Cholesterol is essential for the proper functioning of the body due to its physiological functions, including being a structural component of cell membranes, a precursor of vitamin D, of steroid hormones (progesterone, oestrogen, testosterone, cortisol and aldosterone) and bile acids. Furthermore, humans are unable to metabolise cholesterol because they do not have metabolic pathways that catabolise the cyclopentane-perhydrophenanthrene ring, so it must be transported to the liver for elimination into the intestine via the bile, along with bile acids. This highlights the importance of cholesterol homeostasis, through the balance between endogenous synthesis, intestinal absorption and biliary secretion of bile acids and cholesterol. Since bile acids are efficiently reabsorbed and some biliary cholesterol is reabsorbed in the intestine, the overall cholesterol balance depends on inputs (synthesis and diet) being balanced by losses (faecal excretion) (Fig. 1). The amount of cholesterol excreted with faeces depends on the efficiency of intestinal absorption of intestinal cholesterol (biliary and dietary) into the enterohepatic circulation. This justifies the interest in the mechanisms of intestinal cholesterol synthesis and absorption as therapeutic targets for lowering cholesterolaemia.

Figure 1.

Hepatic and intestinal cholesterol regulation mechanisms. HMG-CoAr, 3-hydroxy-3-methyl-glutaryl-CoA reductase; LDL, low density lipoprotein; NPC1L1, Niemann-Pick C1 L1.

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Hypercholesterolaemia with increased LDL-C is associated with the accumulation of cholesterol in the arterial wall, which is the main factor in the development of atheromatous plaque, whose growth and eventual thrombosis leads to ischaemic syndromes. In this sense, cardiovascular disease (CVD) and especially coronary heart disease and atherothrombotic ischaemic stroke are the leading cause of mortality worldwide and one of the main contributors to disability. In Spain, according to data from the National Institute of Statistics, diseases of the circulatory system continue to be the leading cause of death in 2020 with 119,853 deaths, representing 24.3% of total deaths, with an increase of 2.8% over the previous year.11

The pathophysiological understanding of atherosclerosis is becoming increasingly precise and has led to the identification of LDL-C as a primary aetiological agent, which stimulates inflammatory phenomena and cell proliferation in the vascular wall.12,13 The cardiovascular benefits of lipid-lowering drugs are due to their lowering effect on LDL-C concentrations. There is strong clinical evidence, extensively explored by the Cholesterol Treatment Trialist Collaboration (CTTC),14 showing that the reduction in CVD risk associated with statin therapy is mediated by the lowering of LDL-C concentrations in absolute terms. In addition, LDL-C lowering mediated by other drugs, such as ezetimibe or proprotein convertase subtilisin/kexin type 9 (iPCSK9) inhibitors, or even by non-pharmacological means, such as diet or ileal bypass surgery, leads to the same risk reduction per unit of reduced LDL-C.15 Subsequently, the benefit of cholesterol lowering, regardless of the mechanism by which it is achieved, has been corroborated by Mendelian randomisation studies.16

More recently, studies with iPCSK9 assessing the progression of coronary atherosclerosis using intravascular ultrasound and innovative image analysis techniques have shown that even decreases in LDL-C below those currently recommended are accompanied by a decrease in the atherosclerotic burden and beneficial effects on plaque composition.17 It can therefore be stated that in this clinical situation we are performing an aetiological treatment of the disease.

The therapeutic arsenal for the management of hypercholesterolaemia includes potent, safe drugs with numerous scientific evidences of efficacy and safety, both in primary and secondary prevention of CVD. Drugs as varied as statins, ezetimibe, PCSK9 inhibitors, bempedoic acid and anion exchange resins are available. In monotherapy or in combination, these drugs achieve therapeutic goals in most patients with severe hypercholesterolaemia, with the exception of patients with homozygous familial hypercholesterolaemia (FH). However, in clinical practice, side effects, personal reasons or lack of efficacy, among other barriers, make it difficult to achieve optimal control of dyslipidaemia in many patients. In these circumstances, functional foods or nutraceuticals can play an important role.

