Linking Nutrients to Multiple Sclerosis Pathogenesis: Biological Evidence and Clinical Implications

This narrative review includes data from scientific papers collected across several databases, including PubMed, Google Scholar, ScienceDirect, Scopus and Web of Science. The search was aimed at identifying relevant studies regarding the impact of nutrients, fatty acids, carbohydrates, fibers, and proteins on EAE and MS, considering also their effect on the gut microbiota. Therefore, specific keywords were used in the research, such as "nutrients", "fatty acids", "carbohydrates", "fibers" and "proteins", which were combined with terms like "experimental autoimmune encephalomyelitis", "multiple sclerosis" and "gut microbiota", using Boolean operators (AND, OR) to refine the results. The final research was carried out in October 2025, providing an updated overview of the literature. Inclusion criteria included original articles and reviews relevant to the review topic. The research started with a review of the titles of key references, followed by an accurate examination of the content. Articles whose topics were in line with the review subjects were included, while articles that did not satisfy these criteria were excluded. As this is a narrative review, detailed documentation of the literature searches across specific platforms is not required.

Fatty acids (FAs) represent a family of molecules that are either derived from dietary sources or produced by intestinal bacteria through the fermentation of dietary fibers. Structurally, they consist of a hydrocarbon chain with a hydrophilic terminal carboxyl group. FAs are commonly classified based on the length of their carbon chain and the number of double bonds [31]: short-chain fatty acids (SCFAs) contain 1–5 carbon atoms, medium-chain fatty acids (MCFAs) 6–12, long-chain fatty acids (LCFAs) 13–24, and very-long-chain fatty acids (VLCFAs) more than 24. According to the degree of unsaturation, they can be divided into saturated (SFAs) and mono- or polyunsaturated fatty acids (MUFAs and PUFAs, respectively) [34].

The impact of FAs on MS pathophysiology appears to depend largely on their chemical structure. Lauric acid (LAc; a MCFA) and palmitic acid (PALM; a LCFA) are two representative examples. LAc is mainly found in coconut oil, whereas PALM is abundant in both animal- and plant-derived foods such as butter, milk, chocolate, and eggs. In vivo studies using the EAE model demonstrated that diets enriched in LAc or PALM promote the differentiation of pro-inflammatory Th1 and Th17 cells, worsening the disease course. Specifically, a diet rich in LAc induced an increase in Th17 cells in both the spleen and CNS, suggesting a differential segregation pattern of antigen-specific T cells. Conversely, treatment with SCFAs enhanced the differentiation of regulatory T cells (Tregs). These effects appear to arise from multiple, coordinated mechanisms acting at receptor, transcriptional, and post-transcriptional levels. The gut microbiota seems to play a pivotal role in mediating these effects: fecal microbiota transplantation from mice fed with LAc-rich diet led to an increased abundance of Th17 cells in recipient animals compared with microbiota transplantation from mice fed with control diet. This result indicates that LCFAs induce a perturbation in the gut microbiome and metabolites that act on the immune system [35]. Supporting this evidence, serum concentrations of butyric acid (BA; an SCFA) were found to be decreased, while those of caproic acid (CA; an MCFA) were increased in pwMS. CA levels were positively correlated with Th1 cell abundance, whereas the BA/CA ratio correlated positively with Tregs and negatively with Th1 cells. Hence, an altered SCFA/MCFA ratio may contribute to the chronic inflammatory state associated with MS, paralleling compositional shifts in the gut microbiota [36]. Specifically, a reduction in SCFA-producing taxa (e.g., Roseburia, Coprococcus, Blautia, Parabacteroides, and members of the Lachnospiraceae family) and an increased abundance of mucin-degrading, pro-inflammatory genera such as Akkermansia, Collinsella, and Eubacterium have been observed in pwMS compared with healthy controls. The role of SCFAs as microbiota-derived metabolites and their immunomodulatory properties will be further discussed in Section 5.

