Robert K. Rude

Functional hypoparathyroidism and parathyroid hormone end-organ resistance in human magnesium deficiency

Hypocalcaemia is a well‐recognized manifestation of magnesium deficiency. We have studied seventeen patients with this syndrome in an attempt to determine the pathogenesis of the hypocalcaemia. Mean initial serum calcium concentration was 5.6 mg/dl and mean initial serum magnesium concentration was 0.75 mg/dl. Serum immunoreactive parathyroid hormone (IPTH) was measured in sixteen patients in the untreated state. Despite severe hypocalcaemia, serum IPTH was either undetectable (<150 pg/ml) or normal (<550 pg/ml) in all but two patients. Serial measurments made during the initial 4 days of magnesium therapy in four patients showed an increase in serum IPTH within 24 h, but a delayed increase in serum calcium, which required approximately 4 days to reach normal values. The effect of the rapid normalization of serum magnesium on serum IPTH and serum calcium concentration was studied in three patients. Within 1 min after 144‐300 mg of elemental magnesium was administered i.v., serum IPTH had risen from undetectable to 3600 pg/ml and 1725 pg/ml in two patients and from 425 pg/ml to 937 pg/ml in the third. Serum calcium concentrations were unchanged after 30‐60 min. These data provide evidence for impaired parathyroid gland function in most of the magnesium deficient patients. The rapidity with which serum IPTH rose in response to magnesium therapy indicates that this may reflect a defect in parathyroid hormone (PTH) secretion rather than its biosynthesis. The failure of serum calcium concentration to increase during the initial days of magnesium repletion, at a time when serum IPTH concentrations were normal or elevated, suggests end‐organ resistance to PTH in these patients.

Blood pressure lowering by pioglitazone. Evidence for a direct vascular effect.

To examine potential mechanisms for the blood pressure-lowering action of the thiazolidinedione compound, pioglitazone (PIO), we studied the effects of the drug on blood pressure and insulin action in vivo and on vascular tissue in vitro. In vivo, PIO lowered blood pressure in fructose-fed and chow-fed rats to an extent that could not be explained by alterations in fasting plasma insulin or free magnesium concentrations or by alterations in whole-body insulin sensitivity. In vitro, PIO caused significant blunting of the contractile responses of aortic rings to NE, arginine vasopressin (AVP), and potassium chloride; the blunting of responses to NE was maintained after removal of the endothelium. To assess the potential importance of extracellular calcium to the vasodepressor effect of PIO, we measured contractile responses to NE in the absence of calcium, and then after acute restoration of calcium in the presence of NE. PIO had no effect on the contractile response in the absence of calcium. By contrast, PIO blunted by 42% the contractile response that occurred when the extracellular calcium supply was acutely restored in the presence of NE, suggesting that the blunting was mediated by blockade of calcium uptake by vascular smooth muscle. Such an effect was confirmed in cultured a7r5 vascular smooth muscle cells, which exhibited a brisk increase in intracellular calcium in response to AVP that was blocked by PIO in a dose-dependent fashion. Our data indicate that PIO has a direct vascular effect that appears to be mediated at least in part by inhibition of agonist-mediated calcium uptake by vascular smooth muscle. The direct vascular effect may contribute to the blood pressure-lowering actions of PIO in vivo, because that effect could not be explained by alterations in whole-body insulin sensitivity.

Magnesium Deficiency in Critical Illness

Magnesium (Mg) deficiency commonly occurs in critical illness and correlates with a higher mortality and worse clinical outcome in the intensive care unit (ICU). Magnesium has been directly implicated in hypokalemia, hypocalcemia, tetany, and dysrhythmia. Moreover, Mg may play a role in acute coronary syndromes, acute cerebral ischemia, and asthma. Magnesium regulates hundreds of enzyme systems. By regulating enzymes controlling intracellular calcium, Mg affects smooth muscle vasoconstriction, important to the underlying pathophysiology of several critical illnesses. The principle causes of Mg deficiency are gastrointestinal and renal losses; however, the diagnosis is difficult to make because of the limitations of serum Mg levels, the most common assessment of Mg status. Magnesium tolerance testing and ionized Mg2+ are alternative laboratory assessments; however, each has its own difficulties in the ICU setting. The use of Mg therapy is supported by clinical trials in the treatment of symptomatic hypomagnesemia and preeclampsia and is recommended for torsade de pointes. Magnesium therapy is not supported in the treatment of acute myocardial infarction and is presently undergoing evaluation for the treatment of severe asthma exacerbation, for the prevention of postcoronary bypass grafting dysrhythmias, and as a neuroprotective agent in acute cerebral ischemia.

