The Hidden Players in Multiple Sclerosis Nutrition: A Narrative Review on the Influence of Vitamins, Polyphenols, Salt, and Essential Metals on Disease and Gut Microbiota

Vitamin A, also called retinol, can be obtained through the diet in various forms, such as all-trans retinol, retinyl esters, or β-carotene. It is mainly present in oily fish, liver, eggs, cheese, and butter; following adsorption, it is metabolized into all-trans retinoic acid (RA), which represents the biologically active form of Vitamin A [75,76]. Starting from the observation that CD103⁺ gut-associated dendritic cells (DCs) are capable of synthesizing RA, it is known that RA promotes the differentiation of forkhead box P3 (Foxp3⁺) regulatory T cells and Th2 cells, as well as the induction of IgA-secreting antibody-secreting cells and the inhibition of intestinal Th17 cells [77,78,79], mechanisms involved in MS pathogenesis. Moreover, RA is reported to increase the production of IL-10 by B cells in pwMS [26].

Several studies reported a relation between RA and EAE. Indeed, RA appears to be able to suppress EAE [24], and co-supplementation of vitamins A and C was demonstrated to mitigate neurological severity and EAE disease progression [25].

In pwMS, retinol levels have been reported to be lower than in controls or people without non-inflammatory neurological diseases [54,80]. Moreover, increased serum retinol levels appear to correlate with a reduced risk of developing gadolinium-enhancing T1 lesions, T2 lesions, and active lesions, and its concentrations have been shown to predict the appearance of new gadolinium-enhancing T1 lesions and new T2 lesions up to six months in advance [27]. All this evidence suggests a role of Vitamin A deficiency in MS disease activity and progression.

In parallel, RA supplementation has shown beneficial effects on the health of pwMS. Vitamin A indeed was reported to improve MS functional composite (MSFC) in RRMS patients, even if no significant changes were observed for the Expanded Disability Status Scale (EDSS), brain lesions, and relapse rate [28]. Furthermore, Vitamin A supplementation improved fatigue and depression and psychiatric outcomes [29]. On the contrary, focusing on the Vitamin A that derives from carotenoids, current evidence does not support the hypothesis that dietary intake of carotenoids reduces the risk of developing MS in women [56].

Vitamin C, also known as L-ascorbic acid, is an essential vitamin found mainly in fruits and vegetables, particularly in oranges, kiwifruit, strawberries, broccoli and red and green peppers [95]. It exhibits significant antioxidant activity by limiting damage caused by free radicals, and plays a crucial role in the biosynthesis of certain neurotransmitters and in immune function [95]. In mice, administration of ascorbic acid did not affect the clinical course of pre-existing EAE and also had only moderate effects on the development of clinical symptoms, and failed to prevent the opening of the blood–CNS barrier [53]. Moreover, supplementation with Vitamin C in combination with Vitamin A was able to mitigate neurological severity and disease progression in EAE. Specifically, a significant reduction in demyelination, inflammation, immune cell infiltration, and activation of microglia and astrocytes has been observed following co-supplementation with these two vitamins [25]. In MS, it has been reported that serum ascorbic acid levels were significantly lower in pwMS during a relapse compared to healthy controls [54]. This finding was further confirmed by another study conducted on an Egyptian population, in which Vitamin C levels in pwMS were significantly lower than those in controls. Additionally, patients with infratentorial lesions exhibited markedly lower ascorbic acid levels than those without such lesions [55]. At the same time, a study investigating the impact of Vitamin C supplementation on the risk of developing MS reported that the intake of Vitamin C, as well as Vitamin E and multivitamin supplements, did not reduce the risk of MS onset [56].