The main dietary MUFA is oleic acid (OA), which represents the predominant lipid component of the Mediterranean diet (MD), largely derived from extra virgin olive oil (EVOO) [37]. EVOO is characterized by its high OA content and a rich profile of antioxidant compounds, particularly phenolic molecules, which contribute to its well-documented health benefits [38]. Although studies investigating the effects of EVOO in the EAE model are relatively recent and limited in number [39,40], emerging findings suggest its protective role. Administration of EVOO, as well as its main components OA and hydroxytyrosol, has been shown to improve clinical outcomes, decrease lipid peroxidation and protein carbonylation, and enhance the activity of antioxidant enzymes such as glutathione peroxidase in the brain, spinal cord, blood, and intestine. Moreover, anti-inflammatory effects of EVOO could result in reduced levels of TNF-α, NF-κB p65, and nitric oxide (NO). Notably, both serum and intestinal lipopolysaccharide (LPS) concentrations were significantly lowered following EVOO or component administration, suggesting that part of its beneficial action may involve modulation of the gut barrier integrity and microbiota composition [39,40].

PUFAs are classified into two main families, omega-3 (ω-3) and omega-6 (ω-6), based on the position of the first double bond from the methyl end of the carbon chain. Specifically, ω-3 FA have their first double bond at the third carbon, whereas ω-6 FA have it at the sixth position. Linoleic acid (LA, a member of ω-6) and α-linolenic acid (ALA; member of ω-3) are defined as essential fatty acids because they cannot be synthesized de novo in humans and must therefore be obtained from the diet. Both serve as precursors for the biosynthetic elongation and desaturation cascade leading to very-long-chain PUFAs.

A high dietary intake of ω-6 is a hallmark of the Western diet, which is typically rich in processed foods and red meat while being poor in fish-derived nutrients. Most seed and vegetable oils (including safflower, sunflower, soybean, maize, grape seed, and cottonseed oils) represent major dietary sources of ω-6 PUFAs in the form of LA, whereas ω-3 fatty acids, particularly ALA, are generally present in lower proportions. Since the human body cannot interconvert ω-6 and ω-3 series fatty acids, tissue concentrations of these FAs and their eicosanoid derivatives, eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA), depend directly on dietary intake.

Unlike ω-6 FA, the intake of ω-3 is usually insufficient due to limited sources. ALA is found in green leafy vegetables, flaxseed, walnuts, soya and canola oils. Their derivatives, EPA and DHA, are obtained through breast milk and fish oils, such as salmon, mackerel, sardines, anchovies, herring and rainbow trout, but also algae [41]. Epidemiological data indicate an inverse association between ALA intake and MS risk [42]. Furthermore, regular fish or seafood consumption, at least once per week or once per month combined with fish oil supplementation, was associated with a 44% reduction in the odds of MS or clinically isolated syndrome (CIS) compared to lower intake and no supplementation [43]. PwMS who consumed fish three or more times per week or took high-dose ω-3 supplements exhibited lower disability scores, better mobility, improved health-related quality of life, and reduced levels of inflammatory cytokines and matrix metalloproteinase-9 [44,45,46]. In the mouse model, both EPA and DHA have been shown to attenuate EAE disease severity [47,48]. Mechanistically, ω-3 fatty acids appear to modulate T cell activation through GPR120 receptor engagement, leading to decreased phosphorylation of transforming growth factor β-activated kinase 1 (TAK1) and activation of NF-κB, that acts as a T-cell activating mediator [49]. Additionally, DHA has been reported to exert anti-inflammatory and tolerogenic effects by inducing a tolerogenic dendritic cell (DC) phenotype and expanding Tregs in vivo. This occurs through the activation of DCs' GPR120 receptor signaling with an up-regulation of SOCS3 and a subsequent down-regulation of the JAK2-STAT3 signaling pathway [50]. However, despite promising preclinical and observational evidence, clinical trials investigating PUFA supplementation in humans have yielded inconclusive results [51].

