Abstract
Magnesium (Mg), an essential ion for the human body, is involved in various enzymatic reactions, particularly those related to energy transfer, storage, and transport. Longitudinal studies show that hypomagnesaemia (Mg serum concentration <0.75 mmol/L) and Mg dietary inadequacy (daily intake < EAR (Estimated Average Requirement) for age/gender) are conditions related to metabolic disorders of the immune and cardiovascular system and often occur in obese and diabetic individuals. Poor eating habits, reduced Mg content in food and water are the main causes of the decrease in Mg intake by the general population. In clinical practice, the serum concentration of this mineral is the most widely used marker for diagnosing deficiency. However, the serum concentration does not reflect the nutritional Mg status since it can be maintained by mobilization of body storage, mainly the bone. Thus, the use of serum concentration as the only routine biomarker of Mg status may hinder the diagnosis of Mg deficiency. In clinical and experimental research, different methods for Mg status assessment are proposed (plasma, erythrocyte, urine), but they are seldom used in clinical routine. In some countries (such as USA and Brazil) the average daily Mg dietary ingestion of more than 60% of the adult population is lower than the Estimated Average Requirement for age and gender, and these data are not too different for individuals with chronic non-communicable diseases. It is unclear whether it is an actual reduction of Mg consumption or if the recommendations are overestimated. If we assume that the recommendations are correct, the question is if this condition constitutes a risk factor for chronic diseases or the hypomagnesemia described in some diseases is a consequence of physiopathological changes. This review has the latest information of human and animal studies about Mg status evaluated from plasma, erythrocyte and urine, dietary inadequacy, and its relation to inflammation and to components of metabolic syndrome.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Background
Magnesium (Mg) is the fourth most prevalent cation in the human body and the second in intracellular concentration. It is a cofactor of more than 300 enzymatic reactions, in particular those related to DNA, RNA, and protein synthesis, and it is also an important factor in the control of cell proliferation [1, 2]. Mg exerts structural and also dynamic functions, for example, in formation of enzyme-substrate complexes, in allosteric activation of various reactions, in modulation of ion channels, and in stabilization of cell membranes. The most recognized function of Mg, associated to ATP, is the activation or deactivation of cellular signal transduction pathways, an example of which is insulin signaling [3, 4].
Evidence suggests that a disruption in Mg availability and metabolism could be considered the cause and/or result in pathological conditions such as cardiovascular diseases, hypertension, diabetes, and metabolic syndrome [4] due to the Mg role in the modulation of inflammation processes, carbohydrate metabolism, regulation of vascular tone, and myocardial metabolism [5]. In this context, we have focused this review in Mg status, dietary recommendations and the influence of Mg deficiency in the risk of diseases associated with inflammation and components of metabolic syndrome.
Mg compartmentalization and physiology
About 60% of body Mg is found in mineralized tissues (bones and teeth), and the remaining 40% is distributed in skeletal muscle and other tissues [6]. Serum Mg concentration is regulated by the balance between intestinal absorption (particularly in proximal jejunum and ileum), urinary excretion and reabsorption and retention and bone mobilization [7].
Mg intestinal absorption occurs by passive non-saturable transport when concentration in the intestinal lumen is above 20 mEq/L and by active saturable transport in intraluminal concentrations up to 20 mEq/L, the main mechanism of absorption in cases of dietary restriction. In this condition, TRPM6 channel (transient receptor potential, subfamily melastatin 6), an ion channel of approximately 230 kDa molecular weight fused with an α kinase is used. Abundant in the intestine (especially ileum, cecum and colon), it is also present in the apical membrane of the distal convoluted tubule of the kidney, and it is responsible for renal Mg reabsorption [8, 9]. Another channel, TRPM7, present in all cell types, may be an important sensor of Mg homeostasis. Both channels are downregulated by high intracellular levels of the mineral [10, 11].
Thus, the kidneys are essential for Mg homeostasis since they control Mg serum concentration mainly by modulating its excretion in urine. Under physiological conditions, approximately 2400 mg of plasma Mg are filtered by glomeruli, and of these, approximately 95% are readily absorbed, i.e., 3 to 5% are excreted in urine [12]. As mentioned before, the largest body Mg compartments are bone’s surface and matrix. In the bone surface, Mg functions as a buffer to maintain extracellular concentration constant: whenever there is a reduction in plasma Mg there is a rapid release of surface Mg attached to the bone into the blood compartment [13].