Vitamin D, also known as calciferol, is certainly one of the most widely discussed vitamins in relation to its role in MS. It is found in only a few foods but is also produced endogenously when ultraviolet (UV) rays from sunlight reach the skin and stimulate Vitamin D synthesis [96]. Within the body, it plays several important roles, including maintaining adequate calcium and phosphate levels, as well as contributing to the reduction of inflammation and the modulation of immune and neuromuscular function [96]. Moreover, the actions of Vitamin D on neuronal and immune cells within the central nervous system are particularly intriguing, as they support neuron survival by lowering proinflammatory cytokine levels and enhancing the production of neurotrophic factors [63]. The interest in the potential role of Vitamin D in MS arises from several studies suggesting both a link in the development of the disease and a prognostic role [63]. A lower prevalence of MS in countries with higher exposure to UV radiation and in those with greater consumption of Vitamin D-rich oily fish was observed [16]. Starting from the mice model of MS, one study revealed that both Vitamin D and the Vitamin D receptor are required for EAE development [57]. Conversely, another study reported that Vitamin D3, the most physiologically relevant form of Vitamin D, is capable of inhibiting the differentiation and migration of Treg and Th17 cells, thereby protecting against EAE development. These findings suggest that Vitamin D3 may represent a potential preventive therapeutic strategy for Th17-mediated autoimmune diseases [58]. Although much of the research has focused on the general role of Vitamin D in the development of MS [16], some studies have specifically investigated the effects of Vitamin D obtained through diet or supplementation. A study conducted on 187,000 women found that those with a higher dietary intake of Vitamin D had a 33% lower incidence of MS than those with lower intake. Similarly, women who used Vitamin D supplements had a 41% reduced risk of developing MS compared to non-users [59].

Another study conducted on 25 pwMS revealed that supplementation with Vitamin D3 was able to increase IL-10 levels across all groups analyzed, with a more pronounced effect observed in patients with MS [60]. A meta-analysis published in 2024 compared the results of clinical trials conducted up to 2022 that investigated the effects of Vitamin D3 supplementation on clinical outcomes in pwMS. Analysis of nine studies revealed that Vitamin D3 supplementation did not significantly reduce either EDSS scores or the occurrence of new T2 lesions, even if supplementation may still provide long-term clinical benefits [61]. A randomized clinical trial conducted on 303 patients found that oral high-dose Vitamin D was able to reduce disease activity in CIS and in early RRMS [62]. Finally, lower Vitamin D was linked with worse information processing speed performances in newly diagnosed MS [63] and its supplementation could be beneficial on cognition [64].

Vitamin E, also known as tocopherol, is a vitamin that exists in eight different chemical forms and is well known for its antioxidant properties, which allow it to inhibit the production of reactive oxygen species (ROS) generated during lipid oxidation. In addition to its antioxidant role, Vitamin E is also involved in immune function and other biological processes [97]. Moreover, Vitamin E is present in several foods, mainly in nuts, seeds, vegetable oils, green leafy vegetables, and fortified cereals [97]. In EAE, TFA-12, a tocopherol derivative, has been shown to promote oligodendrocyte regeneration and remyelination [70]. Furthermore, another study demonstrated that treatment with α-tocopherol can attenuate EAE severity and delay disease progression by suppressing T cell proliferation and the Th1 immune response [71]. In pwMS, serum levels of α-tocopherol have been found to be lower than in healthy controls, whereas no significant difference has been observed in the Vitamin E levels in cerebrospinal fluid [54,98]. Another study revealed that Vitamin E supplementation in a population of pwMS significantly reduced lipid peroxidation in serum and helped preserve telomere length in circulating lymphocytes, which is typically increased in MS [72].

Vitamin K refers to a group of fat-soluble compounds that share a similar chemical structure, known also as naphthoquinones. A distinctive feature of one of these forms, the menaquinones, is that they are primarily of bacterial origin and can be endogenously produced in the human body. Vitamin K is involved in various physiological processes, acting as a coenzyme for Vitamin K-dependent carboxylase and contributing to the functional activity of prothrombin [99]. Although significantly lower levels of Vitamin K2 have been reported in patients with MS than in healthy controls [74], and its administration in EAE has led to a significant improvement in disease outcomes [73], there is currently no evidence regarding the effects of Vitamin K supplementation in pwMS.

