The Role of Vitamins and Minerals on the Immune System

Alpert, Patricia T.

doi:10.1177/1084822317713300

Cited by 90 publications

(105 citation statements)

References 8 publications

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“…Iron Involved in regulation of cytokine production and action [3]; required for generation of pathogen-killing ROS by neutrophils during oxidative burst [7] Copper Accumulates at sites of inflammation [7,35]; part of copper/zinc-superoxide dismutase, a key enzyme in defense against ROS [8]; free-radical scavenger [58]; changes in copper homeostasis a crucial component of respiratory burst [8]; important for IL-2 production and response [7,35]; maintains intracellular antioxidant balance, suggesting important role in inflammatory response [8] Selenium Essential for function of selenoproteins that act as redox regulators and cellular antioxidants, potentially counteracting ROS produced during oxidative stress [2] Magnesium Can help to protect DNA against oxidative damage [37]; high concentrations reduce superoxide anion production [59] Differentiation, proliferation and normal functioning of T cells Vitamin A Involved in development and differentiation of Th1 and Th2 cells [60]; enhances TGF-β-dependent conversion of naïve T cells into regulatory T cells [8]; plays a role in acquisition of mucosal-homing properties by T and B cells [8] Vitamin D Homing of T cells to the skin [61]; calcitriol inhibits T-cell proliferation [7]; inhibitory effects mainly in adaptive immunity (e.g., Th1-cell activity) [7]; stimulatory effects in innate immunity [7]; inhibits the effector functions of T helper cells and cytotoxic T cells [27,62], but promotes the production of Tregs [27,62,63]; inhibitory effect on the differentiation and maturation of the antigen-presenting DCs, and helps program DCs for tolerance [27,[64][65][66] Vitamin C Roles in production, differentiation, and proliferation of T cells, particularly cytotoxic T cells [3,21] Vitamin E Enhances lymphocyte proliferation and T-cell-mediated functions [3]; optimizes and enhances Th1 response [3] Vitamin B6 Involved in lymphocyt...…”

Section: Immune Function Roles Micronutrient Commentsmentioning

confidence: 99%

“…Through the Fenton reaction, H 2 O 2 oxidizes ferrous iron to generate highly reactive OH − [89]. Through a Fenton-like reaction, copper can also catalyze the formation of ROS and is thus used to kill pathogens [8,90], while it also acts as a free-radical scavenger [58]. Magnesium helps to protect DNA against oxidative damage and is involved in the regulation of apoptosis [37].…”

Section: Natural Killer Cells and Phagocytesmentioning

confidence: 99%

“…The body requires optimal levels of micronutrients for effective immune function, with different requirements throughout every stage of life [2]. It is well established that overt (clinical) micronutrient deficiencies adversely affect the immune system and predispose individuals to infections [58,[106][107][108] ( Table 2). For example, micronutrient deficiency is known to increase the risk of morbidity and mortality associated with measles, pneumonia, and diarrheal disease [58,[109][110][111]-all common infections encountered worldwide and among the leading causes of death [112].…”

Section: Impact Of Micronutrient Status On the Immune Response And Rimentioning

confidence: 99%

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A Review of Micronutrients and the Immune System–Working in Harmony to Reduce the Risk of Infection

2020

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Immune support by micronutrients is historically based on vitamin C deficiency and supplementation in scurvy in early times. It has since been established that the complex, integrated immune system needs multiple specific micronutrients, including vitamins A, D, C, E, B6, and B12, folate, zinc, iron, copper, and selenium, which play vital, often synergistic roles at every stage of the immune response. Adequate amounts are essential to ensure the proper function of physical barriers and immune cells; however, daily micronutrient intakes necessary to support immune function may be higher than current recommended dietary allowances. Certain populations have inadequate dietary micronutrient intakes, and situations with increased requirements (e.g., infection, stress, and pollution) further decrease stores within the body. Several micronutrients may be deficient, and even marginal deficiency may impair immunity. Although contradictory data exist, available evidence indicates that supplementation with multiple micronutrients with immune-supporting roles may modulate immune function and reduce the risk of infection. Micronutrients with the strongest evidence for immune support are vitamins C and D and zinc. Better design of human clinical studies addressing dosage and combinations of micronutrients in different populations are required to substantiate the benefits of micronutrient supplementation against infection.