Reduction of plasma Mg concentrations between 0.4 to 0.5 mmol/L (severe hypomagnesemia) is a relatively rare condition, and it is often associated with electrolyte imbalance such as hypokalemia and metabolic acidosis. Signs and symptoms of severe hypomagnesemia include weakness, apathy, tetany, paresthesia, and arrhythmia [14, 15].
Dietary Mg recommendations
The major dietary sources of Mg are whole grains, dark green leafy vegetables, nuts, and vegetables [16]. Such foods are often present in the mediterranean diet, which is inversely associated with chronic non-communicable diseases [17, 18]. The US Department of Agriculture (USDA), based on the Dietary Guidelines for Americans, released MyPlate (replaced by the MyPyramid in 2011) in order to encourage the American people to make healthier food choices. In Brazil, the National Program of Food and Nutrition emphasizes practices that promote better nutrition and population health to encourage the population to consume healthy foods and decrease macro and micronutrients (including Mg) deficiencies in adults and children [19].
Mg nutritional requirements for adults were determined in balance studies [20]. The design of these studies must comply basic requirements such as sufficient length for variations in the approximately 12 days of metabolic adaptation to mineral intake and also the evaluation of the association between the consumption of habitual diet and Mg intake levels that can cause adverse effects. However, as some studies that were used to define the Mg recommendations were not strictly controlled there were speculations about the derived recommendations [20, 21]. In this context, a detailed study by Hunt and Johnson [22] analyzed 27 balance studies conducted by the US Department of Agriculture in order to define Mg recommendations for men and women. The authors concluded that the zero balance (when output equals intake) is achieved at intakes of about 165 mg/d Mg for healthy adults, regardless of age or sex. This suggests that the Estimated Average Requirement (EAR) for Mg in adults aged 19–50 years might be lower than that defined by the US Institute of Medicine [20]. The EAR of 165 mg found by Hunt and Johnson converts to an RDA of 237 mg/d [23] (considering EAR plus two standard deviations, as proposed by IOM) which is lower than the current RDA ranging from 310 to 420 mg/d [20].
Moreover, recent findings show that Mg intake of less than 250 mg/day associated or not with serum Mg concentration of 0.75 mmol/L sets a subclinical Mg deficiency, which may be related to pathological conditions [24]. The reduction in the Mg intake by the population is due to process that affect Mg content in food such as water purification, food processing, and the impact of high yield cultivars in lowering Mg concentrations of wheat and vegetable crops over the past 50 years [25, 26] and to change in dietary habits, for example, increased intake of refined and processed grains [27].
The European Food Safety Authority (EFSA) [28] used data from 13 dietary surveys made in healthy subjects (adults and children) in 9 countries of the European Union (EU) and proposed 350 and 300 mg/d Mg, respectively, as adequate intakes for adult men and women and between 170–300 mg/day Mg for children according to the age.
Briefly, there are still important issues to be informed about Mg recommendations, requiring strictly delineated research to discuss new recommendations for the intake of this mineral.
The questions are (1) are the DRIs [21] for Mg overestimated or at least overestimated for some populations? (2) Are the methods the authors have been using to determine Mg inadequacy comparable?
Although there are differences among Mg recommendations in different countries, the values are similar. On the other hand, it is important to have a method to evaluate inadequacy that takes into account within and between personal variations in dietary intake mesurements. The European recommendation uses half the consumption range of the reference population and not exactly the median as proposed by the DRI [20].
Biomarkers for assessment of Mg status
Currently, serum Mg is the most widely used parameter to evaluate Mg status in humans. However, serum compartment is less than 1% of the total content of body Mg, thus, the incorporation of other markers that reflect Mg body stock should be encouraged [29].
The determination of Mg levels in muscles and bones, the primary Mg stock compartments, allows reliable evaluation of Mg status and are widely used in experimental studies. However, this method is invasive and impractical for routine clinical use. Other methods that could easily be adapted to laboratory routine include determination of intracellular (leukocyte and erythrocyte), urinary, and fecal Mg concentrations [30]. The tolerance test can also be used to investigate Mg deficiency [31]. Once the patient is carefully monitored on an outpatient basis during the analysis, the test is safe, reproducible, and reliable.
Mg serum concentration used as the single biomarker to diagnose Mg deficiency should be considered with caution also because Mg depletion in cells and bones can coexist with normal serum levels [7, 32]. For example, Sales et al., in an animal study, observed that 70% dietary Mg restriction in association with increased fat intake resulted in reduced urinary Mg excretion and decreased bone Mg concentration without changes in plasma levels [33]. Likewise, obese women with low dietary Mg intake had low urinary excretion and plasma concentration but had normal erythrocyte Mg [34]. Therefore, defining and diagnosing Mg deficiency in the population is still a challenge, and the impact of Mg low consumption may be underestimated [1, 2].