Skeletal and Hormonal Effects of Magnesium Deficiency

Magnesium (Mg) is the second most abundant intracellular cation where it plays an important role in enzyme function and trans-membrane ion transport. Mg deficiency has been associated with a number of clinical disorders including osteoporosis. Osteoporosis is common problem accounting for 2 million fractures per year in the United States at a cost of over

Magnesium deficiency in a medical ICU population

17 billion dollars. The average dietary Mg intake in women is 68% of the RDA, indicating that a large proportion of our population has substantial dietary Mg deficits. The objective of this paper is to review the evidence for Mg deficiency-induced osteoporosis and potential reasons why this occurs, including a cumulative review of work in our laboratories and well as a review of other published studies linking Mg deficiency to osteoporosis. Epidemiological studies have linked dietary Mg deficiency to osteoporosis. As diets deficient in Mg are also deficient in other nutrients that may affect bone, studies have been carried out with select dietary Mg depletion in animal models. Severe Mg deficiency in the rat (Mg at <0.0002% of total diet; normal = 0.05%) causes impaired bone growth, osteopenia and skeletal fragility. This degree of Mg deficiency probably does not commonly exist in the human population. We have therefore induced dietary Mg deprivation in the rat at 10%, 25% and 50% of recommended nutrient requirement. We observed bone loss, decrease in osteoblasts, and an increase in osteoclasts by histomorphometry. Such reduced Mg intake levels are present in our population. We also investigated potential mechanisms for bone loss in Mg deficiency. Studies in humans and and our rat model demonstrated low serum parathyroid hormone (PTH) and 1,25(OH)2-vitamin D levels, which may contribute to reduced bone formation. It is known that cytokines can increase osteoclastic bone resorption. Mg deficiency in the rat and/or mouse results in increased skeletal substance P, which in turn stimulates production of cytokines. With the use of immunohistocytochemistry, we found that Mg deficiency resulted in an increase in substance P, TNFα and IL1β. Additional studies assessing the relative presence of receptor activator of nuclear factor kB ligand (RANKL) and its decoy receptor, osteoprotegerin (OPG), found a decrease in OPG and an increase in RANKL favoring an increase in bone resorption. These data support the notion at dietary Mg intake at levels not uncommon in humans may perturb bone and mineral metabolism and be a risk factor for osteoporosis.

Magnesium deficiency: effect on bone and mineral metabolism in the mouse.

The serum magnesium level was measured in 94 consecutive patients admitted to the medical ICU of Los Angeles County/University of Southern California Medical Center over a 2-month period. Sixty-five percent of patients with serum creatinine concentrations of 1.1 mg/dl or less were hypomagnesemic. Of these, one third had hypocalcemia that was corrected with magnesium supplementation. Physicians should be alert to the high incidence of magnesium deficiency in critically ill patients.

Intracellular Free Magnesium Deficiency Plays a Key Role in Increased Platelet Reactivity in Type II Diabetes Mellitus

Insufficient dietary magnesium (Mg) intake has been associated in humans with low bone mass. Mg deficiency in the rat has suggested bone loss is due to increased bone resorption and/or inadequate bone formation during remodeling. The purpose of this study was to assess the effect of a low Mg diet on bone and mineral metabolism in the young and mature BALB/c mouse and explore the hypothesis that inflammatory cytokines may contribute to Mg deficiency-induced osteoporosis. Using an artificial diet, we induced targeted Mg depletion (0.002% Mg) with all other nutrients maintained at the normal level. In all Mg-depleted mice, hypomagnesemia developed and skeletal Mg content fell significantly. The serum Ca in Mg-deficient mice was higher than in control mice; however, serum PTH levels were not significantly different. Osteoprotegerin (OPG) in dosages that inhibit osteoclastic bone resorption did not prevent hypercalcemia in Mg-deficient animals. No significant difference in serum Ca was observed between groups when dietary Ca was reduced by 50%, suggesting that a compensatory increase in intestinal absorption might account for the hypercalcemia. Growth plate width decreased 33% in young Mg-deficient animals and chondrocyte columns decreased in number and length, suggesting that Mg deficiency reduced bone growth. Trabecular bone volume in the metaphysis of the tibia in these animals was decreased and osteoclast number was increased by 135%. Osteoblast number was significantly reduced. Immunohistochemistry revealed that substance P increased 230% and 200% in megakaryocytes and lymphocytes, respectively, after 1 day of Mg depletion. IL-1 increased by 140% in osteoclasts by day 3 and TNFa increased in osteoclasts by 120% and 500% in megakaryocytes on day 12. This study demonstrates a profound effect of Mg depletion on bone characterized by impaired bone growth, decreased osteoblast number, increased osteoclast number in young animals, and loss of trabecular bone with stimulation of cytokine activity in bone.

