (p < 0·05)), the authors reported nine down-regulated and nine up-regulated miRNAs in the postprandial state (Table 3). miRNAs hsa-miR-223-3p and hsa-miR-223-5p – the above-mentioned miRNAs involved in cholesterol metabolism in different animal models(Reference Zhu, Corraze and Plagnes-Juan102Reference Talbot, Mensink and Smolders104) – were also detected in this study (see Table S1 of Lopez et al. (Reference Lopez, Bermudez and Montserrat-de la Paz7)) but did not meet the criteria to be selected as overexpressed miRNAs. In a later study, Mantilla-Escalante et al. (Reference Mantilla-Escalante, de las Hazas and Gil-Zamorano108) evaluated the whole mouse miRNome and tried to establish a relationship between the expression of mouse and human miRNAs in the postprandial state. Not all the selected miRNAs from the mouse model (Table 3) showed the same trend in human subjects, but some of these miRNAs (hsa-miR 206, hsa-miR 409-3p and hsa-miR 27b-5p) were up-regulated both in mice and in humans. Interestingly, Lopez et al. (Reference Lopez, Bermudez and Montserrat-de la Paz7) also reported an increase of hsa-miR 206 and hsa-miR 27b-5p in the postprandial state, although the increase was not sufficient to meet their inclusion criteria. Contrary to the results of Mantilla-Escalante et al. (Reference Mantilla-Escalante, de las Hazas and Gil-Zamorano108), Lopez et al. (Reference Lopez, Bermudez and Montserrat-de la Paz7) found a lower expression of mRNAs hsa-miR 409-3p in the postprandial state. Regarding the other miRNAs selected by Mantilla-Escalante et al. (Reference Mantilla-Escalante, de las Hazas and Gil-Zamorano108), Lopez et al. (Reference Lopez, Bermudez and Montserrat-de la Paz7) reported lower levels of hsa-miR-10a-3p and hsa-miR-340-3p, and higher levels of hsa-miR-543 and hsa-miR-125a-3p when comparing fasting with postprandial state, although, again, the difference remained insufficient to meet their inclusion criteria. More recently, Quintanilha et al. (Reference Quintanilha, Pinto Ferreira and Ferreira9) studied the effect of high-fat high-saturated meal ingestion on plasma miRNA expression during the postprandial period in healthy women (Table 3). When comparing their results with the results of Lopez et al. (Reference Lopez, Bermudez and Montserrat-de la Paz7), we observed a shared trend between results (only hsa-miR 200c-3p and hsa-miR 92b-3p showed different tendencies), although in the study of Lopez et al. (2018) none of the miRNAs identified by Quintanilha et al. (Reference Quintanilha, Pinto Ferreira and Ferreira9) meet the inclusion criteria, which could be influenced by the sex difference between studies. Finally, Daimiel et al. (Reference Daimiel, Micó and Valls107) evaluated the effect of olive oil consumption on miRNAs during postprandial state, focusing on fifty-three cardiovascular-related miRNAs. They found that, regardless the polyphenol level in the olive oil, has-let-7e-5p was down-regulated in the postprandial period (Table 3), in agreement with the trend presented by Lopez et al. (Reference Lopez, Bermudez and Montserrat-de la Paz7). Conversely, observations for miR-328a-3p were contradictory, as it was decreased in one study(Reference Daimiel, Micó and Valls107) and increased in another(Reference Lopez, Bermudez and Montserrat-de la Paz7). Moreover, Lopez et al. (Reference Lopez, Bermudez and Montserrat-de la Paz7) observed almost no differences between fasting and postprandial state for miR-20a-5p.

These differences between studies highlight the need for more and larger human in vivo studies to be able to define a reliable range of miRNA biomarkers suitable to assess human postprandial hypertriglyceridaemia. One of the limitations of the available studies is that they tend to focus (or only show the results) on certain miRNAs instead of reporting the whole miRNA human profile, which restricts the comparison with the results of other studies, unless compared studies evaluate the same miRNAs. Only Lopez et al. (Reference Lopez, Bermudez and Montserrat-de la Paz7) reported all miRNAs. Since the expression pattern of miRNAs regulates gene expression and, in some cases, can be associated with different human pathologies, the identification of problematic miRNAs can be of great use for the research community both to try to regulate their expression and to explore their use as relevant biomarkers.