The functional foods and nutraceuticals with the greatest efficacy in reducing cholesterol levels are listed in Table 1, showing the expected cholesterol-lowering effect of each of them. Fig. 2 summarises their different mechanisms of action.

Figure 2.

Mechanisms of action of plant sterols and nutraceuticals. Modified from Cicero AFC, Colleti A, Bajraktari G, Descamps O, Djuric DM, Ezhov M, et al. Lipid lowering nutraceuticals in clinical practice: Position paper from an International Lipid Expert Panel. Arch Med Sci. 2017;13:965-1005. doi: 10.5114/aoms.2017.69326.

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Oilseeds (cereals, legumes, nuts) contain steroid-type phytochemical compounds, the plant sterols or phytosterols, whose cholesterola-lowering properties have been known since the 1950s.26 Sitosterol and campesterol are the most abundant and on average comprise 65% and 30% of the usual dietary intake of phytosterols. The chemical structure of phytosterols differs from that of cholesterol by the presence of C:24 modified side chains. Stanols, which are less abundant in nature, are saturated sterols, i.e., they lack the double bond in the steroid ring.27 Although their molecular structure is almost identical, cholesterol and phytosterols are metabolised differently. Cholesterol absorption in the human intestine averages 50%, whereas absorption of phytosterols is no more than 5% and, once absorbed, they are rapidly excreted in the bile. In gram quantities in the intestinal lumen, phytosterols and stanols reduce the absorption of cholesterol, both from the diet and from bile, because they displace the steroid from the micelles that solubilise it as a step prior to its absorption by the NPC1L1 transporter. NPC1L1.27 Reduced absorption results in less cholesterol reaching the liver, which has two compensatory effects: increased synthesis and increased expression of LDL receptors (Fig. 2), two processes activated by the transcriptional factor SREBP-2 (Sterol-regulatory element-binding protein-2) sensitive to hepatic cholesterol concentration. The net effect is a reduction in serum LDL-C concentrations.28

Other mechanisms involved in the cholesterol-lowering effect of plant sterols include inhibition of enzymatic esterification of free cholesterol in the enterocyte, so that less cholesterol will be incorporated into the forming chylomicrons, and there will be increased synthesis of the ABCG5 and ABCG58 transporters, which facilitate the efflux of free cholesterol from the enterocyte back into the intestinal lumen.29 The amount of phytosterols provided by a plant-rich diet does not usually exceed 600 mg/day. These compounds have been introduced on the market as functional foods, enriching dairy products, margarines and other foods. The cholesterol-lowering effect appears to be dose-dependent up to intakes of 3 g/day, with an average reduction in LDL-C of 12%.30 Phytosterols can also reduce triglycerides, but only in individuals with elevated triglycerides at baseline.31 A meta-analysis of RCTs concluded that plant sterol supplementation significantly increases the concentration of anti-atherogenic apolipoproteins (Apo-AI, Apo-CII) and reduces the concentration of atherogenic apolipoproteins (Apo-B and Apo-E).32

Numerous studies have demonstrated their efficacy in patients treated with statins, in which the LDL-C lowering effect is additive. Although there are fewer studies, they also appear to be effective in combination therapy with ezetimibe or fibrates.29,33

The period of consumption of plant sterols required to observe their effect is at least 2−3 weeks and, to optimise their efficacy, they should be ingested during main meals, when gallbladder contraction discharges cholesterol-laden bile into the duodenum. Plant sterols interfere with the absorption of fat-soluble vitamins (beta-carotene, lycopene, alpha-tocopherol, etc.), and a reduction in serum concentrations of these vitamins has been reported without clinical relevance. However, it is advisable to consume a diet with plenty of fruit and vegetables rich in carotenoids.33 The consumption of plant sterols is contraindicated in patients with sitosterolaemia, a rare genetic disease in which there is intestinal hyperabsorption of sterols (15%–60%, compared to 5% absorbed by healthy individuals) leading to a high concentration of plasma sterols (not cholesterol) which could be related to the severe atherosclerosis in these subjects.29