Trans fatty acids (TFAs) are a subclass of unsaturated fatty acids that contain two or more unconjugated double bonds in the trans configuration. Although a small proportion of TFAs are naturally produced during ruminal fermentation in ruminant animals, most of them are generated industrially through the partial hydrogenation of PUFA-rich vegetable oils [52]. Dietary intake of TFAs has been associated with chronic metabolic disorders. In experimental models of obesity, TFA administration was found to induce gut microbiota dysbiosis, characterized by a slight increase in relative abundance of Proteobacteria and in the genus Bacteroides, accompanied by a decrease in Muribaculaceae, compared with control animals [53]. Similarly, a high-TFA, high-sucrose diet in mice led to an increased abundance of the Desulfovibrionaceae family, concomitant with worsening of diabetes and hepatic steatosis [54].

Although no preclinical or clinical studies have yet specifically investigated the effects of TFA intake on MS pathology, this body of evidence from metabolic disease models suggests a role of TFA in inducing gut dysbiosis also in MS. TFAs are typically present in ultra-processed foods (UPFs) in varying amounts depending on the degree of industrial processing [55]. Data from the 2003–2006 Ausimmune Study revealed that higher UPF consumption was significantly associated with an increased likelihood of a first demyelinating event, with an 8% increase for an energy/day adjusted portion of UPF [56]. Moreover, individuals with higher UPF intake exhibited moderate-to-severe MS disease activity compared with those consuming lower amounts, both in unadjusted analyses and after adjustment for demographic and clinical confounders [57].

High-fat (HF) diets have produced intriguing results in EAE, highlighting the importance of dietary fat quality. In one study, EAE-induced mice fed a HF diet based on canola oil, which is rich in MUFAs and contains approximately 30% PUFAs, showed complete protection from disease, exhibiting no clinical signs and zero incidence compared with mice fed high-carbohydrate or high-protein diets. Furthermore, HF-fed mice displayed limited CNS infiltration and no evidence of demyelination [58]. These findings suggest that specific types of dietary fats, rather than total fat content, may exert protective effects against MS-like pathology. Mechanistically, LCFAs, such as lauric acid, have been shown to promote pro-inflammatory cytokine production (including IFN-γ, IL-17A, and IL-2) in CD4⁺ T cells and drive Th17 differentiation, thereby exacerbating disease severity in EAE [35,59]. In contrast, OA not only stimulates T cell proliferation in lymphoid organs but also suppresses IL-2 and IFN-γ production [60]. Additionally, OA alters cell membrane composition by reducing arachidonic acid levels, resulting in decreased production of pro-inflammatory lipid mediators derived from arachidonic acid [61]. In pwMS, adipose tissue OA levels are lower than in healthy controls, and ex vivo treatment of Tregs from pwMS with OA partially restores their suppressive function [62]. Polyunsaturated fatty acids also demonstrate beneficial effects in MS and EAE, too. Linoleic acid, an omega-6 fatty acid comprising roughly 19% of canola oil, has been reported to modulate inflammatory responses in both preclinical and clinical studies [63,64]. Overall, fatty acids exert several opposing effects on MS pathology and are summarized in Table 1. While certain medium- and long-chain fatty acids promote pro-inflammatory responses, SCFAs, some MUFAs and omega-3 show immunoregulatory and neuroprotective properties. TFA and UPF, instead, appear to worsen inflammation and dysbiosis. Emerging evidence also points to specific HF dietary patterns, such as canola oil-based diets, as potentially protective. In conclusion, although their role in MS is variable, fatty acids remain essential dietary components that, when consumed in balance, can also contribute to general health benefits.

Carbohydrates, commonly referred to as sugars, are one of the essential macronutrients in human nutrition. They represent a major source of energy and play a key role in the regulation of glucose and insulin metabolism, as well as in the modulation of triglyceride and cholesterol levels. Moreover, carbohydrates are substrates for fermentation processes that occur within the gut microbiota [65].

Carbohydrates can be further classified into simple carbohydrates, complex carbohydrates, starches, and dietary fibers. The latter, due to their specific physicochemical properties and well-documented health benefits, will be discussed in detail in the following section. Given the biochemical diversity of this macronutrient group and the wide range of physiological pathways in which they participate, carbohydrates make a substantial contribution to overall human health.

