1. Introduction
Corn (
Zea mays L.) is part of the biological and cultural heritage of several Latin American countries, including Mexico. It is currently classified into more than 250 breeds on the American continent, while 59 are known in Mexico. A large number of varieties are derived from these breeds, the result of selection and improvement processes carried out by the peasant communities that adopted them thousands of years ago, mainly in the Mesoamerican region [
1]. Phytochemicals of corn have received less attention than these of fruits, vegetables and other grains. The consumption of corn and other whole-grain products has been linked to the reduced risk of chronic diseases including cardiovascular disease, type 2 diabetes, obesity, some cancers and with the improvement of digestive tract health [
2].
Currently, corn is grown in different shapes and kernel shades, such as blue, black, cherry, purple and red, known as pigmented corn. Pigmented corns are those that, unlike white corn, contain phenolic and/or carotenoid compounds (terpenic compounds) in one or more of the kernel structures: pericarp, aleurone and/or endosperm. These terpenic and phenolic compounds (mainly anthocyanins) give the kernels shades ranging from blue–violet to almost black, to red. Pigmented maize is appreciated in the producing communities and is used to prepare traditional dishes; however, it is at risk of disappearing due to the decrease in the cultivation area, its limited use and its low demand as a raw material for corn mills. In view of this, strategies are being sought to conserve them, promote their planting and increase their production in the field [
3].
For this review, the search for scientific articles was carried out in the search engines and electronic bookstores PubMed, Google Scholar, ScienceDirect, Dialnet, SciELO, Latindex, Redalyc, Medigraphic and Elicit using the keywords in English and Spanish: pigmented corn, blue corn, red corn, black corn, pigmented corn and health, pigmented corn and human health, pigmented corn and health benefits, blue corn composition, red corn composition, yellow corn composition, black corn composition, purple corn composition, Zea mays benefits and Zea mays and human health. Additionally, various key words were used to relate the pathologies with the highest prevalence and incidence of the different functional compounds found in pigmented corn. The selection of articles was carried out from December 2022 to January 2024 with the following criteria: (a) articles in English and Spanish published from 1980 to 2023 (this wide time range is due to the low number of scientific articles that clinically study the effects of pigmented corn and their bioactive compounds on human health), (b) original articles, narrative reviews, systematic reviews and systematic reviews with meta-analyses written in English and Spanish, (c) theses and dissertations published in repositories of public and private universities in Spanish, (d) official websites of national and international organizations and public and private universities in Spanish and English and (e) studies directly related to the search objective.
Within the limitations of the review study, the following results were obtained: a reduced number of clinical trials were carried out with bioactive compounds obtained from pigmented corn, most meta-analyses with the reviewed molecules were used on preclinical studies, limited data from meta-analyses with these pigmented corn molecules in clinical studies, wide variability in the reports of the clinical outcomes of the bioactive compounds of interest found in pigmented corn, a lack of information on the adverse effects of several of the bioactive compounds analyzed and a lack of composition studies of pigmented corn. Due to this, we have also decided to use information on bioactive compounds found in corn but extracted from other plant species in order to increase the information shown in this review. This review aims to analyze the clinical evidence of the bioactive compounds found in pigmented corns to encourage readers, researchers and clinicians to study the understudied bioactive compounds derived from pigmented corn.
Table 1 summarizes the bromatological composition of pigmented corn reported by various authors [
4,
5,
6,
7]. In general, the composition among the different pigmented corns, as well as in comparison to white and yellow corns, may present different ranges of variation. Bromatologically, pigmented corn tends to contain a higher percentage of carbohydrates, while proteins and lipids are higher in white corn. Likewise, all macronutrients are lower in yellow corn. Several studies have been conducted on the composition of pigmented corn. In blue corn, the results were as follows: protein 7.99%, crude fat 4.24 g/100 g and fatty acids (g/100 g): palmitic 14.66, stearic 3.53, oleic 41.54, linoleic 38.34 and linolenic 1.15. For red corn: protein 8.20%, crude fat 4.05 g/100 g of corn oil and fatty acids (g/100 g): palmitic 13.48, stearic 3.23, oleic 38.19, linoleic 42.82 and linolenic 0.95 [
8]. It is important to mention that the content of the phytochemicals, micronutrients and macronutrients varies according to the variety of corn, its race (genotype), as well as the season in which it was grown and harvested. This gives each breed and variety a different nutraceutical potential and largely determines its possible uses in the food, pharmaceutical and cosmetic industries, among others.
Pigmented corns contain anthocyanins in different ranges, depending on the breed and variety, which give them colorful colors, as well as carotenoid compounds (carotenes and xanthophylls). These phytochemical compounds give pigmented corn a nutraceutical advantage over white and even yellow corn, despite the latter’s high carotenoid content [
3]. Anthocyanins can be found in the pericarp and aleurone, or only in one of them. Pigments have also been observed in its endosperm [
9]. The location of the pigments is of great importance because it is an indication of the amount of pigments that can be extracted and allows one to decide on the best way to use these compounds without degrading them [
3]. Other groups of compounds found in pigmented corn, although in smaller quantities, are free phenols, non-anthocyanidic flavonoids, ferulic acid, lutein, zeaxanthin, cryptoxanthin, alpha and beta carotenes, among others.