Some interesting data show that the consumption of Mg by the population is not appropriate. For example, data from the National Health and Nutrition Examination Survey (NHANES, 2005–2006) indicated that approximately 60% of all American adults did not meet the recommended average intake (EAR) for Mg [35]. In Brazil, the Family Budget Survey (2008–2009) held in all regions of the country evaluated the dietary intake of 34,000 individuals through food records. A 70% probability of inadequate Mg intake mainly in urban areas was reported. Mg is one of the nutrients with the highest percentage of inadequacy in the age group of 19–59 years for both sexes, estimated by the proportion of individuals with consumption below the EAR of 255–265 mg/d for women and 330–350 mg/d for men) [36].
Another Brazilian study conducted with students from a public university found high frequency of what they called Mg subclinical deficiency. The average of plasma Mg in the studied population was close to the lower limit of the reference range (0.76 ± 0.06 mmol/L) and 17% of individuals had low Mg erythrocyte (<1.65 mmol/L). Additionally, a high probability of inadequate Mg intake around 70% for women and 94% for men was observed [37].
The Brazilian Osteoporosis Study (BRAZOS) that evaluated the intake of nutrients related to bone health found that only 20% of the participants reached the Mg daily recommendation (350 mg for men and 265 mg for women). The authors concluded that great part of the studied population had dietary Mg inadequacy but as biomarkers of Mg assessment were not evaluated the diagnose of Mg deficiency was jeopardized [38]. Urinary Mg is an indicator most useful for population studies to be a sensitive biomarker to changes in Mg status resulting from variations in Mg intake [39].
Rocha et al. [40], in the cross-sectional study with 50 pregnant women at a public university hospital in Brazil, evaluated the dietary intake and status of Mg and calcium (Ca). The results showed that despite the high probability of dietary inadequacy of Ca and Mg (58 and 98%, respectively), erythrocyte, and plasma levels of two minerals were adequate due to a strong reduction in their urinary excretion.
Literature is controversial as to the relation of dietary Mg inadequacy with some chronic diseases. On one hand, experimental studies with rats clearly demonstrated the impact of the Mg restriction on its status [41, 42], and on the other hand, human studies do not provide evidence that the moderately low Mg consumption necessarily leads to Mg deficiency [37, 43]. This fact is due possibly to differences in the level of restriction between human and animal studies. For instance, in experimental studies it is possible to impose moderate to severe restriction; in population studies, on the other hand, Mg inadequacy assessed through dietary evaluation is not too expressive. For example, the BRAZOS study in which 2344 people were evaluated, the lowest level of Mg individual intake was 138 mg/day, that is 52 and 40% of the EAR for women and men, respectively [38]. Gobbo et al. performed a systematic review and meta-analysis to investigate associations of circulating and dietary Mg with risk of cardiovascular disease and showed that Mg average intake in studies included was 289 mg/d (82% of the EAR) [44].
Mg and inflammation
Mg deficiency is a condition that causes changes in cell proliferation of the immune system, increases the production of proinflammatory molecules, and influences the onset or worsening of many diseases [24]. In recent decades, studies on Mg deficiency in rats have demonstrated changes in immune system cells evidenced by mast cells degranulation, increase in polymorphonuclear leukocytes and phagocytosis [45,46,47]. Changes in the thymus can also be observed in deficient animals. Rats fed diets with only 7% of the recommendation for rodents (35 mg/kg/diet) for a short period showed thymocytes with alterations in the expression of genes involved in the protection and repair of cells against oxidative stress [48]. Malpuech-Bregère et al. suggest that the activation of imune cells is the first consequence of severe acute (8 days) Mg restriction (32 mgMg/Kg) in weanling rats [46].
In humans, clinical and epidemiological studies suggest that Mg is associated with inflammatory process and oxidative stress. Data from a study conducted with individuals older than 51 years showed that 58% of them were consuming less than the EAR for Mg, and this fact was associated with increased plasma C-reactive protein [49]. A case-control study evaluated the Mg status and oxidative stress and inflammation in preeclampsia compared to a control group. They found that although Mg intake was below the EAR in both groups (did not achieve 85% probability of adequacy) only in pre-eclampsia the concentration of inflammatory cytokines and plasma and erythrocyte Mg were high. The authors suggest that the increased circulating levels of Mg may be a secondary effect of typical features of preeclampsia (vasoconstriction and peripheral vascular resistance) [50].