Although plant sterols at a dose of 2−3 g daily are recommended in different guidelines as an adjunct to lifestyle modification to reduce cholesterolaemia, there are no RCTs showing cardiovascular benefits.34 Nor are they likely to be conducted given the cost, complexity and time involved in clinical trials with hard cardiac CVD events as the primary outcome. However, the concept that LDL-C reduction by any mechanism is associated with cardiovascular benefit is well established.35

In conclusion, sterols and stanols are incorporated into various functional foods in an ever-expanding market because they are safe and effective ingredients for lowering LDL-C, as adjuvants to a healthy diet or to treatment with various lipid-lowering drugs.

Dietary fibre, resistant to hydrolysis by human digestive enzymes, is an integral component of fruits, legumes, vegetables, nuts and whole grains. There are 2 distinct types of dietary fibre defined by their water solubility: insoluble fibre, abundant in whole grains, and soluble fibre, found mainly in legumes, vegetables, fruits and oats (beta-glucans).

The cholesterol-lowering effect of soluble fibre is due to the fact that, in contact with water, it forms a gel that increases the viscosity of the food bolus, and acts as a physical barrier reducing intestinal absorption of cholesterol. In addition, soluble fibre binds bile acids in the small intestine and promotes their faecal elimination, so that hepatic cholesterol is directed towards bile acid synthesis, increasing hepatic uptake of circulating cholesterol into the plasma, with a consequent reduction in cholesterolaemia, a mechanism of action similar to that of anion exchange resins. Another beneficial mechanism of fibre is the production of short-chain fatty acids (mainly butyric and propionic acids) resulting from the fermentation of fibre by the colonic microbiome as these acids can inhibit HMG-CoA reductase, reducing hepatic cholesterol synthesis and contributing to the hypocholesterolaemic effect of soluble fibre.2

Products rich in soluble fibre, such as beta-glucan (from oats or barley), glucomannan (extract from the plant Amorphophallus konjac) and psyllium (extract from Plantago ovata), have shown beneficial effects on the lipid profile. Daily doses that have shown a cholesterol-lowering effect vary between 3 and 30 g depending on the product, achieving a reduction in LDL-C of between 7% and 15%.18,22 The addition of oat fibre to a Mediterranean diet induced a reduction in LDL-C by 15%. Intake of 10 g/day of psyllium resulted in an average LDL-C reduction of 7%, with a greater effect in individuals consuming a high-fat diet.22,36

Glucomannan is a soluble fibre derived from konjac root, which decreases cholesterol absorption in the jejunum and bile acid absorption in the ileum, and increases the activity of hepatic 7-α-hydroxylase, a key enzyme in the synthesis of bile acids from cholesterol, contributing to the reduction of cholesterolaemia. A meta-analysis shows that glucomannan (at doses between 1.2 and 15.1 g/day) significantly reduces LDL-C and triglycerides, respectively by 15.9 mg/dL and 11.5 mg/dL (p < .05 for both) on average.37

In general, tolerance to soluble fibre intake is good, except for the occurrence of gastrointestinal symptoms such as meteorism and diarrhoea that may occasionally limit adherence. Glucomannan intake may reduce the absorption of fat-soluble vitamins, calcium and lipophilic drugs, so it is recommended to separate its intake from that of this compound.18,22

Red yeast rice (Monascus purpureus) has been used as a dye, preservative, flavouring and as a remedy in traditional Chinese medicine to improve blood circulation. Rice fermented by the yeast takes on a reddish hue produced by pigments resulting from fermentative metabolism. It contains monacolin, a compound with a chemical structure similar to lovastatin and a cholesterol-lowering action through inhibition of HMG-CoA reductase,18 and other compounds such as plant sterols, isoflavones and monounsaturated fatty acids, with a potential beneficial effect on the lipid profile.38