2. Phenolic Compounds and Anthocyanins in Pigmented Corns
Phenolic compounds or polyphenols are compounds resulting from the secondary metabolism of plants, with more than 8000 known molecules [
10]. Although several classifications have been made, the most widely used divides polyphenols into two main families: flavonoids (e.g., chalcones, flavones, flavonols, flavandiols, anthocyanins, condensed tannins and aurones) and non-flavonoids (e.g., free phenols, phenolic acids, polyphenolic ketones, fumarins, chromones, benzofurans, lignans, xanthones, stilbenes and quinones) [
11]. Phenolic acids are a class of secondary metabolites highly distributed in plants. According to their chemical structure, phenolic acids can be divided into benzoic and cinnamic acids. The main benzoic groups are gallic, pro-tocatechinic and
p-hydroxybenzoic acids, mainly as conjugates. Cinnamic acids are widely distributed in plants, as esters or amides. The most representative are caffeic, chlorogenic and ferulic acids [
12].
Table 2 shows the contents of phenolic compounds quantified in corn of different colors, which vary widely from one another. However, pigmented corns, as well as their by-products, tend to contain significantly higher amounts of these compounds [
13]. Phenolic compounds include anthocyanins and anthocyanidins of various types, ferulic acid and phlobaphenes.
Cereals, including corn, are the most important source of ferulic acid, derived from cinnamic acid (intake ranges from 0.092 to 0.32 g) [
14]. Ferulic acid ([E]-3-[4-hydroxy-3-methoxyphenyl] propa-2-enoic acid) belongs to the phenolic acid group, commonly found in plant tissues [
15]. Phenolic acids are secondary metabolites of variable chemical structures and biological properties. The antioxidant mechanism of action of ferulic acid is complex, based mainly on the inhibition of the formation of reactive oxygen species (ROS) or nitrogen, but also on the neutralization of free radicals. In addition, this acid is responsible for chelating protonated metal ions, such as Cu(II) or Fe(II) [
16]. Ferulic acid is not only a free radical scavenger, but also an inhibitor of enzymes that catalyze the generation of free radicals and an enhancer of the activity of scavenger enzymes. It is directly related to its chemical structure. It has also been shown to have lipid peroxidation inhibitory activity [
17]. Ferulic acid has low toxicity and possesses many physiological functions, including anti-inflammatory, antimicrobial, anticancer (e.g., lung, breast, colon and skin cancer), antiarrhythmic and antithrombotic activity. It also demonstrated anti-diabetic effects and immunostimulant properties, as well as reduced nerve cell damage, and may help repair damaged cells. [
18].
Ferulic acid has been shown to have an angiogenesis effect by affecting the activity of the main factors involved, i.e., vascular endothelial growth factor (VEGF), platelet-derived growth factor (PDGF) and hypoxia-inducible factor 1 (HIF-1) [
18]. In research with human umbilical vein endothelial cells, ferulic acid has been shown to enhance VEGF and PDGF expression and increase the amount of hypoxia-induced HIF-1, which generates responses to hypoxia [
19]. Ferulic acid appears to be an effective substance that promotes the formation of new vessels, as demonstrated in in vivo and in vitro studies [
20].
It is important to note that in corn, ferulic acid can be found bound to arabinoxylans, a class of carbohydrates consisting of arabinoses and xyloses, both five-carbon monosaccharides (pentoses) [
16]. Several studies have shown that dietary supplementation with cereal-derived arabinoxylans improves the antioxidant capacity of intestinal epithelial cells due to the production of ferulic acid and short-chain fatty acids (SCFA) from microbial fermentation. Ferulic acid may co-operate with SCFA to regulate intestinal integrity and host immune functions. Peroxisome proliferator-activated receptor γ (PPARγ) may play an important role in the integration of ferulic acid and SCFA to regulate host health and metabolism [
21]. In other studies, ferulic acid has been shown to combine with arabinose residues in cereal-derived arabinoxylans, but gut microbiota ferment arabinoxylan to release free ferulic acid, as well as SCFA production [
22]. It has also shown that as one of the phenolic acids it has a strong antioxidant capacity to scavenge reactive oxygen species (ROS) and enhance anti-oxidant activity through the activation of the Kelch-like ECH-associated protein 1 and nuclear factor E2-related factor 2 (Keap1-Nrf2) signaling pathway [
23]. Therefore, the pericarp of pigmented corn, rich in ferulic acid, could be metabolized by the intestinal microbiota of humans, generating a release of ferulic acid bound and conjugated into free ferulic acid, in a manner similar to thermal, acidic and alkaline processes.