Sugimoto et al. [1] evaluated in vitro the immunomodulatory role of Mg in mononuclear cells from the maternal peripheral blood of women treated with MgSO 4 (6 mg/dL) and mononuclear cells from umbilical cord blood. The authors observed the reduction in TNF-α and IL-6 reduced expression of IkBα and NFkB activation. They also found in vitro that mononuclear cells exposed to 2.5 mM MgSO4 decreased the production of inflammatory cytokines after stimulation with different TLR ligands, suggesting that Mg possibly has a broad spectrum anti-inflammatory activity.
In USA, the Women’s Health Initiative Observational Study evaluated women of different ethnicities, aged 50–79 years, the association between dietary Mg intake and concentration of systemic inflammation biomarkers (CRP, IL-6, TNF-R2) and endothelial dysfunction (sICAM-1 and sVCAM-1) and E-selectin. The authors observed that an increase of 100 mg/d Mg intake was associated with a decrease in concentration of these inflammatory and endothelial biomarkers [51].
Given the above information, dietary Mg inadequacy seems to be associated to the emergence and evolution of diseases of inflammatory etiology such as obesity, insulin resistance, metabolic syndrome, and cardiovascular disease [34, 52, 53].
Mg and obesity, diabetes, and metabolic syndrome
Konishi et al. [54] showed that women in the highest quartile of Mg intake had significantly lower risk of diabetes when compared to women in the lowest quartile. They found no association between Mg intake and risk of diabetes in men. The differences between men and women are due to the fact that women have lower Mg body stores and consequently increased risk of Mg depletion. In China, Xu et al. [55] evaluated serum and urinary concentrations of Mg in groups with different morbidities. Subjects with type 1 diabetes (DM1, n = 25), type 2 diabetes with and without complications (DM2, n = 137), with change in fasting glucose (IFG, n = 12) or decreased glucose tolerance (IGT n = 15) were evaluated. The authors found that all groups had lower serum Mg concentrations compared to the matched control group and Mg urinary concentration was significantly higher in DM2 and DM1 groups compared to the control. In these cases, hyperinsulinemia and hyperglycemia may affect renal Mg transporters and, consequentely, urinary Mg excretion increases [56].
Wang et al. [57] described an inverse association between dietary Mg intake and glucose, insulin and HOMA-IR in 234 non-diabetic subjects of both genders and also the benefit of higher level of Mg intake from foods for glycemic control. In experimental conditions, rats under hyperlipidemic and moderately Mg-restricted (70% of recommendation) diet exhibited lower hepatic insulin sensitivity, as evidenced by reduced phosphorylation of IR β, Akt, and IRS-1, without any change in the circulating blood glucose or insulin levels [33]. This study draws attention to the molecular changes caused by the reduction of Mg intake prior to installation of insulin resistance.
Guerrero-Romero and Rodriguez-Moran [58] studied obese and non-obese individuals of both genders, aged 20–65 years, with and without metabolic alterations (hyperglycemia, insulin resistance, hypertension, and increased triglycerides). The authors found that hypomagnesemia was positively associated with these alterations in both groups. They also observed that in obese patients, hypomagnesemia was strongly related to high levels of triglycerides and insulin resistance. On the other hand, normomagnesemia was more frequent in healthy subjects. In obese children and adolescents, serum Mg levels were inversely correlated with the degree of obesity and positively with an unfavorable lipid profile, as well as high blood pressure [59].
Study with diabetic patients has demonstrated an inverse correlation between serum Mg and fasting insulin level. They also described a highly significant correlation between Mg and insulin sensitivity indices: homeostasis model assessment of insulin resistance (HOMA-IR) and quantitative insulin sensitivity check index (QUICKI) [60].
In spite of the number of studies that have established the relationship between minerals and components of MS, more research is required to evaluate the effects of increased Mg intake and the reduction of the risk for type 2 diabetes and cardiovascular disease. It is well established that Mg modulates vascular tonus, coronary blood flow, contractility, and excitability of heart muscle and that dietary Mg restriction may be related to increased risk factors for cardiovascular disease and atherosclerosis [61]. It is worth mentioning that there is no consensus on what level of intake is required to effectively reduce the risk of disease and also what level of restriction is related to adverse health outcomes.
Ferrè et al. [62] in experimental testing in vitro with human umbilical vein endothelial cells (HUVEC) evaluated the effects of 24 h Mg restriction on the path of NFkB by electrophoretic mobility shift assay (EMSA) and used proteomic analysis to investigate proteins involved in inflammation and atherogenesis. Their results showed major proteins in atherogenesis as RANTES, IL-8, PDGF-BB, TIMP-2, and GM-CSF, as well as activation of the NFkB in the culture medium with low concentration of Mg (0.1 mM).