Red yeast rice comes in capsule form (it is a nutraceutical, not a functional food) and its lipid-lowering efficacy is directly related to the amount of monacolin K it contains.39 Consumption of between 3 and 10 mg/day of monacolin K results in a 10%–25% reduction in LDL-C, which is accompanied by similar reductions in total cholesterol, apolipoprotein B, and high-sensitivity C-reactive protein. In a Chinese RCT involving 1445 subjects with a history of acute myocardial infarction, red yeast rice supplementation for 4 years versus placebo showed a reduction in the risk of ischaemic heart disease (31%; p = .04), all-cause mortality (31.9%; p = .01) and stroke (44.1%; p = .04), with a good safety profile.41

In general, the consumption of red yeast rice has few associated risks. In a meta-analysis, there was no increased risk of muscle symptoms with monacolin treatment. Monacolina.42 However, since monacolin is structurally identical to a synthetic statin, the use of high doses can cause myalgia in people intolerant to statins.40 In fact, recently the European Commission has established a limit concentration level of 3 mg of monacolin K per daily dose.43

Monacolin inhibits the activity of CYP P450 and P-gp enzymes. Therefore, the concomitant use of red yeast rice with strong inhibitors of CYP3A4 (imidazole antifungals, macrolides, protease inhibitors…) or CYP1A2 (for example, verapamil) may increase the risk of adverse reactions,42 which makes their association inadvisable, especially with high doses.

A potential danger of consuming red yeast rice in nutraceuticals is the lack of standardization of some of the preparations, which may present different concentrations of monacolin K. To avoid the use of low-quality products, companies that market nutraceuticals with monacolin K should list all the substances they contain and their doses.18

The combination of several nutraceuticals in a single formulation leads to obtaining a polypill, with several theoretical advantages. The first is greater colesterol-lowering efficacy, with a reduction in LDL-C concentrations, which range between 5% and 25%. Secondly, associating the combination with an already prescribed pharmacological therapy could avoid adding a second drug or using lower doses of it, minimizing the risk of side effects, improving adherence and avoiding the use of more expensive drugs, such as PCSK9i., offering cost-effective control. The basic principle of combinations of nutraceuticals is that each of them has a different hypolipidaemic action to achieve a synergistic effect, in such a way that, with lower doses than those used of each of them separately, a similar cholesterol-lowering effect is achieved. Furthermore, by consuming smaller amounts of a nutraceutical, an attempt is made to reduce the occurrence of adverse effects.22 A systematic analysis that provides accurate information on the effectiveness of nutraceuticals is a recent meta-analysis of 148 studies that included 13,062 participants. In it, the cholesterol-lowering effect of these products was compared, in isolation and in different combinations. The association of red yeast rice rich in monacolin K with berberine was the most effective and this effect was not modified with the addition of policosanols.45

Regarding the results obtained in RCT, the only nutraceutical formulation with class I evidence is a product that includes a combination of berberine (500 mg), red yeast rice (200 mg, including 2.8 mg of monacolins), policosanols (10 mg), coenzyme Q10 (2 mg), astaxanthin (.5 mg) and folic acid (.2 mg), although the only components of this combination that have been shown to be effective in reducing LDL-C are berberine and red yeast rice. This product was evaluated in the context of a low-fat diet in a parallel RCT of 16 weeks duration, carried out in 751 patients with moderate hypercholesterolaemia in 248 centres in Italy. A reduction in total cholesterol of 19.1% was observed in the nutraceutical group associated with the diet compared to 9.4% in the group with the isolated diet (p < .001), with a reduction in LDL-C of 23.5% compared to 10.8% (p < .001) and triglycerides of 17.9% compared to 11.3% (p < .001) respectively, with an increase in HDL-C of 4% compared to 1.6% (p < .001).46 The doubt remains as to whether this product is more effective than one of its isolated components, red yeast rice. Although there are no clinical trials in which both have been compared directly, in a review that collects data from several meta-analyses, it was shown that the product derived from the combination of 6 components containing red yeast rice with a dose of monacolin K of 3 or 10 mg reduced LDL-C by 15% and 25%, respectively. In turn, in the existing RCTs, the isolated red yeast rice used with the same doses of monacolin K, 3 and 10 mg, reduced LDL-C identically, 15% and 25% respectively.