Another phenolic compound found in some pigmented corn, specifically in the red breeds and varieties, is phlobafen. These are condensed tannins of a high molecular weight, coming from the union of several molecules of naringenin and eriodictyol joined by the central ring. They are oxidized, hardly soluble in water—probably due to the abundance of methoxyl groups in their structure—and present a reddish-brown color. There are also phlobaphenes composed of a mixture of polymeric procyanidins, dihydroquercetin, carbohydrate (glucosyl) and methoxyl moieties [
24]. In the case of red corn, these accumulate in the pericarp of the seed and the glumes of the cob. A study showed that they are related to the thickness of the pericarp of red corn (the higher the amount of phlobafen, the thicker the pericarp) [
25]. It is speculated that they could have beneficial effects on human health due to their high antioxidant capacity; however, up to this moment there are no clinical trials that confirm this effect. The biological effects of phlobafen are still unknown, so there is a great opportunity for future research to elucidate the effects of these phytochemicals and their biological activity in human physiology.
In order to identify pigmented corn with nutraceutical potential, a study analyzed the content of secondary metabolites, phenolic compounds, the antioxidant capacity and the antimutagenic activity of red and blue corn. The ranges of the total phenol, flavonoid and anthocyanin contents of the corn samples were 69.4 to 212.8 mg gallic acid eq./100 g DW (dry weight), 0.07 to 12.19 mg (+) catechin eq./100 g DW and 3.89 to 34.17 mg cyanidin-3-O-glucoside eq./100 g DW, respectively [
26,
27]. The phenolic extracts demonstrated the highest antioxidant capacity, evaluated by the ABTS assay, showing values from 2.06 to 7.34 mmol Trolox (vitamin E equivalents)/100 g DW. The total phenol and anthocyanin contents correlated with the observed antioxidant capacity. The corn samples with the highest biological activity were those with a blue color, while the least active were those with a red color. The results showed that the blue corn samples studied are good sources of antioxidant and antimutagenic compounds that could be used to develop products that contribute to human health [
26,
27].
One of the most important flavonoids are anthocyanins. These are water-soluble pigments, abundant in nature, which can be found in vegetables, fruits, flowers and grains. Chemically, they are glycosides of anthocyanidins, i.e., they consist of an anthocyanidin molecule to which a sugar is attached by a β-glucosidic bond. Anthocyanins can be formed from two metabolic biosynthetic pathways: the shikimate pathway to produce the amino acid phenylalanine and the malonyl-CoA pathway (polyacetates or acetyl-CoA pathway) [
28]. In purple corn kernels, as in wheat and barley, anthocyanins are found in the pericarp, while in blue varieties they are found in the aleurone layer [
29]. In black and dark red grains, anthocyanins are found in both the aleurone and pericarp layers [
30,
31].
Table 2 summarizes the content of phenolic compounds and anthocyanins in various presentations of corn of different colors [
8,
13,
32].
Table 2.
Ranges of phenolic compounds and anthocyanins content in various presentations of corn of different colors [
8,
13,
32].
Table 2.
Ranges of phenolic compounds and anthocyanins content in various presentations of corn of different colors [
8,
13,
32].
Parameters |
Blue Corn
|
Corn High in Carotenoids
|
Red Corn
|
White Corn
|
Yellow Corn
|
---|
Free phenols (mg GAE/100 g) |
39.1–45.5
|
40.3–53
|
26.4–38.2
|
34.7–47.2
|
41.5–51.1
|
Bound phenols (mg GAE/100 g) |
95.5–220.7
|
108.6–270.1
|
85.3–205.6
|
97.3–226
|
102.1–242.2
|
Free ferulic acid (µg/100 g) |
683–17,587
|
970–21,566
|
588–8202
|
455–9988
|
645–17,462
|
Conjugated ferulic acid (µg/100 g) |
1451–31,746
|
1965–37,743
|
1259–29,391
|
756–15,588
|
1474–27,827
|
Bound ferulic acid (µg/100 g) |
23,330–127,851
|
40,610–150,077
|
22,865–128,450
|
20,470–119,201
|
44,527–100,849
|
Total anthocyanins (mg CGE/100 g) |
2.63–6.87
|
0.56–4.63
|
2.08–9.75
|
0.28–1.33
|
0.29–0.57
|
The daily intake of flavonoids and anthocyanins has been reported to be around 200–250 mg/day [
33], while the Food and Drug Administration and NHANES (National Health and Nutrition Examination Survey of the United States) have set it at 12.5 mg/day/person [
34,
35,
36,
37,
38].
Several in vitro assays, animal and human cell line studies, animal models and human clinical trials indicated that the consumption of anthocyanin-rich foods (among which are pigmented corn), beverages and supplements provides numerous health benefits. In fact, this is due to the easy ability of anthocyanins to scavenge and/or neutralize free radicals and reactive species, chelate metals, control signaling pathways, decrease pro-inflammatory markers and thus reduce the risk of cardiovascular pathologies, cancer and neurodegeneration [
39].