Vitamins are essential nutrients for the human body, and their deficiency can lead to the onset of diseases or the worsening of pre-existing conditions. Moreover, vitamins also exert effects at the level of the gut microbiota, where they can influence both the abundance and the functionality of microbial populations [100]. A study conducted in an EAE model revealed that treatment with several B vitamins together (B1, B2, B3, B5, B6, and B12) was able to improve the gut dysbiosis typically associated with the disease and to maintain homeostasis [33]. However, most studies on the microbiota in MS have focused on the role of Vitamin D, which remains the most widely discussed vitamin in relation to the pathology. Vitamin D plays an important role in maintaining the integrity of the intestinal barrier [65]. Consequently, its deficiency leads to disruption of this barrier, resulting in dysbiosis, specifically, a reduction in butyrate-producing bacteria [66,67]. A study conducted on pwMS, both treated and untreated with glatiramer acetate, reported that untreated pwMS showed an increase in Faecalibacterium, Coprococcus, and Akkermansia following Vitamin D supplementation compared to the other study groups [68]. Moreover, Vitamin D supplementation was positively correlated with the abundance of Barnesiella, as well as one unspecified family and one genus, while it was negatively correlated with the genera Succinivibrio and Mitsuokella, the family Succinivibrionaceae, and the order Aeromonadales [69].

Curcumin is a polyphenol whose effects have been extensively studied. It is an hydroxycinnamic acid which displays several beneficial properties, as it is considered an important anticancer, antioxidant, anti-inflammatory, and antimicrobial compound which is used not only for cooking but also in the treatment of neurodegenerative disease [137]. In EAE, curcumin was found to improve neurological symptomatology and increased the serum levels of transforming growth factor β (TGF-β) and IL-10, as well as decreasing the immune cells infiltration in the spinal cord and the inflammatory response given by the microglia and mediated by Anexelekto (AXL)/Janus kinase (JAK) 2/Signal Transducer and Activator of Transcription (STAT) 3 [102,103]. Similarly, Khosropour et al. also found that the administration of both curcumin and its semisynthetic derivative F-curcumin ameliorated the onset and severity of EAE by decreasing the expression of genes encoding for IL-17, Il-2, and IFN-γ and by increasing IL-10 and TGF-β. A similar trend was also observed for the gene expression of T-cell derived transcription factors [104]. Moreover, it was found that curcumin was also able to act on toll-like receptors (TLR) by modulating their expression in EAE. Sadek et al. also demonstrated that in EAE, curcumin neuroprotective effect was controlled by adenosine monophosphate-activated protein kinase (AMPK)/sirtuin 1 (SIRT1) activation, which in turn reduced the EAE-related neuronal demyelination, neuroinflammation, and oxidative stress [105]. In pwMS, curcumin has been investigated as a potential novel therapy for its beneficial properties. One study reported that the administration for 6 months of nanocurcumin, an oral-used gel made by encapsulated curcumin in nano-micelle, to RRMS led to decrease in microRNA (miR)-145, miR-132, miR-16, STAT1, Nuclear Factor kappa-light-chain-enhancer of activated B cells (NF-κB), activator protein 1 (AP-1), IL-1β, IL-6, IFN-γ, Monocyte Chemoattractant Protein-1 (CCL2), Chemokine (C-C motif) ligand 5 (CCL5), tumor necrosis factor (TNF)-α levels in peripheral blood mononuclear cells (PBMCs) together with an increase in expression levels of miRNAs targets compared to controls [106]. Dolati et al. also investigated the regulation of dysregulated miRNA, confirming the involvement of nanocurcumin in its restoration [138]. Nanocurcumin was also demonstrated to significantly decrease Th17 and IL-17, and the expression levels of retinoid-related orphan receptor γ t (RORγt), and to increase Treg cells, FoxP3 expression, IL-10, and TGF-β in PBMCs of RRMS patients [107,108]. Lastly, a randomized controlled trial reported that supplementation with curcumin could confer efficacy to IFN β-1a therapy on radiological signs of inflammation in MS, even if it did not exert any neuroprotective effect [109].