In conclusion, consumption of the product containing 6 nutraceuticals (with the recommended amount of monacolins K of less than 3 mg/day) has a colesterol-lowering effect significantly greater than that of a low-fat diet. However, there are no RCTs that demonstrate that this combination, containing red yeast rice equivalent to 3 mg of monacolins, is more effective than the use of isolated red yeast rice, with the same monacolin content.

The degree of scientific evidence for the use of combined therapy of functional foods or nutraceuticals with statins or ezetimibe is limited, given that the existing clinical trials are scarce, with populations of small sample size, short duration, variegated design and suffer from frequency of low systematisation in the doses of nutraceuticals used. The result of all of this is that the scientific quality of the information we have is not optimal.

Functional foods and nutraceuticals whose lipid effects have been examined in combination therapy with lipid-lowering drugs are berberine, soluble fibre, plant sterols, bergamot, red yeast rice and mixtures of several of these, especially berberine and red yeast rice. Berberine, which in monotherapy is attributed with an LDL-C reduction capacity of between 20 and 50 mg/dL, has been used in combination with statins, although few clinical trials exists and they are of low methodological quality, which has prevented a meta-analysis from being carried out. There is a systematic study of 4 RCTs with berberine, all carried out in China, and published in little-known journals in that country. Berberine added to low or moderate doses of statins resulted in an additional decrease in total cholesterol of 10.4 mg/dL and LDL-C of 4.25 mg/dL, with an increase in HDL-C of 7.7 mg/dL. dL.47 In an RCT designed to examine the effect of soluble fibre added to statins, 68 participants were randomized into 3 groups. They received treatment for 8 weeks with simvastatin 20 mg associated with placebo, simvastatin 10 mg associated with placebo, or 10  mg of simvastatin associated with 15 g of psyllium. The combination of simvastatin with soluble fibre had the same efficacy in reducing LDL-C as monotherapy with 20 mg of simvastatin.48 Similar data were obtained in another RCT with 36 volunteers, randomized for 4 weeks to receive 10 mg of lovastatin associated with 15 g of psyllium or 20 mg of lovastatin in monotherapy. The benefit was the same in both groups of participants.49 In another RCT, 30 g of total fibre (equivalent to 6 g of soluble fibre) associated with 40 mg of rosuvastatin was compared with statin monotherapy. The result was a similar decrease in LDL-C in both groups, which would indicate that the additive effect is only evident when soluble fibre is associated with low or moderate intensity statins.50 Another nutraceutical, bergamot (1 g daily), was studied in association with 10 mg of rosuvastatin, compared with 20 mg of rosuvastatin in monotherapy. The regimen in which the nutraceutical was included was accompanied by a 53% decrease in LDL-C, similar to that obtained with 20 mg rosuvastatin monotherapy. The decrease in triglycerides and the increase in HDL-C were greater with the presence of the nutraceutical.51

Regarding the combination therapy of statins with phytosterols or stanols, data from a meta-analysis of 15 RCTs comprising a total of 500 participants indicate that phytosterols/stanols at doses of 2−3 g/day, in combination with statins, compared with statins in monotherapy, produce significant additional reductions in total cholesterol and LDL-C of 11.6 mg/dL (95% CI, −13.5 to −9.7), without changes in HDL-C or triglycerides.52 Therefore, the colesterol-lowering effect of phytosterols/stanols added to statins is similar to that of these functional foods administered alone. Taken together, and in the absence of more information, the available studies indicate that the nutraceuticals studied could be used to reduce the dose of statins by half.