In humans, authors have demonstrated the relationship between low Mg intake and increased cardiovascular risk factors. Among them, Bain et al. [63] investigated the association between dietary Mg and blood pressure, total cholesterol and risk of cardiovascular event in a random population of adult men and women (n = 4443) from the EPIC-Norfolk cohort (n ~ 25.639). They showed that low Mg consumption was associated with increase of blood pressure, total cholesterol, and risk of cardiovascular event. The results of this study suggest that increasing dietary Mg could positively impact hypertension and risk of cardiovascular accident in men and total cholesterol levels in both sexes.
A cross-sectional study of high relevance by Guerrero-Romero et al. [64] evaluated the association between of pre-hypertension and hypertension with serum Mg in healthy Mexican children. The study population was divided into two groups (n = 3954) aged 6 to 10 years and 11 to 15 years. The results showed that serum Mg levels < 0.74 mmol/L were associated with pre-hypertension and hypertension in the two groups. The cross-sectional study of Rodriguez-Moran and Guerrero-Romero [65] demonstrated, in adults the relationship between serum Mg concentration and pre-hypertension. This study included apparently healthy adult volunteers (n = 514), in Mexico. Of these, only 175 met all inclusion criteria and were divided into two groups: control (n = 107) and pre-hypertensive patients (n = 68). The pre-hypertensive individuals had lower serum Mg (0.73 mmol/L) and high triglyceride levels when compared to the control group. However, due to limitations of the studies (for example, lack of evaluation of other risk factors for hypertension and of habitual dietary Mg intake), more research is needed to clarify the relationship between Mg intake and hypertension in adults and children remained undefined.
In summary, low Mg consumption and decreased plasma Mg levels apparently are risk factors for cardiovascular disease associated with dyslipidemia, inflammation, and endothelial dysfunction. Thus, increasing Mg intake may be a useful approach to prevent these conditions. Nevertheless, it is noteworthy that Mg upper limit of ingestion is 350 mg/d through supplements, and population intervention possibilities should be evaluated with caution.
Conclusions
There is a growing number of studies conducted to elucidate the mechanisms by which reduced Mg consumption contributes to the etiology of chronic diseases. Nevertheless, it is not clear whether dietary Mg inadequacy predisposes to or increases the progression of metabolic diseases or both, or if these patological conditions lead to impairment of Mg homeostasis. Although there are many evidences that the reduction of Mg intake contributes to the development of chronic disease, it is not yet clear on what level of daily dietary intake it is processed in humans. In this scenario, biomarkers as Mg in plasm, urine, erytrocyte are important for Mg status assessment. Mg decompartmentalisation in cases of some morbidities and the effect of Mg supplementation before or after the onset of the disease deserve to be investigated.
Abbreviations
- CRP:
-
C-reactive protein
- EAR:
-
Estimated Average Intake
- GM-CSF:
-
Granulocyte macrophage-colony stimulating fator
- IKBα:
-
Nuclear factor of kappa light polypeptide gene enhancer in B-cells inhibitor, alpha
- IL:
-
Interleukin
- IL-6:
-
Interleukin 6
- MAGT1:
-
Mg2+ transporter 1
- Mg:
-
Mg
- MgSO4 :
-
Mg sulfate
- NFkB:
-
Nuclear transcription factor kappa B
- NK:
-
Natural killer
- NKG2D:
-
Natural killer group 2 member D
- PDGF:
-
Platelet-derived growth factor
- RDA:
-
Recommended Dietary Allowance
- sICAM-1:
-
Soluble intercellular adhesion molecule-1
- sVCAM-1:
-
Soluble vascular cell adhesion molecule-1
- TIMP:
-
Inhibitor of metalloprotease
- TLR:
-
Toll-like receptor
- TNFα:
-
Tumor necrosis factor alpha
- TNF-R2:
-
Tumor necrosis factor receptor 2
- TRPM6:
-
Transient potential melastatin type 6
- TRPM7:
-
Transient potential melastatin type 7
References
Sugimoto J, et al. Mg decreases inflammatory cytokine production: a novel innate immunomodulatory mechanism. J Immunol. 2012;188(12):6338–46.
Baaij JHF, Hoenderop JGJ, Bindels RJM. Regulation of Mg balance: lessons learned from human genetic disease. Clin Kidney J. 2012;5:15–24.