Resveratrol is a polyphenolic compound and a stilbene found in blueberries, red grapes, mulberries, rhubarb, pistachios, and peanuts. Due to its antioxidant and anti-inflammatory properties, resveratrol has been studied also for its neuroprotective effects [139]. Resveratrol can increase sirtuin 1 (SIRT1) levels, reduce Nicotinamide Adenine Dinucleotide Phosphate (NADPH) oxidases, NADPH Oxidase 2 (NOX2) and 4 (NOX4) levels and promote BBB integrity [110,111]. Indeed, increased SIRT1 expression has been associated with elevated levels of IL-10 and reduced levels of IFN-γ and IL-17 in EAE. Moreover, the analysis of myelin basic protein (MBP) levels and neurofilament (NF) counts demonstrated that axonal damage and demyelination are decreased upon SIRT1 overexpression [112]. It has also been shown that the pharmaceutical formulation of resveratrol, SRT501, was able to prevent neuronal damage and long-term neurological dysfunction by delaying the onset of EAE and protecting against neuronal damage [140]. Additionally, one study reported that resveratrol could improve EAE by increasing miR-124 levels, which in turn inhibit sphingosine kinase 1, leading to an amelioration in general disease outcome [113]. Regarding its antioxidant activity, Dirk et al. found with an in vitro study that resveratrol effectively modulates ROS production in MS, by increasing IL-10 levels [141]. Beneficial effects of the administration of resveratrol were observed also in a cuprizone- treated (CPZ) C57B1/6 mice model, where an amelioration in the clinical condition of the mice was registered [142]. In pwMS, resveratrol supplementation was instead found to decrease TNF-α and malondialdehyde, compared to the control, exerting an anti-inflammatory and antioxidant effect [114].

Quercetin, a flavonol found in fruits, vegetables, and certain medicinal herbs, has demonstrated anti-inflammatory and antioxidant properties in EAE and in in vitro treatments on blood cells from patients with MS [101]. It was demonstrated that quercetin was able to delay the disease onset in MS mice model and to improve the demyelination and inflammatory infiltration in the CNS. Moreover the same group demonstrated that this therapeutic action was related to the ability of quercetin to inhibit expression of proinflammatory cytokines such as TNF-α, IL-6, IL-1β, IFN-γ, IL-17A, and IL-2 [115]. A similar effect on IL-17 was also observed for quercetin pentaacetate, even if the inhibitory effect observed on Th17 cells and ROR receptor C (RORc) gene expression by quercetin was not maintained for its modified compound [143]. In CPZ MS model, quercetin significantly increased the general quality of mice ambulation, superoxide dismutase, glutathione peroxidase and total antioxidant status, while decreasing serum malondialdehyde, TNF-α, and IL-1β [144]. Similar beneficial effects were also observed in EAE, where quercetin was able to ameliorate the disease by inhibiting IL-2 signaling and Th1 cells differentiation [116].

Anti-inflammatory and neuroprotective properties were observed also for luteolin, one of the most bioactive polyphenols and flavones mainly present in fruits, vegetables, and in particular oranges, carrots, celery, broccoli, parsley, and chamomile [101]. Lutein indeed has been reported to inhibit the activation of peripheral blood leukocytes, mast cells, mast cell-dependent T cell, microglia, and astrocytes, suppress neuroinflammation and oxidative stress and improve disease severity in MS [118,119]. Moreover, it has been observed that luteolin was able to reduce the proliferation of PBMCs from pwMS and to modulate levels of IL-1β and TNF-α. At the same time, it was capable of decreasing metalloproteinase-9 (MMP-9) production and, when used in combination with IFN-β, it promoted a modulation of cell proliferation and Metallopeptidase Inhibitor 1 (TIMP-1), MMP-9, TNF-α, and IL-1β [145]. In EAE, Verbeek et al. reported that luteolin was able to reduce T cells proliferation by 40–60% compared to controls, while increasing IFN-γ production in vitro [117].