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Section: Immune Function Roles Micronutrient Commentsmentioning

confidence: 99%

Section: Natural Killer Cells and Phagocytesmentioning

confidence: 99%

Section: Impact Of Micronutrient Status On the Immune Response And Rimentioning

confidence: 99%

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A Review of Micronutrients and the Immune System–Working in Harmony to Reduce the Risk of Infection

2020

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“…Micronutrients have vital roles in the human health and the immune system that are independent of the life stage. Essential micronutrients include vitamins and mineral compounds such as fluoride, selenium, sodium, iodine, copper, and zinc (Zn; Alpert, 2017; Black, 2003). An inadequate intake of micronutrients affects the human immune system which then reduces our resistance to diseases.…”

Section: Introductionmentioning

confidence: 99%

Foliar applied zinc increases yield, zinc concentration, and germination in wheat genotypes

et al. 2020

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Human malnutrition associated with zinc (Zn) deficiency is a growing problem in many areas. This study was conducted to assess wheat (Triticum aestivum L.) genotypic variation of grain Zn concentration, grain germination, and grain yield in response to foliar application of Zn. Twenty-four wheat genotypes, including several recombinant inbred lines (RILs) and commercial cultivars, were assessed in two separate experiments; one experiment sprayed with ZnSO 4 ⋅7H 2 O dissolved in water at wheat heading growth stage and one without applying Zn foliar treatment. The range for grain (25.1-63.1) and endosperm (1.2-61.6 mg kg −1 ) Zn concentrations were different between the two Zn treatments. Significant (p = .05) genotype × Zn treatment interactions showed that some genotypes were more responsive to Zn applications than others. The application of Zn increased the Zn concentration in the endosperm in 18 out of the 24 genotypes. For grain, Zn application increased the concentration in the grain in 21 out of the 24 genotypes. Grain yield and germination were increased in the Zn treated cultivars compared with non-treated. In conclusion, foliar application of Zn improved traits in wheat, and identified genetic variation lays the foundation for genotype selection with respect to higher Zn concentration.Abbreviations: CCA, canonical correlation analysis; CIMMYT, international maize and wheat improvement center; DTZ, diphenyl-thiocarbazone; GCV, genotypic coefficients of variations; GE, germination energy; GS, germination speed; GV, germination value; MTG, mean time of germination; PCA, principal component analysis; PCV, phenotypic coefficients of variations; RCBD, randomized complete block design; RIL, recombinant inbred line; TPN, total pixel number.

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“…Lacking adequate nutrition, the immune system is clearly deprived of the components needed to generate an effective immune response. Various micronutrients are essential for immune competence, particularly vitamins A, C, D, E, B2, B6, and B12, folic acid, iron, selenium, and zinc [1], [2], [3], [4]. For example, vitamin A deficiency impairs mucosal barriers and diminishes the function of neutrophils, macrophages, and NK cells [5].…”

Section: Introductionmentioning

confidence: 99%

A randomized observational analysis examining the correlation between patients’ food sensitivities, micronutrient deficiencies, oxidative stress response and immune redox status

Steele¹,

Allright²,

Deutsch³

2020

FFHD

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Background: Malnutrition due to insufficient intake of micronutrients, or due to impaired delivery of micronutrients to patients’ cells, is suppressing immune functions that are fundamental to host protection. Concurrently, an excessive triggering of patients’ immune reactions as the result of adverse responses to certain food antigens, can also lead to various chronic health conditions.Objective: To examine nutritional and immunological status in patients’ groups varying in age, dietary regimens and gastrointestinal condition; and explore a possible correlation between an impaired patients’ immune status and micronutrient deficiencies, food sensitivity and oxidative stress responses.Methods: This is a population-based study consisting of a American residents, age 13 and older, who completed the investigator’s provided questionnaires with application of cell-based individualized functional assays. Data for this paper were collected from 845 individuals between May and September 2019, as part of CSS CNA beta study. Micronutrient deficiencies, immune Redox status, antioxidative responses and food sensitivity profiles were assessed for each patient participating in this study.Results: The group of patients with low Redox status demonstrated significantly higher percent of immune reactivity (17%) to food antigens as compared to15% reactivity detected in the groups with the average and strong Redox response. An average number of identified micronutrient deficiencies, as well as beneficial anti-oxidative protective compounds, was also significantly higher in the group with the weak immune function as compared to other two groups.Conclusion: This study suggests that high food sensitivity is associated with a higher nutrient deficiency, a stronger oxidative stress response and a lower immune redox status.

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The Role of Vitamins and Minerals on the Immune System

Cited by 90 publications

References 8 publications

A Review of Micronutrients and the Immune System–Working in Harmony to Reduce the Risk of Infection

A Review of Micronutrients and the Immune System–Working in Harmony to Reduce the Risk of Infection

Foliar applied zinc increases yield, zinc concentration, and germination in wheat genotypes

A randomized observational analysis examining the correlation between patients’ food sensitivities, micronutrient deficiencies, oxidative stress response and immune redox status

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