In PwMS, a lower intake of total carbohydrates and sugars has been associated with improved walking ability and a lower degree of disability [66,67]. Conversely, individuals consuming diets rich in simple carbohydrates but insufficient in total carbohydrate and thiamine relative to their nutritional needs exhibit higher levels of MS-associated depression [68].

A high intake of carbohydrates has been linked to the promotion of a pro-inflammatory metabolic environment [69]. Accordingly, several studies have explored the relationship between their consumption and the risk of developing or exacerbating chronic inflammatory and autoimmune diseases, including MS.

Studies conducted in EAE mice have demonstrated that the consumption of caffeine-free high-sucrose (10–11% w/v) cola beverages for a long period of 8 weeks can exacerbate disease pathogenesis through a microbiota-dependent mechanism, involving the expansion of Th17 cells. Specifically, this dietary intervention favored the growth of several bacterial genera, including Mucispirillum, Coprococcus, Escherichia, Paraprevotella, Desulfovibrio, Odoribacter, and Ruminococcus, as well as the species Escherichia coli, Ruminococcus gnavus, Mucispirillum schaedleri, Desulfovibrio C21_c20, and Butyricicoccus pullicaecorum [70].

A similar alteration in gut microbial composition was observed in another EAE model fed with a fructose-rich diet (649.19 g/kg or 70% kcal from fructose, in some cases supplemented with 30% w/v fructose-containing water). This diet significantly reduced the abundance of beneficial commensals while favoring the proliferation of pro-inflammatory bacteria. Although the high fructose intake had only a modest effect on disease severity, an immune modulation was observed both in the gut and periphery. In particular, an enrichment of Helios⁻RORγt⁺Foxp3⁺CD4⁺ Treg cells was detected in the small intestinal lamina propria [71] probably as a result of fructose absorption in the small intestine [72]. The expansion of Helios⁻RORγt⁺Foxp3⁺CD4⁺ Tregs may appear to contrast with the pro-inflammatory effects typically attributed to high fructose consumption; however, the functional nature of this subset remains unclear. Helios is generally considered a marker of thymus-derived Tregs, while the observed Helios⁻ populations likely represent peripherally induced subsets shaped by environmental factors such as diet and microbiota composition [73,74,75,76]. Moreover, RORγt serves as the lineage-defining transcription factor for Th17 cells; thus, Tregs co-expressing Foxp3 and RORγt may represent IL-17-producing Tregs with reduced suppressive capacity [77,78]. Nonetheless, other reports indicate that these double-positive Tregs can retain significant immunosuppressive properties [79]. Taken together, these findings suggest that the presence of this specific Treg subset within the small intestinal lamina propria could be diet-dependent, potentially induced by high fructose intake through gut microbiota remodeling, although its precise immunological function in inflammatory contexts remains to be fully elucidated.

Further evidence on sugar-mediated inflammation in EAE was provided by Zhang et al., who demonstrated that the administration of a high-glucose diet (20% glucose for 2 weeks) induced the generation of reactive oxygen species (ROS), which modulate transforming growth factor beta (TGF-β) signaling, thereby promoting Th17 cell differentiation and their accumulation within the spinal cord and brain [80].

More recently, a 2025 study reported that a high-carbohydrate diet (75% carbohydrates for 6–7 weeks) was associated with an earlier onset of EAE, a higher disease incidence and with more severe clinical symptoms. Mice fed this diet displayed higher CNS immune cell infiltration and pronounced demyelination, indicating that excessive carbohydrate consumption acts as an aggravating factor in EAE pathogenesis [58].

Overall, these findings suggest a potential association between high carbohydrate intake and MS. However, it is important to consider the source and quality of carbohydrates. The studies discussed mainly address the detrimental effects of simple sugars present in sugar-sweetened beverages and ultra-processed foods. Conversely, a diet providing an appropriate proportion of carbohydrates (approximately 50–55% of total energy), primarily derived from whole grains and unprocessed or minimally processed foods such as fresh fruit, is recommended to ensure balanced macronutrient intake. Such dietary patterns are associated with a higher intake of fiber and micronutrients and a lower risk of mortality [81]. Therefore, the adoption of anti-inflammatory dietary patterns appears to offer promising opportunities as an adjunct to conventional therapies for MS management. Nevertheless, further evidence from well-designed studies is required to substantiate these findings and clarify the mechanisms underlying their potential benefits. The main effects of dietary carbohydrates on EAE and MS are summarized in Table 2.