Epigallocatechin gallate (EGCG) is a flavanol and the most prevalent catechin in green tea, and it is believed to be responsible for the beneficial effects of the consumption of green tea due to its several properties. Among these, it is known that consumption of green tea is associated with antioxidant effects, cancer chemoprevention, reduction of weight, improvement of cardiovascular health and protection of the skin against ionizing radiation damages [146]. EGCG was reported to reduce the clinical severity of EAE through the reduction of neuronal damage and brain inflammation, and to inhibit the production of TNF-α. Additionally, EGCG was able to block the production of reactive oxygen species in neurons [120]. Sun et al. demonstrated that EGCG inhibited IFN-γ and IL-17 production in CD4+ cells and blocked the Th1 and Th17 differentiation [121]. EGCG also exerted an effect on macrophages, by inhibiting M1 polarization, thereby promoting M2 macrophages [122]. Moreover, when used in combination with glatiramer acetate, EGCG induced regeneration of hippocampal axons in an outgrowth assay [123].

In pwMS, several clinical trials monitoring the effects of EGCG in MS have been conducted. It emerged that EGCG was able to reduce IL-6 and anxiety and depression levels, while no or low effects were reported on the EDSS, annualized relapse rate, or MRI lesion activity compared to controls [124,125]. Mähler et al. found that EGCG supplementation was also able to improve fat oxidation and exercise efficiency, and this was also confirmed by other studies in which emerged the capability of ECGC to ameliorate lipid metabolism, and functional abilities such as balance and gait speed and muscle mass [126,127,128,129,130]. Lastly, higher dosage or longer periods of EGCG supplementation were not able to lead to a reduction in brain atrophy and to significant differences in longitudinal retinal thickness measured by optical coherence tomography (OCT) between EGCG treated and placebo groups [147,148].

Caffeic acid (CA) is a polyphenolic compound belonging to hydroxycinnamic acids which can be found in black chokeberries, coffee, and red wine, but that is also present in apples, plums, lingonberries, sage, thyme, oregano, marjoram, oregano, and spearmint [149]. Due to its structure, CA has several beneficial properties, as it is considered an important antioxidant with positive effects on several diseases such as obesity, diabetes, cancers, and neurodegenerative diseases [149]. These effects could be attributable to the ability of CA, as well as other polyphenolic compounds, to cross the BBB [150]. In EAE, CA phenethyl ester (CAPE) reported a reduction in immune cell infiltration, demyelination in the spinal cord and a decrease in α4integrin expression [131]. Zhou et al. analyzed instead the effect of CA phenethyl ester in MS treatment, discovering that pwMS have higher levels of proinflammatory cytokines/chemokines that preferentially skew towards T helper cytokines. In that study, it was also shown that CAPE was able to modulate T cells, to inhibit their activation and proliferation, to downregulate CD4 + IFN-γ + cells, to increase CD4 + Foxp3+, and to block NF-κB p65 nuclear translocation. Finally, Zhou et al. reported that administration of CA phenethyl ester in the EAE model led to a decreased disease incidence and severity, with less inflammatory cell infiltration, demyelination injury, and microglia/macrophage activation, and to a reduction of Th1 cells in the spleen and CNS and an increase in Treg cells in the CNS [132]. An inhibition in ROS production and an amelioration in EAE clinical symptoms was also observed in rats after the administration of CA phenethyl ester treatment [133].

Isoflavones are phytoestrogens and a subdivision of flavonoids, which are mainly present in soy and other legumes, and which have been investigated for their anti-inflammatory and neuroprotective properties. In particular, isoflavones can suppress pro-inflammatory cytokines, enhance immune system activity and function as antioxidants [151]. Genistein, an isoflavone abundant in soy products, presents apoptotic, anti-inflammatory, and antioxidant properties, led to an amelioration of clinical symptoms and modulation of pro- and anti-inflammatory cytokines in the EAE mice model. Also, genistein treatment resulted in a reduction in rolling and adhering of leukocytes in the CNS compared to the control group [134]. Moreover, in CPZ, genistein promotes the survival of mature oligodendrocytes and myelin formation in the hippocampus [152]. All these properties exerted by genistein are probably due to its ability to modulate the factors involved in the innate immune response in the early EAE, particularly increasing toll-like receptors TLR3, TLR9, and IFN-β, IL-10 in splenocytes and the brain, and reducing Th1 and Th17 cells, IFN-γ, and IL-12 and TNF-α secretion in splenocytes [135,136]. Effects on the immune system of EAE mice were reported also for daidzein, which was able to reduce INF-γ and IL-12, increase IL-10 production, and block lymphocytes proliferation [136].