Other studies have examined the efficacy of various combinations of nutraceuticals associated with different lipid-lowering therapies. In one of them, carried out in 45 people with diabetes mellitus and hypercholesterolaemia with intolerance to statins, berberine (500 mg/day) and silymarin (105 mg/day) were associated. The participants were distributed into 3 groups: those who had abandoned previous treatment with statins, those who had stopped statins but started treatment with ezetimibe, and those who had reduced the dose of statins to tolerance. In all of them, an additional decrease in LDL-C was observed at 6 months, which was 15% in the statin group, 20% in the ezetimibe group, and 17% in the control group that only received nutraceuticals. Tolerance was good in all cases.53 In another RCT, statins at moderate doses were compared against an association of ezetimibe, red yeast rice (200 mg/day, containing 3 mg of monacolines), berberine (500 mg) and policosanol (10 mg), in 26 patients with FH who refused statins. The efficacy on LDL-C was similar in both groups, which implies that the combination of ezetimibe with nutraceuticals, in these individuals, achieves an effect similar to moderate doses of statins.54

Of all the combinations of nutraceuticals, the most studied is the one already mentioned, which includes berberine (500 mg), red yeast rice (200 mg, including 2.8 mg of monacolines), policosanols (10 mg), coenzyme Q10 (2 mg), astaxanthin (.5 mg) and folic acid (.2 mg). The effectiveness of this product associated with ezetimibe, statins or multiple therapy has been studied in 3 RCTs carried out by the same group of researchers, with certain limitations, such as the use of different types and doses of statins or the lack of control groups in some of them. Each one was carried out in 100 patients with ischaemic heart disease intolerant to statins, and with diverse designs. In one of them they were randomized to receive treatment with ezetimibe or the aforementioned combination of nutraceuticals. At 3 months, only 14 of the participants in the nutraceutical group reached the LDL-C goal ≤ 100 mg/dL. Ezetimibe was then added to the nutraceutical combination for the 86 participants who had not reached this goal, so that the LDL-C goals were achieved in 58 of the 86 participants (72.5%) after one year.55 A second RCT was carried out in 100 patients with coronary heart disease, similar to the previous ones and who had not achieved a 50% decrease in LDL-C with low doses of statins. Fifty of them were randomized to continue with the same doses of statins (10−20 mg/day of simvastatin or 5−10 mg/day of atorvastatin or 5 mg/day of rosuvastatin) and the remaining 50 began treatment with the same dose of statin in combination with the same combination of nutraceuticals. At 3 months, 68% of those treated with the combination reached the goal of LDL-C< 70 mg/dL, while no patient in the control group, with low doses of statins in monotherapy, achieved it. Three patients in each group had to drop out due to mialgia.56 The remaining 36 patients who did not reach the goal (<70 mg/dL LDL-C) were started on triple therapy with low-dose statins, ezetimibe, and nutraceuticals, with 28 of them reaching the previously indicated LDL-C goal at 6 months. To sum up, 92% were controlled with double or triple therapy, with few notable side effects.57 Finally, in a study by another group of researchers, carried out in 30 patients with FH on stable treatment with statins at the maximum tolerated doses, in monotherapy or associated with ezetimibe, the addition of the nutraceutical containing berberine, policosanol and red yeast rice induced a slight additional effect of reduction of total cholesterol, LDL-C, non-HDL-C and triglycerides of 8.1%; 10.5%; 9.7% and 5.4%, respectively.54

In short, the available studies that explore the cholesterol-lowering effect of different functional foods or nutraceuticals in combination with statins or ezetimibe are scarce, variegated in design, include few participants, and are published in journals that are not always of proven quality. In general, these studies confirm the capacity of the functional foods and nutraceuticals reviewed in this work to reduce LDL-C in a similar way to that of statin dose doubling. The tolerance described is generally good, but the lack of replication of the studies and the aforementioned methodological limitations prevent these treatments from being recommended with sufficient certainty. Results need to be confirmed by improving the methodology and size of the populations studied. Regarding the combinations of various nutraceuticals, the most studied is that of berberine and red yeast rice, which is marketed together with other components. With all their limitations, the results of the existing RCTs would support the cholesterol-lowering effect of the combination and its good tolerance, offering an alternative to high doses of statins when combined with ezetimibe and/or moderate doses of statins. The lack of clinical evidence studies forces us to be cautious with its recommendation.