Dietary fibers are indigestible carbohydrates derived from plant sources. They are generally classified as soluble or insoluble, and as fermentable or non-fermentable complex carbohydrates. Fibers are naturally present in a wide range of commonly consumed foods, including fruits, grains, vegetables, nuts, legumes, and seaweeds, although their content varies depending on the source [82,83]. The impact of both fermentable and non-fermentable fibers has been explored in the context of MS, as higher dietary fiber intake has been associated with significant improvements in disease outcomes compared with a Western-type diet [84]. The main effects of dietary fiber on EAE and MS are summarized in Table 3.

The end products of fermentable fibers are the SCFAs, whose protective effects against MS have been extensively documented. Fettig et al. demonstrated that guar gum, a soluble and fermentable fiber, significantly reduced the activation and migration of CD4⁺ Th1 cells, resulting in attenuated neuroinflammation following EAE induction [85]. In contrast, non-fermentable fibers, commonly found in vegetarian diets, have been investigated for their immunomodulatory effects despite their limited degradation by gut microbiota [83]. A diet enriched in non-fermentable fibers (cellulose-rich, CR diet) was shown to prevent disease development in EAE mice. This protective effect was linked to an increased production of LCFAs, which promoted a Th2 anti-inflammatory immune response and modulated gut microbial composition [86].

Other findings supporting the protective role of dietary fibers in EAE come from studies on oral administration of pomegranate peel extract, as pomegranate peel is composed primarily of soluble and insoluble fibers in nearly equal proportions [87]. This treatment has been shown to ameliorate EAE, by reducing CNS infiltration and preventing myelin loss, and by modulating gut microbiota composition [88].

Conversely, Sen et al. reported that a high-fiber diet was associated with a pro-inflammatory milieu in EAE, leading to a worsened disease course compared with a fiber-free diet [89]. Peripheral blood cells displayed an enhanced pro-inflammatory phenotype, accompanied by increased infiltration of dendritic cells and monocytes into the CNS. Notably, this inflammatory environment was observed despite the increase in SCFA levels, highlighting the context-dependent and potentially bifunctional nature of these metabolites as deeply discussed in the following section [89].

In line with preclinical data, several human studies have investigated the role of dietary fiber intake in MS. Since 1998, numerous studies have examined the potential protective effect of a high-fiber diet on MS risk [90], as it has been observed that pwMS often consume less fiber than recommended [91]. A low fiber intake has been associated with an increased risk of a first demyelinating event [92], whereas a diet enriched in prebiotic fibers was shown to attenuate systemic inflammation and modulate disease severity in pwMS [93]. Similarly, higher fiber consumption and greater adherence to the MD have been linked to lower Multiple Sclerosis Severity Scores (MSSSs) and improved clinical outcomes [94,95]. Conversely, Hatami et al. reported a positive association between total fiber intake and the odds of developing MS [96].

In this context, beyond carbohydrates and fibers, dietary proteins also emerge as crucial modulators of immune and neuroinflammatory processes, influencing both gut microbial metabolism and CNS function. Proteins are essential macronutrients required for the maintenance and proper functioning of the human body. They are primarily obtained through dietary sources and play critical roles in numerous physiological and metabolic processes. In recent years, increasing attention has been devoted to understanding how dietary proteins may influence the course of MS. The following section will discuss current evidence regarding the impact of proteins derived from meat and dairy products on MS progression. Additionally, the potential roles of dietary tryptophan and gluten in modulating disease mechanisms will be explored. The main effects of dietary proteins on EAE and MS are summarized in Table 4.

Based on the evidence linking macronutrient composition to immune and metabolic homeostasis, several dietary patterns have been developed and evaluated for their potential impact on MS progression. Each of these regimens modulates nutrient intake differently, thereby influencing inflammatory and neurodegenerative processes.