Evidence highlights the ability of polyphenols to affect gut microbiota composition [153,154,155,156]. Moreover, studies report that this occurs also in EAE and MS. Jensen at al. found that the gut microbial composition in mice fed with an isoflavone-rich diet was more similar to healthy mice than those fed with an isoflavone-free diet [157]. Indeed, the gut microbiota of mice fed with an isoflavone-rich diet presented more abundant levels of Adlercreutzia and Parabacteroides diastonis, similar to healthy donors. These genera instead were depleted in pwMS, where a high abundance of Akkermansia muciniphila was present, as well as in the gut microbiota of mice fed with an isoflavone-free diet [157]. Additionally, curcumin administration in EAE was able to modulate the disease clinically and histologically. Moreover, curcumin administration in EAE correlated with a significant decrease in the relative abundance of Ruminococcus bromii and Blautia gnavus in feces, Turicibacter sp. and Alistipes finegoldii in ileal contents, and Burkholderia spp. and Azoarcus spp. in the ileal mucosa, all of which were associated with modulation of neuroinflammation [158]. The effects that these bacterial modulations have on MS disease have already been investigated. Bacteria like Aldercreutzia, which are responsible for the conversion into monomers of phytoestrogens, were reported to be reduced in RRMS compared to controls, leading to an increase of oxidative stress and inflammatory cytokines [159,160]. Therefore, an increase of Adlercreutzia levels after an isoflavone-rich diet could contribute to a decrease of the proinflammatory environment typically associated with MS. Similarly, Parabacteroides distasonis was also reported to be reduced in MS compared controls, and its increase after isoflavone administrations could be associated with beneficial and anti-inflammatory effects [161]. Akkermansia, a genus involved in into short-chain fatty acids (SCFAs) production and in pro-inflammatory activity, was present in higher abundance in MS patients, similar to a diet free from isoflavone, highlighting the potential anti-inflammatory role of polyphenols [162]. Blautia gnavus, Turicibacter sp., and Alistipes finegoldii, which were reported to be decreased after curcumin administration, are instead pro-inflammatory species associated with the presence of MS [163]. Specifically, Turicibacter sp. was observed to be less abundant in progressive MS compared to RRMS [164], and is associated with a 0–2 year worsening in cognition in MS [165]. Similarly, Alistipes finegoldii were observed to be increased in untreated MS and RRMS compared to controls [166,167]. Accordingly, curcumin may have a beneficial impact by decreasing these species' abundance, thereby modulating the gut microbial composition toward a less pro-inflammatory profile. On the contrary, even if curcumin appeared able to reduce Ruminococcus bromii, previous data show that this SCFA-producing bacteria was less present in MS, and that its depletion could impair the gut barrier function and increase inflammation [168]. Lastly, Burkholderia spp. and Azoarcuss spp. are environmental pathogens, but their influence on MS development and course are still not clear. To date, only a single bioinformatic analysis has shown that a peptide sequence derived from Burkholderia thailandensis reaches a prediction score above 80 for CD4⁺ T-cell epitope presentation in the context of the HLA-DRB115:01 allele [169].

Even if only few studies have been conducted on the influence of specific polyphenols on the gut microbiota in EAE and MS, evidence from analysis on other diseases suggest that also other classes of polyphenols could exert beneficial influence on gut microorganisms. However, more data are still necessary.