Anthocyanins have demonstrated antioxidant potential in both in vitro [
40] and in vivo studies [
41] and the consumption of anthocyanin-rich foods has been linked to lower risks of chronic diseases [
42,
43,
44]. There are several mechanisms of action through which anthocyanins could exert their biological effects on human health, among which is the activation of nuclear factor erythroid 2 (Nrf2). It serves as a transcription factor for the expression, transcription and translation of the antioxidant response element (ARE), which encodes for several antioxidant enzymes, including superoxide dismutase (SOD), glutathione peroxidase, catalase, etc., [
45]. Another way in which anthocyanins exert their antioxidant power is by donating hydrogenions, thus reducing a large number of pro-oxidant molecules, as well as neutralizing various free radicals. This is due to the hydroxyl groups in anthocyanins, which usually contain between two and three of these. The last mechanism described by which they can exert an antioxidant and thus anti-inflammatory effect is through the chelation of metals and metalloids, mainly transition metals such as iron (Fe), copper (Cu), nickel (Ni), aluminum (Al), cadmium (Cd) and arsenic (As), as well as their respective valence forms [
31]. The anthocyanins identified in several varieties of peruvian pigmented corns are cyanidin-3-glucoside, pelargonidin-3-glucoside, peonidin-3-glucoside, cyanidin-3-(6″ malonylglucoside) and cyanidin-3-(3″,6″-dimalonylglucoside) [
30].
Delphinidin, a type of anthocyanidin that can act as a precursor of many anthocyanins, shows the most considerable ability to scavenge superoxide species, followed by petunidin > malvidin = cyanidin > peonidin > pelargonidin, at 1 µM. Similar results were obtained for the ability of these compounds, at the same concentration, to scavenge peroxynitrite radicals [
46]. In addition, cyanidin 3-
O-glucoside at concentrations between 100 and 200 µM showed potential to protect human keratinocyte HaCaT cells against ultraviolet-A radiation, preventing DNA fragmentation and hydrogen peroxide (H
2O
2) release [
39,
47]. In one study, 12 healthy participants who consumed one of two beverage options high in anthocyanins and anthocyanidins, composed of 165.9 mg/L and 303.8 mg/kg of anthocyanins, respectively, showed increases in their plasma antioxidant capacity by 3-fold and 2.3-fold, respectively [
48].
Anthocyanins decrease plasma low-density lipoproteins (LDL), leading to a reduction in their accumulation in the walls of medium and large arteries [
49]. Thus, anthocyanins indirectly inhibit LDL-promoted endothelial cell activation/dysfunction. Endothelial damage affects the nitric oxide (NO) release which, together with the increased local degradation of NO by the increased generation of reactive oxygen species (ROS), decreases NO availability. Anthocyanins can increase NO availability by several mechanisms. After activation, the endothelium begins to express cell adhesion molecules on its surface (ICAM-1, intercellular adhesion molecule-1 and VCAM-1, vascular cell adhesion molecule-1) to recruit circulating monocytes to the site of oxidized LDL (oxLDL) accumulation. Anthocyanins downregulate the expression of these adhesion molecules [
50]. On the luminal side, anthocyanins decrease chemokines (CK), which also results in decreased myeloid cell recruitment. Anthocyanins counteract ROS on both the luminal and intimal sides, reducing LDL oxidation in the vessel wall [
51]. During the progression of atherogenesis, neutrophil-derived granular proteins stimulate macrophage activation to a proinflammatory state that can be inhibited by anthocyanins [
52]. Both the antioxidant and anti-inflammatory effects of anthocyanins decrease foam cell formation. Anthocyanins also lower cholesterol by reducing its accumulation in the lipid-rich necrotic core [
41]. During the late stages of atherosclerosis, anthocyanins reduce the expression of Toll-like receptor 2 (TLR2) signaling in endothelial cells that regulate the neutrophil stimulation of stress and endothelial cell apoptosis [
53]. Regarding anthocyanin-enriched fractions of natural products, extracts of blackberries, blueberries, strawberries, sweet cherries and red raspberries at 10 µM showed the potential to inhibit human LDL oxidation, having been twice as effective as an ascorbic acid control [
39,
54]. Blackberry and raspberry fruits also revealed lipid peroxidation inhibitory potential, showing IC
50 values below 50 µg/mL [
55].
Anthocyanins are also involved in the regulation of the inflammatory status and activation of endogenous antioxidant defenses, as well as in the regulation of the immune system through MAPK-, NF-κB- and JAK-STAT-related signaling pathways [
50]. The effects of anthocyanins on inflammatory markers are promising and may have the potential to exert anti-inflammatory biological action in vitro and in vivo. Therefore, translating these research findings into clinical practice would effectively contribute to the prolonged maintenance of a healthy state. A review study summarized the results of clinical studies from the last five years in the context of the anti-inflammatory and antioxidant role of anthocyanins in a health state as preventive agents and concluded that there is evidence indicating that anthocyanin supplementation in the regulation of proinflammatory markers among the healthy population is highly functional, although inconsistencies between the outcome of randomized controlled trials (RCTs) and meta-analyses were also noted. Regarding the effects of anthocyanins on inflammatory markers, there is a need for long-term clinical trials with large cohorts that allow the quantifiable progression of inflammation [
56].