Rude RK. Mg homeostasis. Principles of Bone Biology, vol. 1. 3rd ed. 2002.
Wolf FI, Trapani V. Cell (patho)physiology of Mg. Clin Sci (Lond). 2008;114(1):27–35.
Baaij JH, Hoenderop JG, Bindels RJ. Mg in man: implications for health and disease. Physiol Rev. 2015;95(1):1–46.
Rude RK, Gruber HE. Mg deficiency and osteoporosis: animal and human observations. J Nutr Biochem. 2004;15:710–6.
Arnaud MJ. Update on the assessment of Mg status. Brit J Nutr. 2008;99(Suppl3):S24–33.
Houillier P. Mechanisms and regulation of renal Mg transport. Annu Rev Physiol. 2014;76:411–30.
Groenestege WMT, Hoenderop JG, Van den Heuvel L, Knoers N, Bindels RJ. The epithelial Mg2+channel transient receptor potential melastatin 6 is regulated by dietary Mg2+ content and estrogens. J Am Soc Nephrol. 2006;17:1035–43.
Schlingmann KP, Waldegger S, Konrad M, Chubanov V, Gudermann T. TRPM6 and TRPM7 – Gatekeepers of human Mg metabolism. Biochim Biophys Acta. 2007;17(72):813–21.
Ryazanova LV, Rondon LJ, Zierler S, Hu Z, Galli J, Yamaguchi TP, Mazur A, Fleig A, Ryazanov AG. TRPM7 is essential for Mg2+ homeostasis in mammals. Nat Commun. 2010;1:109.
Jahnen-Dechent WM. Mg basics. Clin Kidney J. 2012;5(Sup 1):3–14.
Alfrey AC, Miller NL, Trow R. Effect of age and Mg depletion on bone Mg pools in rats. J Clin Invest. 1974;54:1074–81.
Ayuk J, Gittoes NJL. How should hypomagnesaemia be investigated and treated? Clin Endocrinol. 2011;75:743–6.
Dimke H, Monnens L, Hoenderop JG, Bindels RJ. Evaluation of hypomagnesemia: lessons from disorders of tubular transport. Am J Kidney Dis. 2013;62(2):377–83.
Katcher HI, Legro RS, Kunselman AR, Gillies PJ, Demers LM, Bagshaw DM, et al. The effects of a whole grain-enriched hypocaloric diet on cardiovascular disease risk factors in men and women with metabolic syndrome. Am J Clin Nutr. 2008;87:79–90.
Khemayanto H, Shi B. Role of Mediterranean diet in prevention and management of type 2 diabetes. Chin Med J. 2014;127(20):3651–6.
Salas-Salvadó J, Bulló M, Estruch R, Ros E, Covas MI, Ibarrola Jurado N, et al. Prevention of diabetes with Mediterranean diets: a subgroup analysis of a randomized trial. Ann Intern Med. 2014;160:1–10.
United States Department of Agriculture. MyPyramid. Avaliable in: http://www.cnpp.usda.gov/MyPyramid. Acessed 12 July 2016.
Institute of Medicine. Dietary reference intakes: the essential guide to nutrient requirements. Washington (DC): National Academy Press; 2006.
WHO. Vitamin and mineral requirements in human nutrition. 2nd ed. Geneva: World Health Organization and Food and Agriculture Organization of the United Nations; 2004.
Hunt CD, Johnson LK. Mg requirement: new estimations for men and women by cross-sectional statistical analyses of metabolic Mg balance data. Am J Clin Nutr. 2006;84(4):843–52.
Rosanoff A, Weaver CM, Rude RK. Suboptimal Mg status in the United States: are the health consequences underestimated? Nutr Rev. 2012;70(3):153–64.
Nielsen FH. Effects of Mg depletion on inflammation in chronic disease. Curr Opin Clin Nutr Metab Care. 2014;17(6):525–30.
Kanadhia KC, Ramavataram DV, Nilakhe SP. Patel S.A study of water hardness and the prevalence of hypomagnesaemia and hypocalcaemia in healthy subjects of Surat district (Gujarat). Magnes Res. 2014;27(4):165–74.
Rosanoff A. Changing crop Mg concentrations: impact on human health. Plant Soil. 2013;368:139–53.
Esmaillzadeh A, Kimiagar M, Mehrabi Y, Azadbakht L, Hu FB, Willett WC. Dietary patterns, insulin resistance, and prevalence of the metabolic syndrome in women. Am J Clin Nutr. 2007;85:910–8.
European Food Safety Authority. Scientific opinion on dietary reference values for Mg. EFSA J. 2015;13(7):4186.