Given the reported effects of salt on the immune system, several studies have investigated whether salt intake influences the gut microbiota, to determine if microbial changes could mediate its immunological effects. Wilck et al. reported that a high-salt diet was able to affect gut microbiota composition by particularly decreasing(ex-) [,] and fecal levels of indole-3-lactic and indole-3-acetic acid metabolites. Treatment of EAE withand(ex-) led to an amelioration of the disease, with a reduction of Th17 cells []. This observed effect on EAE supports the evidence that a high-salt diet may also act in EAE by altering the abundance of these bacteria and metabolites, as bacterial supplementation led to an amelioration of the disease. However, further studies are needed to confirm these results. The impact of salt on the gut was also confirmed by another study in which salt administration was able to decrease the dysbiosis together with oxidative stress and inflammation in EAE []. However, although some studies have been conducted, an important gap remains in the understanding of how high salt intake affects the gut microbiota, both in EAE and MS. In particular, little is known about which microbial species are modulated, which metabolic pathways are involved, and how these changes influence the immune system. Therefore, further studies are needed, especially considering that modern dietary habits often include a high consumption of this mineral. Ligilactobacillus murinus Lactobacillus murinus Ligilactobacillus murinus Limosilactobacillus reuteri Lactobacillus reuteri ^{205 206 207 176}

Zinc is an essential metal mainly present in food as meat, fish, and seafood, and especially in oysters, eggs, dairy products, beans, nuts, and whole grains [210]. This micronutrient appears to have a role on the immune system through an anti-inflammatory response of inhibiting the development of Th17-pathogenic lymphocytes and promoting Treg lymphocytes [211]. On the other hand, zinc can also be neurotoxic, as it is involved in neuronal death [212]. Some initial evidence seems to suggest a role for this mineral in the pathogenesis of EAE. In particular, oral administration of zinc aspartate was reported to reduce histopathological and clinical signs during the relapsing remitting phase of the disease in EAE. Together, a suppression of IFN-γ, TNF-α, Granulocyte-Macrophage Colony-Stimulating Factor (GM-CSF) and IL-5 production was observed in stimulated human T cells and mouse splenocytes, and a modulation of proinflammatory cytokines in vitro. These results aligned with previously reported data according to which injection of zinc aspartate was able to suppress EAE [181]. Contrarily, deficiency of zinc prevented the development of neurological signs of EAE in guinea pigs, with only a few cases of focal inflammatory alteration in the CNS [182]. Choi et al. found that 1H10, a zinc chelator and AMPK inhibitor, was able to reduce EAE severity and demyelination, microglial activation, immune cell infiltration, BBB disruption, and MMP-9 activation. Additionally, results show that long-term treatment with 1H10 was able to reduce the clinical course of EAE [183]. Lastly, it was reported that both zinc chelation and zinc transporter 3 (ZnT3) gene deletion significantly reduced inflammation and demyelination in the spinal cord in EAE [184,185]. Instead, PwMS were found to have higher erythrocyte zinc compared to controls [189]. On the contrary, Oraby et al. observed that disease duration, number of relapses, EDSS, and MRI lesion load were negatively correlated with zinc levels in pwMS [190]. Lastly, Cortese et al. did not observe association between dietary minerals intake as zinc and MS risk [191]. The dual nature of zinc, showing both beneficial and detrimental effects in EAE and MS, can primarily be explained by its dose-dependent behavior. Zinc must be maintained within an optimal range, as both deficiency and excess can lead to imbalance and tissue damage [213,214]. This paradox also reflects zinc's distinct actions on the immune and nervous systems: in the immune system, zinc exerts anti-inflammatory and immunomodulatory effects [211,215,216], whereas in the central nervous system, excessive zinc accumulation can exert neurotoxic effects [217].