In another study, different anthocyanin dilutions (concentrations of 100, 150 and 200 µg/mL) showed the ability to reduce the expression levels of cyclooxygenase-2 (COX-2), inducible nitric oxide synthase (iNOS), IL 1β and IL -6 and to suppress AP-1 signaling and nuclear factor kappa B (NF-kB) pathways [
57]. It was also verified that, at concentrations of 10, 25 and 50 µg/mL, they can decrease the phosphorylation of IKK, IkBa, p65 and JNK, prevent the nuclear translocation of p65 in RAW 264.7 macrophage cells stimulated with LPS/IFN-γ and inhibit lipoxygenase activity [
58]. These biological activities demonstrate the direct and indirect antihypertensive, anti-inflammatory endothelial vasodilator enhancement and modulation of inflammasome activation, as well as other signal transduction pathways related to the immune response.
In another study, the phenolic profile and associated antioxidant properties of corn samples with different pigmentations were characterized using spectrophotometric and chromatographic techniques and the stability of anthocyanins during gastrointestinal digestion was evaluated. Pigmented varieties showed a significantly higher anthocyanin content compared to common yellow varieties and, as a consequence, higher antioxidant activity. However, although corn is among the cereals mostly used in gluten-free products, it can produce an inflammatory response in some people with gluten intolerance. Therefore, after chemical characterization, the safety of pigmented varieties for patients with gluten intolerance was confirmed by different in vitro models (a cell agglutination test and measurement of transepithelial electrical resistance). Although in vivo studies are necessary, the data collected in the aforementioned study underline that pigmented corn could play a role in reducing oxidative stress at the intestinal level [
59]. Cellular assays applied in another study confirmed the absence of alterations by pigmented strains in the permeability of the cell monolayer, a key step in the mucosal inflammatory cascade in various intestinal disorders [
60]. Considering the daily consumption of corn and the high content of anthocyanins in pigmented corn, these varieties could contribute antioxidant and anti-inflammatory ingredients to the diet of the general population, but in particular, of people with gastroenteric disorders since corn represents one of the most important ingredients among the cereals used in the formulation of gluten-free products [
61].
In a study, monomeric anthocyanin contents and antioxidant activity were determined by DPPH and TBARS methods, as well as the in vitro antiproliferative activity of blue corn and blue corn tortillas. The tortilla anthocyanin profile was obtained by HPLC-ESI-MS. The antiproliferative activity of the tortilla and blue corn extract on human cell lines Hep-G2 (hepatocellulatar carcinoma), H-460 (lung cancer), HeLa (cervical cancer), MCF-7 (breast cancer) and PC-3 (prostate cancer) was evaluated by an MTT assay [
62]. Blue corn had a higher monomeric anthocyanin content, as well as a lower percentage of polymeric color than the tortilla; however, both showed similar antioxidant activity by DPPH. Also, although higher anthocyanin degradation was observed in the tortilla extract, both extracts inhibited lipid peroxidation (IC50) at a similar concentration. The anthocyanin profile showed 28 compounds derived mainly from cyanidin, including acylated anthocyanins and proanthocyanidins. Blue corn and tortilla extracts showed antiproliferative effects against HepG2, H-460, MCF-7 and PC-3 cells at 1000 μg/mL; however, Hela cells had higher sensitivity at this concentration [
62]. Anthocyanins activate the MAPK molecular signaling cascade, in turn activating MEKK1/4, which in turn activates MKK3/6, resulting in the activation of the nuclear transcription factor p38 [
63].
Another trial described some red and blue pigmented maize in terms of their secondary metabolite content and antioxidant and antimutagenic properties. High concentrations of ferulic acid were found for both red and blue corn, while the cyanidin-3-O-glucoside content was prominent for blue corn. Likewise, blue corn samples proved to be good sources of antioxidant and antimutagenic compounds, mainly those belonging to anthocyanins. These pigmented maize can be considered for scaling up production to obtain natural dyes, bioactive extracts for pharmaceutical and cosmetic applications and maize-based products that contribute to human health [
26].
There is some evidence from in vitro, animal and human studies supporting the beneficial effect of cereal-based anthocyanins on a variety of health outcomes such as obesity, diabetes, aging, cancer and cardiovascular disease (
Table 3). However, more research is needed to determine the true effects of anthocyanins in humans. In addition, most studies used purified extracts to the test health effects. However, this is an unrealistic means of consuming cereal-based anthocyanins. More trials are needed to elucidate the effect of anthocyanin consumption within a matrix of processed cereals, including those made from pigmented corn [
31].
Table 3 shows the most studied biological effects of phenolic compounds and anthocyanins found in pigmented corn in humans, based on clinical trials and systematic reviews with meta-analyses.
3. Carotenoids in Pigmented Corn
Carotenoids are organic pigments of the isoprenoid group found naturally in plants and other photosynthetic organisms such as algae, some kinds of fungi and bacteria; they belong to the group of terpene compounds or terpenoids, being tetraterpenes. More than 700 compounds belonging to this group are known to exist [
70]. Various carotenoids, both carotenes and xanthophylls, are present in pigmented corn, being found in greater quantities in yellow corn [
4].