One of the most investigated approaches is the ketogenic diet (KD), which aims at reducing pro-inflammatory consequences of carbohydrate intake (Figure 1). In this nutritional regimen, the reduction in carbohydrate intake is compensated by an increased consumption of fats and an adequate intake of proteins [174]. KD enhances mitochondrial function by increasing energy output and reducing ROS production, while elevating circulating ketone bodies. These metabolic adaptations contribute to reduced inflammation and neuroprotection [175]. In EAE, KD has been shown to decrease disease severity and improve motor, learning, and memory performance [176,177]. In the cuprizone-induced demyelination model, KD ameliorated behavioral and motor deficits and inhibited microglial and astrocytic activation, thus exerting neuroprotective effects [178]. Studies in pwMS have also documented beneficial outcomes associated with the adoption of this dietary regimen: in pwMS, KD has been associated with reduced inflammation, fatigue, disability, and depressive symptoms, along with enhanced remyelination and lower serum neurofilament light chain (sNfL) levels, a marker of neuroaxonal damage [177,179,180,181,182,183]. KD has also been reported to reduce the levels of enzymes involved in the synthesis of pro-inflammatory eicosanoids in pwMS. These eicosanoids play a key role in the pathogenesis of MS, as they contribute to increase vascular permeability and promote leukocyte migration into the CNS. Specifically, a reduction in ALOX5 expression was observed in pwMS compared to the HD group, and a down-regulation of COX-1 and COX-2 after KD, indicating an impaired activity of these enzymes following dietary intervention [184]. With respect to gut microbiota modulation, whereas KD initially reduced the abundance of several commensal bacteria such as Bacteroides and Faecalibacterium prausnitzii in pwMS, after 12 weeks, their levels progressively recovered to values comparable to healthy controls. Conversely, Akkermansia showed a slight but consistent decline throughout the intervention [185].

The MD represents another dietary pattern of interest especially for high fibre intake. MD is characterized by a high intake of plant-based foods such as vegetables, fruits, cereals, legumes, nuts, and olive oil, together with moderate consumption of dairy products, eggs, fish, and poultry, and limited red meat intake [186] (Figure 1). Adherence to MD has been consistently associated with lower risk of neurodegenerative diseases, including MS [186,187,188]. In pwMS, higher MD adherence correlated with reduced fatigue, disability, relapse risk, and the general disease outcomes [94,189,190,191,192,193,194,195,196]. MD also promotes favorable changes in the gut microbiota of pwMS, increasing the abundance of beneficial genera such as Faecalibacterium and Prevotella [197]. Furthermore, adherence to MD was found to be inversely associated with Eggerthella sp., Methanobrevibacter and Lactococcus sp., and positively associated with Ruminococcaceae NK4A214 group sp. and Clostridiales vadin BB60 group in MS [99]. In EAE, MD combined with lycopene delayed disease onset and reduced clinical scores, splenic T cell counts, and IL-17A production, while increasing IFN-γ, IL-22, and myelination scores [198]. Probably through action on gut microbiota: increased abundances of Akkermansia, Dorea, Bifidobacterium, and Coprococcus were found in mice fed with MD supplemented with lycopene compared to mice following a western diet [198].

Although high protein intake, especially from red meat, has been linked to pro-inflammatory effects, data on the impact of low-protein diets in MS remain limited (Figure 1). In 2017 a study evaluated the impact of a high-vegetable/low-protein diet in a cohort of patients with RRMS over a 12-month period, observing both clinical and cellular as well as microbiota-level changes [84]. Specifically, during the 12-month follow-up, a significant reduction in both relapse rate and EDSS was reported. At the immunological level, a significant decrease in IL-17-producing CD4⁺ T lymphocytes and PD-1-expressing CD4+ T lymphocytes was observed, alongside a significant increase in PD-L1-expressing monocytes. The proposed mechanism underlying these effects involves modulation of the gut microbiota, as the dietary intervention also led to a significant increase in the abundance of the Lachnospiraceae family [84].