Iron (Fe) is a mineral which is introduced through the diet or through supplementation. It is an essential element found in hemoglobin, and it can be found in two main forms: heme and nonheme. Nonheme iron is contained in plants and iron-fortified foods, whereas meat, seafood, and poultry contain both heme and nonheme iron [218]. Fe is a mineral with a key role in normal neuronal processes, yet abnormal iron accumulation can cause neurodegeneration through lipid peroxidation and cell death in the brain [219]. It is possible that inadequate Fe levels, both low and high, may be detrimental in MS, as Fe reduction may decrease immune system function and cause an energy deficit due to loss of membrane potential of the mitochondria, while excess Fe may increase oxidative stress [208,219]. A study performed in 1998 on EAE revealed that mice at a clinical stage showed increased stained pathological features such as macrophages, extravasated red blood cells, and granular staining compared to the preclinical stage. Moreover, this situation persisted also in the recovery phase, but with less extravasated red blood cells [192]. Additionally, iron deficiency was reported to be protective against EAE development by Grant et al., even if iron excess was not found to be relevant for disease onset [193]. One study identified several genes associated with both MS and Fe metabolism, finding, through a Mendelian randomization analysis, a potential causal relationship between transferrin saturation and serum transferrin and MS, highlighting the link between iron metabolism and MS [220]. When considering pwMS, iron accumulation in deep grey matter was found to be strongly and independently associated with disease duration and severity [194], as well as depletion in white matter [195]. Conversely, another study reported that exacerbation of depressive disorders and a decline in quality of life of pwMS was associated with ferritin deficiency [196]. A 6-month pilot study revealed that 12 subjects taking a regimen of nutritional supplements that included also in some cases Fe supplementation, improved significantly neurologically. However, this improvement was also observed in patients who did not receive iron supplementation, suggesting that, although iron is not the only factor contributing to the beneficial effects, it does not appear to exert any negative influence on the disease [221]. Lastly, another study reported no association between dietary minerals such as iron and MS risk, either for baseline or cumulative intake during follow-up [191]. This dual effect of iron is also evident in a study conducted by Lynch et al., in which, following administration of desferrioxamine, an iron-chelating drug, one patient showed improvement, three remained stable, and five worsened by 0.5 on the EDSS scale [222]. Therefore, although the majority of studies report a detrimental role of Fe, it is likely that each patient's condition should be evaluated individually, as different patients may respond differently to iron supplementation.

Selenium (Se) is a micronutrient that can be found in edible plants that accumulate this mineral from the environment, as soil and aquatic sediments. Se is known to function as part of selenoproteins, which play an essential role in redox homeostasis, mediating synaptic plasticity and protecting CNS cells from oxidative stress and therefore the attenuation of inflammatory processes. Moreover, immunomodulatory properties of Se have been reported [223]. In EAE, it has been observed how Se reaches the CNS and reduces local inflammation and the clinical severity of the disease [197]. Additionally, another study reported that EAE animal models fed with high doses of non-toxic Se displayed higher incidence of death and developed the disease with a subacute course in some cases, compared to animals fed with lower doses of Se [198]. A first study conducted in 1988 reported lower levels of Se in MS patients compared to controls, while it was possible to obtain normal metal levels after daily Se supplementation [201]. Conversely, Alizadeh et al. did not observe differences in Se blood levels between pwMS and healthy controls [202]. In RRMS serum selenium concentrations were reported to be significantly lower than in healthy volunteers and this could also depend on dietary habits, such as higher intake of sugar, preserved products, and margarine [199]. A recent meta-analysis showed that 14.3% of MS patients use selenium as a supplement, although there is a lack of evidence regarding the safety and efficacy of selenium supplements in MS patients. However, in some randomized controlled trials, selenium-containing products were found to be well tolerated and associated with benefits with regard to inflammatory status and oxidative stress in the MS population [203]. Lastly, the administration of crocin-selenium nanoparticles, both antioxidant agents, was reported to improve the total antioxidant capacity, and the cognitive function in pwMS [204]. These findings highlight the antioxidant role of Se and suggest that the deficiencies observed in the analyzed cohorts are often attributable to inadequate dietary intake of this micronutrient. Increasing the consumption of selenium-rich foods, or considering supplementation when appropriate, may help achieve recommended intake levels and potentially exert beneficial effects in pwMS. However, further studies are needed to confirm these observations.

Essential metals such as zinc, iron, and selenium have already been described as modifiers of gut microbiota composition [224,225,226,227]. A recent study reported that high levels of arsenic, nickel, manganese, and zinc and low levels of iron, lead, titanium, and tin in MS patients compared to health controls correlated with increased abundance of Verrumicrobiaceae, Lachnospiraceae, and Ruminococcaceae [228]. Although a correlation has been established and it is known that these essential metals can influence gut microbiota composition, a significant gap remains in the literature regarding the effects of essential metal supplementation in EAE and MS. Further studies are therefore needed to clarify their impact on the gut microbial community.