Witkowski M, Hubert J, Mazur A. Methods of assessment of Mg status in humans: a systematic review. Mg Research. 2011;24(4):163–80.
Sales CH, Rocha VS, Setaro L, Colli C. Magnésio urinário, plasmático e eritrocitário: validação do método de análise por espectrofotometria de absorção atômica com chama. Revista do Instituto Adolfo Lutz. 2012;71:685–90.
Gullestad L, Dolva LO, Waage A, Falch D, Fagerthun H, Kjekshus J. Mg deficiency diagnosed by an intravenous loading test. Scan J Clin Lab Invest. 1992;52:245–53.
William JH, Danzinger J. Mg deficiency and proton-pump inhibitor use:a clinical review. J Clin Pharmacol. 2015;00:1–9.
Sales CH, Santos AR, Cintra DE, Colli C, et al. Mg-deficient high-fat diet: effects on adiposity, lipid profile and insulin sensitivity in growing rats. Clin Nutr. 2014;33:879–88.
De Oliveira AR, Cruz KJ, Morais JB, Severo JS, de Freitas TE, Veras AL, et al. Mg status and its relationship with c-reactive protein in obese women. Biol Trace Elem Res. 2015;168(2):296–302.
Centers for Disease Control and Prevention (CDC) National Health and Nutrition Examination Survey. http://www.ars.usda.gov/SP2UserFiles/Place/80400530/pdf/0506/usual_nutrient_intake_vitD_ca_phos_mg_2005-06.pdf. Accessed 8 Jul 2016.
Instituto Brasileiro de Geografia e Estatística. Pesquisa de orçamentos familiares, 2008-2009. Análise do consumo alimentar pessoal no Brasil. Rio de Janeiro: Instituto Brasileiro de Geografia e Estatística; 2011.
Sales CH, Do Nascimento DA, De Medeiros ACQ, Lima KC, Pedrosa LFC, Colli C. There is chronic latent Mg deficiency in apparently healthy university students. Nutr Hosp. 2014;30:200–4.
Pinheiro MM, Schuch NJ, Genaro PS, Ciconelli RM, Ferraz MB, Martini LA. Nutrient intakes related to osteoporotic fractures in men and women-the Brazilian Osteoporosis Study (BRAZOS). Nutr J. 2009;8:6.
Nielsen FH, Johnson LA. Data from Controlled Metabolic Ward Studies Provide Guidance for the Determination of Status Indicators and Dietary Requirements for Magnesium. Biol Trace Elem Res. 2016;1–10. doi: 10.1007/s12011-016-0873-2.
Rocha VS, Lavanda I, Nakano EY, Ruano R, Zugaib M, Colli C. Calcium and Mg status is not impaired in pregnant women. Nutr Res. 2012;32(7):542–6.
Kramer JH, Mak IT, Phillips TM, Weglicki WB. Dietary Mg intake influences circulating pro-inflammatory neuropeptide levels and loss of myocardial tolerance to postischemic stress. Exp Biol Med. 2003;228(6):665–73.
Kramer JH, Spurney C, Iantorno M, Tziros C, Mak IT, Tejero-Taldo MI, Chmielinska JJ, Komarov AM, Weglicki WB. Neurogenic inflammation and cardiac dysfunction due to hypomagnesemia. Am J Med Sci. 2009;338(1):22–7.
Morais JB, Severo JS, de Oliveira AR, Cruz KJ, da Silva Dias TM, de Assis RC, Colli C, do Nascimento Marreiro D. Mg Status and Its Association with Oxidative Stress in Obese Women. Biol Trace Elem Res. 2016;175:1-6.
Del Gobbo LC, Imamura F, Wu JH, de Oliveira Otto MC, Chiuve SE, Mozaffarian D. Circulating and dietary Mg and risk of cardiovascular disease: a systematic review and meta-analysis of prospective studies. Am J Clin Nutr. 2013;98(1):160–7.
Bois P. Effect of Mg deficiency on mast cells and urinary histamine in rats. Br J Exp Pathol. 1963;44(2):151–5.
Malpuech-Brugère C, Nowacki W, Daveau M, et al. Inflammatory response following acute Mg deficiency in the rat. Biochimica Biophysica Acta. 2000;1501:91–8.
Tong GM, Rude RK. Mg deficiency in critical illness. J Intensive Care Med. 2005;20(1):3–17.
Petrault I, Zimowska W, Mathieu J, Bayle D, Rock E, Favier A, et al. Changes in gene expression in rat thymocytes identi¢ed by cDNA array support the occurrence of oxidative stress in early Mg deficiency. Biochim Biophys Acta. 2002;1586(1):92–8.
