Obesity is the main modifiable risk factor for the development of chronic degenerative diseases (CDDs) such as diabetes mellitus (DM) and cardiovascular diseases, which represent the leading causes of mortality worldwide, along with other complications.1,2 In Mexico, the prevalence of overweight and obesity has increased from 61.8% in 2000 to 72.5% in 2016.3 On analysing the results of the 2016 National Health Survey by geographical zones, the figures are seen to be even higher than the national average in the north of the country (73.9%3,4).

There is evidence that imbalanced nutrition is related to CDDs. In recent years, the trends in eating habits have been towards an increased consumption of fast foods that are high in saturated fat, sodium, proteins of animal origin, refined flour and sugar. The quantities consumed have also increased. As an example, soft drink cup servings tripled in size.5 On the other hand, these foods contain little fibre, which is why one of the strategies of the Mexican National Agreement on Food Health (Acuerdo Nacional para la Salud Alimentaria) has been to increase the daily consumption of vegetables, legumes, whole grain cereals and fruit—incrementing their availability and accessibility, and promoting their consumption.6,7

One way to address this problem is to recommend that concrete supplements and food products be included in the diet. These products must contribute to the specific needs and requirements of the population, ensuring that their intake does not cause problems of intolerance or malabsorption. Furthermore, they must be easy to prepare and should be agreeable from the organoleptic perspective, i.e., their colour, smell, texture and taste should be pleasant to encourage consumption with the recommended frequency.8

The aim of a food product is to improve the nutritional intake of the individual with a view to securing good health. Consumption of such products is mediated by factors such as culture, habits, physical environment and the availability of resources. These products are added to the normal diet of the individual and may be formulated based on vitamins, minerals, fibre, amino acids, proteins, fatty acids, carbohydrates, antioxidants, herbal extracts or concentrates and foods, among others, either alone or in different combinations. Food products or supplements can be packaged and supplied in the form of tablets, capsules, liquids or powders. Nevertheless, it must be taken into account that they are not a substitute for food, and do not constitute the only component of a correct diet.9

Few studies are available on food products and their effect on human health. In this regard, studies on plant proteins are mainly referred to soya, and publications on other legumes are scarce. It is important to develop and evaluate food products that encourage their consumption and afford nutritional benefits, leading to a more balanced and better quality diet. The purpose of this study was to assess the effect of a 6-legume powder product, prepared as no added sugar chocolate shake, upon the lipid profile and certain biochemical markers related to obesity, metabolic syndrome and CDDs in a group of healthy adults. The markers evaluated were serum malondialdehyde (MDA) as an indicator of lipid peroxidation; high-sensitivity C-reactive protein (hsCRP) as a mediator of inflammation and an indicator of coronary risk; and insulin resistance in the fasting state as estimated by the homeostatic model assessment (HOMA).

Based on the established screening criteria, the study included a total of 60 subjects, of which 53% were males. The study population was randomly divided into a control group (n = 30; 53% males) and a study group (n = 30; 46% males). Four subjects were excluded because they failed to comply with the anthropometric, dietary and laboratory tests at the end of the three-month intervention period (Fig. 1). Table 1 shows the anthropometric characteristics of both groups before and after the intervention.

Figure 1.

Flowchart of the methodology used in the study.

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The biochemical test results are shown in Table 2. At the end of the intervention, the study group showed a significant decrease in MDA (P = .001), glucose (P = .001) and HOMA index (P = .017), with no significant changes in the rest of the blood parameters. However, a nonsignificant decrease in serum total cholesterol and LDL-C was observed (P = .092 and P = .105, respectively). In this same group, the serum glucose concentration decreased almost 10 mg/dl at the end of the intervention.

The diet of the participants showed no significant variations at the end of the study. However, the most relevant data were referred to the intake of total fatty acids, which was greater than the recommendation of 2%–30% daily, and to total fibre intake, which was lower than the 27−40 g daily advised by the World Health Organization (WHO),16 and the 25−35 g daily suggested by the American Dietetic Associatio.17 The data are shown in Table 3.

The labelling of the study food product offers nutritional information, indicating that it contains the following ingredients: legumes in powder form (soya [Glycine max], frijol bean [Phaseolus vulgaris], chickpea [Cicer arietinum ], lentils [Lens culinaris], faba bean [Vicia faba] and kidney bean [Phaseolus vulgaris]), vegetable fibre, fructose, cocoa, guar gum, carboxymethylcellulose, xanthan gum, cinnamon, silicon dioxide, lecithin, vitamin E acetate, sucralose and ethyl vanillin. Table 4 shows the nutritional information contained in the product labelling. It can be seen that the total protein and carbohydrate content corresponds to a little over 80% w/w of the product, while the fibre content practically reaches 10% w/w.