Finally, growing attention has been directed toward vegan diets, characterized by the exclusion of all animal-derived products and reliance on plant-based protein sources. In a pilot study including patients with various neurological and psychiatric conditions, adherence to an anti-inflammatory vegan diet for three months led to improvements in cognition, energy, and activity levels in the MS participant [199]. Similar benefits were also reported in individuals with other neurodegenerative diseases such as Alzheimer's and Parkinson's disease, including better sleep quality, reduced pain, and enhanced physical activity [199]. While preliminary, these findings suggest that plant-based, anti-inflammatory vegan diets may exert beneficial effects on MS-related symptoms and warrant further investigation.

Diet profoundly affects gut microbiota composition and the production of microbial metabolites, which in turn modulate immune responses relevant to MS pathogenesis. In this section, we summarize and critically discuss the most significant findings reported in our review.

LCFAs are a chemically heterogeneous group, encompassing SFAs, MUFAs, and PUFAs, which can exert diverse effects on neuroinflammation. While TFAs are predominantly found in industrially processed foods and are associated with gut dysbiosis and systemic inflammation [52,53,54,55,56,57], MUFAs including oleic acid from EVOO have shown beneficial effects on gut barrier integrity and an indirect anti-inflammatory mechanism via microbiota modulation, due to its polyphenolic components [38,39,40]. Additionally, ω-3 PUFAs including EPA and DHA, have consistently shown anti-inflammatory effects across experimental studies [42,47,48,49,50]. This evidence supports the non-negligible role of LCFA in immune and neuroinflammatory pathways, potentially through microbiota-dependent mechanisms. Despite this biological rationale, clinical trials investigating the effects of specific fatty acid profiles in MS remain limited to clarify their therapeutic relevance in MS.

A high intake of carbohydrates has been associated with the establishment of a pro-inflammatory metabolic milieu. Experimental studies in EAE models indicate that high-sucrose and high-fructose diets exacerbate disease pathogenesis through microbiota-dependent mechanisms and immunomodulatory effects [70,71]. Likewise, high-glucose diets have been shown to promote ROS production, thereby favoring Th17 cell differentiation [80]. In pwMS, both the total carbohydrate intake and, more importantly, the quality and type of carbohydrates consumed play a key role in modulating disease-related inflammation. Increased consumption of simple carbohydrates has been linked to greater depressive symptoms associated with MS [66,67,68]. Therefore, the source and quality of carbohydrates should be carefully considered: high consumption of simple sugars, particularly those found in sugar-sweetened beverages and ultra-processed foods, contributes to a pro-inflammatory state; conversely, a dietary pattern characterized by an adequate proportion of complex carbohydrates from whole grains, fruits, and other minimally processed foods is recommended and may confer beneficial effects on overall health.

Dietary fibers are a fundamental component of human nutrition, and their intake has been consistently associated with beneficial effects in both EAE and MS [82,83,84]. The positive health outcomes linked to a high-fiber diet are largely attributed to its ability to modulate the gut microbiota, favoring the expansion of anti-inflammatory and beneficial bacterial taxa, which in turn leads to the increased production of SCFAs [100]. SCFAs, such as acetate, propionate, and butyrate, have been shown to exert immunomodulatory and neuroprotective effects, influencing peripheral and central immune responses as well as maintaining intestinal barrier integrity [102]. Nevertheless, the relationship between dietary fibers, microbiota-derived metabolites, and host immunity is complex. Emerging evidence suggests that the effects of fiber supplementation may depend on the type, fermentability, and dosage of the fibers, as well as on the baseline microbial composition of the host [103,104,105,106,107,108]. Moreover, excessive fiber intake or specific SCFA profiles may promote pro-inflammatory responses, underscoring the importance of a balanced microbiota–host interaction [89,113]. Future studies are necessary to clarify the mechanisms through which different fiber sources and microbiota configurations modulate immune function and neuroinflammation, with the goal of optimizing dietary interventions for MS prevention and management.