Lutein and zeaxanthin belong to the xanthophyll family of carotenoids, pigments produced by plants. Key sources of these carotenoids include kale, collard greens, spinach, broccoli, peas, parsley, corn and egg yolks. Yellow corn is rich in carotenoids (up to 823 μg/100 g DW corn) including lutein (50%), zeaxanthin (40%), β-cryptoxanthin (3%), β-carotene (4%) and α-carotene (2%) [
2,
71]. The recommended daily intake of lutein is approximately 10.0 mg, while that of zeaxanthin is 2 mg. Lutein intake in adults varies, with an average intake of 1–2 mg/day. Due to the lack of synthesis of the intake of these compounds in humans, these substances are extremely important for the proper functioning of certain organs of the body (eye, skin, heart, intestines, etc.).
Maize presents a higher carotenoid content compared to non-corn cereals, with zeaxanthin as the dominant carotenoid [
72]. The protective effects of carotenoids are mainly related to their defense against oxidative stress and their ability to scavenge free radicals. Lutein and zeaxanthin are the only dietary carotenoids that accumulate in the retina, specifically in the macula, and are called macular pigments. These carotenoids are concentrated by the action of specific binding proteins such as StARD3, which binds lutein, and GSTP1, which binds zeaxanthin and its dietary metabolite, mesozeaxanthin. It has been shown that supportive therapy with lutein and zeaxanthin may have a beneficial effect in delaying the progression of eye diseases such as age-related macular degeneration (AMD) and cataracts [
73].
The possibility of using modern research techniques may provide new evidence for the effective role of lutein and zeaxanthin in the etiology of age-related macular degeneration (AMD). So far, treatment options for the dry form of AMD are limited and all efforts are limited to inhibiting progression to advanced forms of this degeneration, i.e., geographic atrophy and exudative form. The AREDS 2 study, conducted between 2006 and 2012, developed a dietary supplement formulation that can reduce the risk of progression to advanced forms at certain stages of the disease. This risk is reduced by about 25% in people with moderate disease in both eyes or moderate disease in one eye and advanced disease in the other eye. The research continues on other treatments for dry AMD, including methods using nanosecond laser-2RT, orally administered drugs (emixustat) or intravitreal preparations (lampalizumab, sirolismus, pegcetacoplan, etc.) [
74,
75,
76]. So far, the results of the use of these forms of therapy are not satisfactory. Other forms of treatment, independent or complementary, are also being sought. The effects of inhibiting other growth factors, such as angiopoietin (Faricimab) [
77], the use of a Port Delivery System (PDS) with ranibizumab [
78] and gene therapy [
79] are being tested. It appears that in aging retinal tissue, the inhibition of the endogenous antioxidant capacity, marked by a decrease in macular xanthophylls (lutein, zeaxanthin and mesozeaxanthin), is an important factor contributing to the progression of AMD. The use of adjuvant therapy with carotenoid phytochemicals in clinical treatment algorithms for AMD appears to be warranted. It has been shown that adjunctive therapy with carotenoid phytochemicals not only provides neuroprotection, but may also have a beneficial effect on treatment strategies at any stage of AMD, even in advanced AMD [
73].
Table 4 shows the most studied biological effects of carotenoids found in pigmented corn in humans, based on clinical trials and systematic reviews with meta-analyses.
4. Bioactive Peptides and Inflammation
Bioactive peptides (BPs) are generally a group of peptides, in most cases consisting of less than 50 residues, that have a function in a living organism or cell. Although some of these peptides are in naked form, many of them are hidden in the intact structure of protein molecules [
85]. The content of BP chains in most cases comprises the amino acids proline, arginine and lysine, together with hydrophobic residues [
86]. In terms of quantity, the protein content of maize kernels is composed mostly of prolamins or zeins (40%), followed by glutelins (30%), with globulins and albumins found in lesser quantities (5%) [
87,
88]. Zeins are mainly found in protein bodies in the rough endoplasmic reticulum and constitute ~44–79% of maize endosperm proteins. Zeins are devoid of lysine and tryptophan, amino acids that are essential for human survival [
88].
From a structural point of view, there is no consensus on the architecture of BPs [
89]. They are classified into two main types: endogenous and exogenous peptides. Endogenous peptides are produced in different cell types, such as neural cells (analgesic/opioid application) or immune cells (role in inflammation and antimicrobial), or in various glands throughout the body, such as the pituitary and adrenal glands. Exogenous peptides enter the body from various sources, such as food, dietary supplements and drugs [
86,
90]. Notably, certain activities have recently been discovered in plant-derived peptides that may perform important functions in humans; among these benefits are anti-diabetic, immunomodulatory, antimicrobial, hypocholesterolemic, opioid, antihypertensive and antioxidant activities [
86].