Table 5 shows the total polyphenol content in each of the three random samples of the food product. The mean value of these measurements was 184.41 mg of gallic acid equivalent per gram of product.

In recent years, and in coincidence with our own observations, a number of studies have reported a decrease in blood glucose levels with the consumption of legumes or dietary fibre. Among these studies, mention should be made of the article published by Simpson et al., who found that a diet high in carbohydrates and legume viscous fibre can improve glycemic control in both type 1 and type 2 diabetic patients.18 Yao et al. found fibre intake to decrease the risk of developing type 2 DM (T2DM). They suggested that the consumption of at least 25 g of dietary fibre daily could help prevent the development of T2DM.19 Chandalia et al. showed that a high fibre diet promotes glycemic control, decreasing hyperinsulinemic states and favouring a decrease in plasma lipid levels in patients with T2DM.20 Likewise, in 2013, Agrawal and Ebrahim reported that daily or weekly legume consumption is inversely associated to the presence of diabetes in a population in India. As they point out, however, further epidemiological research is needed to confirm this association.21 Other studies in the same line have related legume intake to a lower risk of developing diabetes.22–26

As regards the diet of the participants in our study, no significant differences in nutrient intake were seen before and after the intervention (Table 3). It should be noted that the control group showed a decrease in caloric intake of 600 kcal at the end of the study. However, this decrease only tended towards statistical significance (P = .055), in contrast to the situation in the study group (P = .44). With regard to the lack of correspondence in caloric intake in the control group, we believe that two factors may have exerted an influence. On one hand, the control group had no type of limitation in intake during the study, and on the other hand, the study ended at the close of the academic period: since these were individuals studying a career as demanding as Medicine, the control group very likely felt greater pressure as a result of their final examinations, and this could have influenced their caloric intake. It should be noted that the food frequency analysis did not include the intake of nutrients from the food product under study. The significant reductions in blood glucose and HOMA index recorded at the end of the intervention therefore could be explained at least in part by the intake of soluble fibre, which is abundant in legumes.21

In relation to the effect of the consumption of legumes upon the plasma levels of total cholesterol, LDL-C, triglycerides and HDL-C, a number of studies suggest that legumes, as part of the normal diet, exert beneficial effects upon the lipid profile, not only in diabetes, but also in individuals with metabolic syndrome and cardiovascular diseases.26 Such benefits include a reduction in total cholesterol, LDL-C and triglycerides,27 as well as an increase in HDL-C concentration,28 which was not evidenced in the present study. In contrast to the above information and in line with our own findings, Mackay and Ball reported no changes in the plasma concentrations of total cholesterol and LDL-C in hypercholesterolemic subjects consuming a diet rich in white beans and other legumes.29 However, in this study the group receiving the food product showed a decrease in serum LDL-C concentration from 123.6 mg/dl to 119.0 mg/dl at the end of the intervention—though the difference failed to reach statistical significance (P = .105).

On the other hand, with regard to the imbalance between antioxidant and oxidant species systemically present in the body—a phenomenon known as oxidative stress (OS)—it is now accepted that OS is responsible for an increase in undesirable processes that affect macromolecules such as proteins, lipids and DNA. Oxidative stress is associated to a large number of disorders, and particularly to chronic degenerative diseases such as T2DM, Parkinson’s disease, arterial hypertension, Alzheimer’s disease and atherosclerosis, to name but a few. In some cases OS has been identified as the causal agent of the disease, while in other cases it is a consequence of the disease.30 In recent years, a number of studies have shown that fruit and vegetable consumption can reduce morbidity and mortality due to such disease conditions, thanks to their high polyphenol content and protective effects as antioxidants.31,32

Polyphenols—particularly flavonoids and phenolic acids—are characterised by their wide distribution in foods commonly consumed by humans, such as fruit, vegetables and legumes, and by their important antioxidant properties.22,31,33 In addition, and mainly in soya, a number of isoflavones have been identified that exert significant inhibitory effects upon alpha-glucosidase. These isoflavones include genistein, daidzein and glycitein, which exert their effect in a dose-dependent manner—with genistein exhibiting the greatest inhibitory effect.34 This isoflavone has also been identified in frijol beans and lentils, and has been implicated in the improvement of glucose homeostasis, as reported by Squadrito et al.35 These authors, in a randomised, double-blind, controlled study involving the daily administration of 54 mg of genistin (the glycoside of genistein) during one year among 60 postmenopausal women with metabolic syndrome, observed a significant decrease in HOMA index at the end of the intervention. Despite the differences in trial design, these findings are consistent with those obtained in our study group.