Currently, there is no internationally accepted consensus on the role of functional foods and nutraceuticals in the treatment of hypercholesterolaemia. However, the positioning of the main scientific societies is briefly reviewed.

The latest version of the 2019 guidelines of the European Society of Cardiology (ESC)/European Artherosclerosis Society (EAS) for the treatment of dyslipidaemia summarises the existing evidence on the most effective functional foods and nutraceuticals for the treatment of hypercholesterolaemia.9 According to these guidelines, with the aim of achieving the LDL-C target and given that there are no contraindications derived from their safety, "plant sterols/stanols can be considered: (a) in individuals with high cholesterol concentrations with an intermediate or low overall risk of CVD, not meeting the requirements for pharmacotherapy; (b) as a complement to pharmacological treatment in patients at high and very high cardiovascular risk who do not reach LDL-C goals with statins or who cannot be treated with statins; and (c) in adults and children (>6 years) with FH. These guidelines also point out that "nutraceuticals containing purified red yeast rice are an option to consider in people with high cholesterol concentrations who do not meet the indication for treatment with statins in view of their overall cardiovascular risk".9

The approach of the U.S.A. recommendations is different. In the 2018 guideline of the AHA/ACC/AACVPR/AAPA/ABC/ACPM/ADA/AGS/APhA/ASPC/NLA/PCNA, nutraceuticals are not mentioned and the importance of paying special attention to the diet58 is only mentioned in passing. In 2018, the International Lipid Expert Panel (ILEP) published a position paper defining the use of nutraceuticals in the management of statin intolerance.46 In this case it is established that "nutraceuticals, such as red yeast rice, bergamot, berberine, artichoke, soluble fibre and plant sterols and stanols alone, in combined treatments or associated with ezetimibe, could be considered a lipid-lowering alternative or an additional therapy to statins.”46

The ESC 2021 guideline on CVD prevention in practice indicates the potential benefit of nutraceuticals, noting that “their use could improve the quality of lipid-lowering treatment, including therapeutic compliance and achievement of LDL-C goals in clinical practice.” 59 However, the ESC document warns about the lack of evidence showing that nutraceuticals prevent morbidity and mortality from CVD. Therefore, they are positioned on their usefulness as a possible treatment option in mild dyslipidaemia, indicating the low level of evidence regarding its benefit on cardiovascular clinical episodes.

The SEA emphasizes that there are no cardiovascular morbidity and mortality studies with nutraceuticals or functional foods, and that there are few or limited long-term safety data. Both aspects should be discussed with the patient before proceeding to recommend their use. Likewise, it is understood that the functional foods and nutraceuticals that have the greatest amount of scientific evidence are phytosterols and red yeast rice. According to the data reviewed, the SEA considers that the use of nutraceuticals could be recommended in the following situations (Table 2).

This document was prepared independently and was not funded by any pharmaceutical company or corporation.

PP-M received fees for scientific advice, lectures and educational activities from Ferrer, Novo-Nordisk, Boehringer Ingelheim, Amgen, Esteve, Menarini, Daiichi-Sankyo, Servier and Viatris. ER received scientific consulting fees from Alexion and the California Walnut Commission. JP-B received fees for speaking engagements and educational activities from Amarin, Amgem, Daiichi-Sankyo, Esteve, Ferrer, MSD, Sanofi, and Viatris. FC received fees for speaking engagements and educational activities from Ferrer, Amgen, Sanofi, and Novartis. VP-F received fees for lectures and educational activities from Adamed, Amarin, Almirall, Astra-Zeneca, Daichii-Sankyo, Esteve, Ferrer, Novartis, Sanofi-Aventis, Servier, Viatris. CG does not receive fees for conferences or training activities from the pharmaceutical or food industry. RS received fees for educational activities from Viatris and scientific projects with Rottapharm/Madaus. FP-J does not receive fees for conferences or training activities from the pharmaceutical or food industry. JMM received fees for speaking engagements and educational activities from Amgen, Sanofi, Novartis, Ferrer, Daiichi Sankyo, Servier, and Viatris.