The presence of hydrophilic amino acids such as proline, alanine, valine and leucine in the N-position and the amino acids tyrosine, valine, methionine, leucine, isoleucine, glutamine and tryptophan in the C-terminal position was associated with the antioxidant properties of peptides [
91]. In addition, liposoluble free radicals (peroxyl radicals) produced during the oxidation process of unsaturated fatty acids are neutralized by hydrophobic amino acids such as leucine, valine, alanine and proline [
92]. Amino acids such as histidine, tyrosine, methionine and cysteine inactivate free radicals by providing them with protons. Aromatic amino acids (phenylalanine, tryptophan and tyrosine) convert free radicals into stable molecules by providing them with electrons [
86,
93].
Most food-derived antioxidant peptides include hydrophobic amino acids such as valine or leucine at the N-terminal end and proline, histidine, tyrosine, tryptophan, methionine and cysteine in their sequence. Hydrophobic amino acids such as valine or leucine can increase the affinity of peptides in the fatty phase, thus facilitating access to free radicals produced in the fatty phase [
86,
94].
A wide range of plant-derived peptides can help diabetics through a variety of pathways. The pathways that have been studied so far include inhibitory properties on alpha-amylase, dipeptidyl peptidase IV, the glucose transporter system and mimicking insulin activity [
86,
95].
Antimicrobial peptides are probably involved in all stages of host defense. Apart from enhancing the immune response, these compounds prevent uncontrolled inflammation by suppressing proinflammatory responses. Despite the specific overlap, antimicrobial peptides interact with each other, complementing each other to guide effective cells to the site of inflammation and modulate the local immune response [
96]. Phagocytes, neutrophils and monocytes adsorb through alpha-defensins, human neutrophil peptides 1HNP1-3 and beta-defensins such as human β-defensins 2hBD3 and 3hBD4, whereas mast cells adsorb through HNP1-3, LL-37 and 4B. Likewise, hBD1 and hBD3 are chemotactic for immature dendritic cells and memory T cells [
86].
Different bioactive peptides have been identified in various corn breeds with antioxidant, antihypertensive, hepatoprotective, alcohol (ethanol) metabolism facilitator, anti-inflammatory, anticancer, antimicrobial and dipeptidyl peptidase IV inhibitor (antidiabetic activity) activities [
97].
The suggested mechanism of action of maize peptides on liver health encompasses the inhibition of NF-κB, Fas, FasL and caspase 3, resulting in a decrease in the apoptotic process in structural and functional liver cells, thus preventing liver damage that could progress to liver injury. A role of corn bioactive peptides in the activation of Bcl-2, which inhibits apoptosis, has also been elucidated. Corn peptides could also increase the levels of endogenous enzymatic antioxidants such as superoxide dismutase (SOD), reduced glutathione (GSH) and glutathione peroxidase (GPx), which would reduce the proinflammatory environment in the liver, as well as in other organs and systems. This is due to their ability to neutralize and inhibit reactive oxygen species (ROS) with proapoptotic and pyroptotic potential [
97].
Bioactive peptides from different maize species can also facilitate ethanol and other alcohol metabolisms by activating the MEOS-CYP2E1 (Microsomal Alcohol Oxidation System–cytochrome P2E1) enzyme complex, which includes the enzyme alcohol dehydrogenase, as well as enhancing and increasing the availability of NAD. All this would lead to a higher conversion of alcohols into acetate (a two-carbon fatty acid), which can be easily metabolized by the liver without generating ROS or damage to Kupffer cells [
97].
The anti-inflammatory activity of corn bioactive peptides is important, which is also closely related to their antimicrobial capacity. Some peptides obtained by the cleavage of corn proteins, mainly zein (a prolamin similar to gluten gliadin), have demonstrated a TNF-α (tumor necrosis factor alpha) inhibitory capacity, which would generate an inhibition in the expression of ICAM-1 (intercellular adhesion molecule 1), MCP-1 (monocyte chemotactic protein 1) and VCAM-1 (vascular cell adhesion protein 1), which are protein molecules related to inflammation and various pathologies of the cardiovascular system, including atherosclerosis. All this would lead to a decrease in macrophage adhesion to the epithelium, as well as a decrease in proinflammatory interleukins such as IL-1 and IL-6, since an efficient inflammatory response could not be mounted. There would also be a decrease in the cyclooxygenase-2 (COX-2) pathway, so there would be a decrease in the production of proinflammatory leukotrienes, prostaglandins and thromboxanes, as well as an infra-regulation in the expression of resistin. It is worth mentioning that this signaling cascade would also decrease the nitrosative stress caused by the nitric oxide pathway. The modulation of these proinflammatory pathways has a beneficial systemic effect in different diseases, among them: metabolic endotoxemia generated by the passage of lipopolysaccharides (LPS), originating from the membrane of the resident Gram-negative bacteria of the intestinal microbiota, into the systemic circulation; type 2 diabetes mellitus; various nephropathies; liver diseases; cancer; severe acute inflammatory syndromes; dyslipidemias; cardiovascular and cerebrovascular diseases; among other conditions [
88,
97].