In this same sense, it should be noted that the control group also showed a significant decrease in HOMA index (Table 2). However, it needs to be underscored that in this group four subjects had basal insulin levels > 20 μIU/mL, and three of them presented a baseline BMI of 30−32 kg/m2, which suggests that these individuals had insulin resistance. On recalculating the median HOMA scores before and after the intervention, without taking into account the data corresponding to these four subjects, the values were found to be 2.03 and 1.01, respectively. When compared using the Mann-Whitney U test, this resulted in P = .08.

The inhibitory effect of phytochemical extracts of isoflavones and soyasaponins upon alpha-glucosidase and alpha-amylase, as well as their hypoglycemic effect in DM, has been demonstrated in different animal models and with different designs.36–38 On the other hand, it has been seen that d-pinitol, an inositol derivative purified from soya, may be useful for controlling the postprandial increase in blood glucose in patients with T2DM.39

As regards the antioxidant properties of the study product, the quantification of its total polyphenol content using the Folin-Ciocalteu method yielded an mean of 184.06 ± 5.46 mg of gallic acid (GA) equivalent per gram of product. Based on this result, and in accordance with the recommended daily intake for this product (15 g/day), the subjects in the study group consumed a total amount of polyphenols of 2760 mg/day of GA equivalent during the intervention. This may explain our findings regarding the significant decrease in serum MDA levels at the end of the intervention.

Although little information is available on the intake of phenolic compounds from food, some authors suggest that polyphenol intake from the diet of some populations may range from 50 to 800 mg/day, depending on the consumption of the products containing them.40 However, a study conducted in a population in the United States found polyphenol intake to be 1000 mg/day,41 which can be achieved through a diet rich in fruit, vegetables and legumes, or by means of supplements providing this amount. It is important to mention that the consumption of other products with a good polyphenol content, such as cereals, tea, wine and coffee, also contribute to total polyphenol intake. In this regard, and based on the daily polyphenol intake found in the abovementioned United States population (1000 g/day), the daily consumption of 15 g of the food supplement evaluated in our study contributes more than twice this amount.

Limitations of the present study include the small sample size, the fact that subjects were not excluded based on BMI and insulin levels, and the fact that the food product was administered non-continuously during the intervention period (administration 5 days a week, with two days of rest, during three months). Nevertheless, despite these limitations, our study provides the basis for future research on the preparation, administration and effects of legumes as a dietary supplement upon oxidative stress marker levels and glycemic control.

The daily administration of 15 g of a food supplement based on 6 legumes, during a period of three months, resulted in a significant decrease in blood glucose levels and insulin resistance (HOMA index) in the study sample, with no changes in insulin, hsCRP or the lipid profile, which could be attributed to legume contents referred to isoflavones such as genistein and total fiber. On the other hand, a significant decrease was observed in the levels of MDA, a lipoperoxidation marker associated to OS, which can be attributed to the consumption of 2760 mg of polyphenols of gallic acid (GA) equivalent contained in the daily portion of the product administered to the participants during the intervention. However, further studies involving larger sample sizes are needed to confirm these findings.

Dr. Josefina Ruiz Esparza-Cisneros was involved in the design of the study, the application and processing of the food frequency survey before and after the intervention, the statistical analysis, preparation and administration of the supplement, and in writing and approval of the manuscript.

M.C. Javier de Jesús Vasconcelos-Ulloa participated in the standardization and performance of the laboratory tests (MDA, glucose and lipid profile), the literature search, and the writing of the results.

Dr. Daniel González-Mendoza participated in the quantification of total polyphenols in the dietary supplement and in the analysis of the results.

Dr. Guillermo Beltrán-González participated in the study design and collaborated in the analysis of the results.

Dr. Raúl Díaz-Molina participated in the study design, in standardization and performance of the laboratory tests (MDA, lipid profile, hsCRP, insulin and glucose), blood sample collection from the study subjects, and in writing and approval of the manuscript.

The present study was carried out with financial support from the National Council of Science and Technology of Mexico (Consejo Nacional de Ciencia y Tecnología de México [CONACYT]) through Innovation Stimulation Program 2015 (project no.: 221,394).

The authors declare that they have no conflicts of interest.