Circulating microvesicles

Endothelial microvesicles can be released into the blood stream from the endothelium as a response to activation, injury or apoptosis of endothelial cells(Reference Dignat-George and Boulanger109). Associations between high levels of these microvesicles, endothelial dysfunction and obesity have been reported(Reference Esposito, Ciotola and Schisano110Reference Helal, Defoort and Robert112). Their potential use as biomarkers to determine the effect of fat consumption in the postprandial state, both in healthy and in non-healthy individuals, has been already evaluated by some studies(Reference Araujo, Silva and Guerra8,Reference Bulut, Jelich and Dacanay-Schwarz113) that reported a significant increase after fat consumption. However, the levels of microvesicles seem to be also affected by blood flow(Reference Jenkins, Padilla and Boyle114,Reference Silva, Sales and Araujo115) . This could affect the interpretation of the results, although Araujo et al. (Reference Araujo, Silva and Guerra8) showed that the circulation of endothelial microvesicles increases in a similar way in individuals with postprandial lipaemia and those with postprandial lipaemia plus disturbed blood flow. According to a recent study by Kumar et al. (Reference Kumar, Sundaram and Mu116), it is not only the blood concentration of endothelial microvesicles that changes after fat consumption, but also their fat composition. High-fat diet dramatically changes the lipid profile of intestinal epithelial exosomes from predominantly phosphatidylethanolamine to phosphatidylcholine, which results in the inhibition of the insulin response and therefore contributes to insulin resistance(Reference Kumar, Sundaram and Mu116). The use of microvesicles as biomarkers has not been fully validated yet, but the available results support their high potential.

Future prospects

The role of FSM, food emulsions and food structure in postprandial hypertriglyceridaemia still needs to be better understood. Available studies regarding the impact of liposoluble vitamins on postprandial hypertriglyceridaemia show promising results, although their interpretation can be complex, either because these studies (i) evaluated foods where other components may be playing a role (e.g. polyphenols or macronutrient profile), (ii) were underpowered, (iii) did not assess the effect of food structure or (iv) were constrained to the use of traditional biomarkers (such as interleukins, cholesterol or TG levels). In addition, little attention is given to the influence of digestion on food structure along the gastric tract, as well as lipid digestion and lipid release on postprandial hypertriglyceridaemia, which would certainly help in understanding the mechanism behind the observed in vivo postprandial responses. Studies with a global approach addressing both in vitro food destructuring and digestion and in vivo biomarkers are thus needed.

From the available literature, it seems clear that dietary approaches that consider food nutrient profile in the postprandial state are needed to properly control postprandial hypertriglyceridaemia. FSM presence in foods appears to have a positive effect in this context. The rise of novel biomarkers such as miRNAs or microvesicles is an opportunity that should also be further explored, as they may bring a better understanding of the metabolic pathways linking foods with hypertriglyceridaemia and inflammation.

Financial support

Ángela Bravo-Núñez’s competitive postdoctoral contract ‘Margarita Salas’ is funded by the Government of Spain (Ministerio de Universidades) and by the European Union (NextGeneration-EU).

Competing interests

Declaration of interests: The authors declare none.

Authorship

The authors’ responsibilities were as follows. A.B.N., E.R.: conceptualisation; A.B.N., E.R.: investigation; A.B.N.: formal analysis, data curation; A.B.N., R.V.: original draft preparation; A.B.N., E.R.: had primary responsibility for final content, reviewing and editing; and all authors: read and approved the final manuscript.

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Figure 0

Table 1. Summary of relevant studies regarding the effect of fat-soluble micronutrients from supplements on postprandial hypertriglyceridaemia and/or inflammation

Figure 1

Table 2. Summary of relevant studies regarding the effect of foods containing fat-soluble micronutrients on postprandial hypertriglyceridaemia and/or inflammation

Figure 2

Table 3. Relevant human studies regarding the expression of miRNAs related to postprandial hypertriglyceridaemia/inflammation