Bioactive peptides can cross the intestinal lumen by various mechanisms; the mechanism used depends mainly on the length of the peptide (the amount of amino acid residue), as well as its electrical charge. Among the transport mechanisms in the intestinal lumen are passive transport (by concentration gradient in free amino acids), proton transport coupled to PepT1 (used by dipeptides and tripeptides), sodium transport coupled to SOPT1 and 2 (used by peptides of five or more amino acids), transcytosis (used by decapeptides and longer peptides) and paracellular transport (used by free amino acids and peptides of four to nine amino acid residues) [
88,
97]. However, much remains to be elucidated regarding their transport, distribution and metabolism mechanisms. The study of bioactive peptides obtained from corn is in its early stages; therefore, further characterization of these bioactive peptide compounds is needed.
Table 5 shows the most studied biological effects of bioactive peptides in humans from clinical trials and systematic reviews with meta-analyses.
5. Resistant Starches and Inflammation
Resistant starch (RS) is a linear or branched polysaccharide consisting of glucose molecules linked by glycosidic bonds, which is resistant to digestion by human amylase enzymes; it is often considered a type of dietary fiber. It is among the recent focuses of non-digestible carbohydrate therapies. Boosting intestinal butyrate production has been the focus of several RS intervention studies associated with aging [
103], insulin resistance [
104], metabolic syndrome, kidney disease [
105] and schizophrenia [
106] and may be especially relevant for diseases characterized by dysregulated epithelial integrity and immune function, such as inflammatory bowel disease [
107]. The surface microstructure of a starch is the main factor affecting its digestibility. The relative amylose content, amylopectin branched chain density and crystallinity appear to influence the size, type and packing density of the blocks, which then determine the texture and porosity of the granule surface. Retrogradation and cross-linking modify starch surface crystallinity and intermolecular networks, respectively, which increases resistance to hydrolysis. It is unclear whether the blocks simply affect the surface area and integrity or whether they constitute “discrete structures” [
108] that complement amylase active sites. These questions relate to whether different bacteria preferentially degrade certain starches more than others based on binding site availability or the recognition of discrete microstructures [
109].
Resistant starch (RS) is a common natural component of several types of foods, including pigmented and unpigmented corn, which can be classified into four based on their physical and chemical characteristics. RS1, which is generally found in whole grains and legumes, is a starch trapped in a non-digestible matrix [
110]. RS2 refers to non-gelatinized starch granules, such as starch from raw potato and high-amylose corn starch. Traditional corn starch is composed of 25% amylose and 75% amylopectin and resistant starch (1.4–39.4%) varies greatly among corn breeds [
111]. High-amylose corn is rich in amylose (up to 70% of all carbohydrates) [
2]. The FDA has approved Hi-Maize resistant starch (produced naturally from modified high-amylose corn) for use in patients with type 2 diabetes [
112]. RS3 consists of starch that has already undergone retrogradation (starch is cooled after gelatinization). RS4, found in bread, includes starch that is chemically modified by the addition of ester or ether groups. RS is found in considerable amounts in pigmented corn, depending on the breed, variety and the processing the corn has received [
109]. The correlation between SR consumption, gut health, inflammatory markers, insulin response and lipid metabolism has been well documented [
113].
RS should be considered for elderly diets because it can increase the population of beneficial bacteria and butyrate production according to multiple studies. In a serial study, MSPrebiotic
® (Carberry, Canada), a commercial RS containing 70% RS2, promoted bifidobacteria growth and ameliorated dysbiosis related to high proteobacteria abundance in subjects ≥70 years old [
103]. Consequently, changes in the levels of inflammatory markers (IL-10, C-reactive protein and TNF-α) in blood were observed. However, other research has shown that although RS was able to reduce dysbiosis in the elderly, the inflammatory levels remained elevated at the end of the study [
113,
114].
Beneficial effects of RS were also found in a study with 18-month-old mice that reported therapeutic effects of RS2 against high-fat-diet-induced and aging-related dysfunctions [
112]. According to this study, RS2 effectively decreased the expression of systemic endotoxemia and proinflammatory cytokines, as evidenced by lower levels of serum and fecal lipopolysaccharide (LPS), which are endotoxic components in the cell membrane of Gram-negative bacteria that induce an inflammatory response mediated by colonic IL-2 and hepatic IL-4, among others. This corroborated the anti-inflammatory properties of RS2 against chronic low-grade inflammation related to aging. RS2 also improved the intestinal barrier function, which was characterized by the increased expression of colonic type 2 mucin at both mRNA and protein levels. Similarly, this study revealed that RS2 reduced the abundance of pathogenic taxa associated with obesity, inflammation and aging, such as
Desulfovibrio (phylum
Proteobacteria),
Ruminiclostridium,
Lachnoclostridium,
Helicobacteria,
Oscillibacter,
Alistipes,
Peptococcus and
Rikenella [
112,
113].
Table 6 shows the most studied biological effects of retained starches in humans, based on clinical trials and systematic reviews with meta-analyses.