Nielsen FH, Johnson LK, Zeng H. Mg supplementation improves indicators of low Mg status and inflammatory stress in adults older than 51 years with poor quality sleep. Mg Research. 2010;23(4):158–68.
De Sousa Rocha V, Della Rosa FB, Ruano R, Zugaib M, Colli C. Association between Mg status, oxidative stress and inflammation in preeclampsia: a case-control study. Clin Nutr. 2015;34(6):1166–71.
Chacko AS, Song Y, Nathan L, et al. Relations of dietary Mg intake to biomarkers of inflammation and endothelial dysfunction in an ethnically diverse cohort of postmenopausal women. Diabetes Care. 2010;33(2):304–10.
Mazur A, Maier JA, Rock E, Gueux E, Nowacki W, Rayssiguier Y. Mg and the inflammatory response: Potential physiopathological implications. Arch Biochem Biophys. 2007;458(1):48–56.
Bertinato J, Xiao CW, Ratnayake WMN, Fernandez L, Lavergne C, Wood C, Swist E. Lower serum Mg concentration is associated with diabetes, insulin resistance, and obesity in south- asian and white canadian women but not men. Food Nutr Res. 2015;59:259–74.
Konishi K, Wada K, Tamura T, Tsuji M, Kawachi T2, Nagata C et al. Dietary Mg intake and the risk of diabetes in the Japanese community: results from the Takayama study. Eur J Nutr. 2015;21:1–8.
Xu J, Xu W, Yao H, Sun W, Zhou Q, Cai L. Associations of serum and urinary Mg with the pre-diabetes, diabetes and diabetic complications in the chinese northeast population. PLoS ONE. 2013;8(2):e56750.
Barbagallo M, Dominguez LJ. Mg and type 2 diabetes. World J Diabetes. 2015;6(10):1152–7.
Wang J, Persuitte G, Olendzki BC, Wedick NM, Zhang Z, Merriam PA. Dietary Mg intake improves insulin resistance among non-diabetic individuals with metabolic syndrome participating in a dietary trial. Nutrients. 2013;5(10):3910–9.
Guerrero-Romero F, Rodríguez-Morán M. Serum Mg in the metabolically-obese normal-weight and healthy-obese subjects. Eur J Intern Med. 2013;24:639–43.
Zaakouk AM, Hassan MA. Tolba OA. Serum Mg status among obese children and adolescents. Egypt Pediatr Assoc Gazette. 2015;64:32–37.
Chutia H. K. Association of serum Mg deficiency with insulin resistance in type 2 diabetes mellitus. J Lab Physicians. 2015;2:75–8.
Maier JAM, Corinne Malpuech-Brugere C, Zimowskab W, Rayssiguier Y, Mazur A. Low Mg promotes endothelial cell dysfunction: implications for atherosclerosis, inflammation and thrombosis. Biochim Biophys Acta. 2004;1689:13–21.
Ferrè S, Baldoli E, Leidi M, Maier JA. Mg deficiency promotes a pro-atherogenic phenotype in cultured human endothelial cells via activation of NFkB. Biochim Biophys Acta. 2010;1802(11):952–8.
Bain LK, Myint PK, Jennings A, Lentjes MA, Luben RN, Khaw KT, Wareham NJ, Welch AA. The relationship between dietary Mg intake, stroke and its major risk factors, blood pressure and cholesterol, in the EPIC-Norfolk cohort. Int J Cardiol. 2015;196:108–14.
Guerrero-Romero F, Rodríguez-Morán M, Hernández-Ronquillo G, Gómez-Díaz R, Pizano-Zarate ML, Wacher NH, et al. Low serum Mg levels and its association with high blood pressure in children. J Pediatr. 2016;168:93–98.e1.
Rodriguez-Moran M, Guerrero-Romero F. Hypomagnesemia and prehypertension in otherwise healthy individuals. Eur J intern Med. 2014;25:128–31.
Authors’ contributions
AR and FL performed the bibliographic research and writing. CC made the general supervision and textual revision. All authors read and approved the final manuscript.
Competing interests
The authors declare that they have no competing interests.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.
About this article
Cite this article
da Rocha Romero, A.B., da Silva Lima, F. & Colli, C. Mg status in inflammation, insulin resistance, and associated conditions. Nutrire 42, 6 (2017). https://doi.org/10.1186/s41110-017-0031-4
Received:
Accepted:
Published:
DOI: https://doi.org/10.1186/s41110-017-0031-4