The relationship between meat consumption and MS remains controversial. Evidence regarding red meat intake is inconsistent, even if some studies reported a higher risk of MS among patients with greater consumption of red and processed meats [90,129,131,132]. The potential adverse effects of red or processed meat could come from its components, such as saturated fatty acids, heme iron and sodium, as well as compounds formed during high-temperature cooking or industrial processing [120,121,122,123,124,125,126]. Mechanistically, the link between red meat consumption and MS pathophysiology may involve modulation of immune responses via alterations in gut microbiota composition and function [136]. Another mechanism could involve molecular mimicry, whereby dietary sialic acid derivatives may elicit cross-reactive immune responses against host neural antigens [137,138]. Overall, current evidence does not allow for clear conclusions, given the heterogeneity of study designs, dietary assessment methods, and population characteristics. Future research should aim to clarify the specific effects of different meat types, preparation methods, and associated dietary patterns.

Several studies have reported that immune responses directed against milk-derived proteins may aggravate disease activity, while others have described anti-inflammatory or neuroprotective properties associated with specific dairy components [149,156]. These inconsistencies likely reflect substantial heterogeneity in experimental design, the type and source of dairy products investigated and the technological processes involved in their production, and interindividual differences in genetic background and environmental exposures that shape immune tolerance. One explanation for the potential detrimental effects of dairy involves molecular mimicry mechanisms, whereby structural similarities between milk proteins and CNS antigens could trigger autoimmune cross-reactivity [147]. At the same time, findings indicate that the gut microbiota may act as an intermediary between dairy intake and host immune modulation. In this context, the metabolic activity of microbial communities and the bioactive compounds generated during fermentation could critically determine whether dairy consumption exerts pro- or anti-inflammatory effects. Taken together, the current body of research highlights the need for a deeper understanding of how dairy products influence MS pathophysiology.

The role of wheat proteins in MS has also been debated. In particular, gluten-free diet has been associated with improvements in EDSS, MRI lesion activity, fatigue and quality of life MS [162]. However, wheat contains not only gluten but also proteins as ATIs, which have been recently associated with inflammatory processes within CNS [163]. The current knowledge remains limited, and the available studies often include small sample sizes, heterogeneous populations, and potential confounding factors such as concurrent dietary modifications or lifestyle interventions. Therefore, while the hypothesis that gluten or other wheat-derived proteins may influence MS disease activity is plausible, further well-controlled, large-scale clinical and mechanistic studies are still required.

Studies have reported that pwMS treated with tryptophan supplementation experienced improvements in motor function, bladder disturbances, mood and memory performance [171,172]. Additionally, in EAE models, dietary tryptophan restriction impaired immune responses and altered gut microbiota composition [173]. These findings can be interpreted within the complex interactions of the gut–brain axis, highlighting the role of tryptophan metabolism by commensal bacteria in generating bioactive metabolites that can influence both immune regulation and neuronal activity. This emerging evidence suggests a potential therapeutic opportunity through microbiota-targeted dietary modulation of tryptophan metabolism in MS, but further studies are still required.

Overall, distinct dietary components, from fats and carbohydrates to fibers and amino acids, can exert divergent effects on MS pathogenesis via the microbiota–metabolite–immune axis. However, inconsistencies across models highlight the need for dose-controlled, longitudinal human studies to delineate causality and identify microbiota-derived biomarkers predictive of dietary response.

There is growing scientific interest in the role of diet due to its potential impact on health and the course of MS. Several studies have investigated the effects of diet and individual macronutrients on disease risk and progression, both in EAE and in MS. However, the majority of scientific evidence comes from animal models, while data in MS remains limited. Further targeted studies involving larger cohorts are needed to better understand whether certain foods may be more beneficial than others in promoting an anti-inflammatory environment with positive implications for disease outcomes. While it is unlikely that a single universally beneficial diet for MS patients can be identified, or that one macronutrient category can be recommended over others, clarifying the role of dietary components in relation to the disease could help to guide patients toward a healthy and balanced diet, with positive effects on their overall health. This would also support clinical practice, as physicians could recommend dietary patterns tailored to individual patient needs. Such an approach would not replace conventional therapies, but rather complement them, potentially enhancing both their efficacy and the patient's quality of life.