Low blood mononuclear cell magnesium in intensive cardiac care unit patients

Objective Mg deficiency may be an important factor leading to cardiovascular disease. Diabetic subjects show an increase in platelet reactivity that can enhance the risks of vascular disease. In addition, diabetic patients have been reported to be at risk of developing extracellular Mg deficiency. However, the intracellular free Mg concentration and its role in the enhanced platelet reactivity in diabetes is not known. Research Design and Methods We evaluated the intracellular erythrocyte (RBC) Mg2+ concentration in 20 non-insulin-dependent (type II) diabetics. In addition, the effects of intravenous 3-h drip or 8 wk of oral Mg supplementation on intracellular RBC Mg2+ levels and platelet reactivity was studied. To more clearly evaluate the direct role of Mg in these effects, we induced isolated Mg deficiency in 16 nondiabetic control subjects with an Mg-free liquid diet for 3 wk. Results The intracellular RBC Mg2+ concentration of diabetic patients was significantly reduced compared with values in nondiabetic control subjects (166 ± 7 vs. 204 ± 7 μM, P < 0.01). Serum Mg levels were also reduced in the diabetic patients compared with the control subjects (1.59 ± 0.04 vs. 1.9 ± 0.1 mEq/L, P < 0.05). Oral Mg supplementation for 8 wk (400 mg/day) restored RBC Mg2+ concentration to normal without significantly changing serum Mg concentration. Both intravenous and oral Mg supplementation markedly reduced platelet reactivity in response to the thromboxane A2 analog, U46619. The Mg-free diet resulted in a significant reduction in RBC Mg2+ concentration and markedly enhanced the sensitivity of platelet aggregation to U46619 and ADP. Conclusions These results suggest that type II diabetic patients have intracellular Mg2+ deficiency and that Mg deficiency may be a key factor in leading to enhanced platelet reactivity in type II diabetes. Therefore, Mg supplementation may provide a new therapeutic approach to reducing vascular disease in patients with diabetes.

Magnesium deficiency: Possible role in osteoporosis associated with gluten-sensitive enteropathy

Magnesium deficiency may play a role in the pathogenesis of atherosclerosis, cardiac arrhythmias, and coronary spasm. Because less than 1% of magnesium (Mg) is extracellular, the serum magnesium (sMg) does not always accurately reflect intracellular Mg stores. To determine the frequency of Mg deficiency in patients with cardiovascular disease, we measured blood mononuclear cell Mg content (mMg) and sMg concentrations in 104 unselected patients admitted to our intensive cardiac care unit (CCU). Twenty-seven normal healthy controls and 33 hypomagnesemic patients with chronic alcoholism and/or malabsorption syndrome served as reference groups. The sMg concentration in the CCU patients was 2.05 +/- 0.03 mg/dl (mean +/- SEM), and did not differ from normal controls (mean 2.01 +/- 0.03 mg/dl). Only 8 of 104 CCU patients were hypomagnesemic (7.7%). mMg in the CCU patients, however, was significantly lower than in the normal controls (1.15 +/- 0.02 micrograms/mg protein and 1.34 +/- 0.02 micrograms/mg protein respectively, p less than 0.001). Fifty-three percent (55 of 104) of CCU patients had mMg contents less than 1.119 micrograms/mg protein, i.e., below that of the lowest normal control. mMg was significantly lower in those patients with congestive heart failure (mMg = 1.08 +/- 0.03 micrograms/mg protein) when compared to those patients without congestive heart failure (1.23 +/- 0.02 micrograms/mg protein, p less than 0.001). We conclude that the incidence of intracellular Mg deficiency in patients with cardiovascular disease is much higher than the sMg would lead one to suspect, and may contribute to clinical cardiovascular morbidity.

Oral Magnesium Supplementation Inhibits Platelet-Dependent Thrombosis in Patients With Coronary Artery Disease

Osteoporosis and magnesium (Mg) deficiency often occur in malabsorption syndromes such as gluten-sensitive enteropathy (GSE). Mg deficiency is known to impair parathyroid hormone (PTH) secretion and action in humans and will result in osteopenia and increased skeletal fragility in animal models. We hypothesize that Mg depletion may contribute to the osteoporosis associated with malabsorption. It was our objective to determine Mg status and bone mass in GSE patients who were clinically asymptomatic and on a stable gluten-free diet, as well as their response to Mg therapy. Twenty-three patients with biopsy-proven GSE on a gluten-free diet were assessed for Mg deficiency by determination of the serum Mg, red blood cell (RBC) and lymphocyte free Mg2+, and total lymphocyte Mg. Fourteen subjects completed a 3-month treatment period in which they were given 504−576 mg MgCl2 or Mg lactate daily. Serum PTH, 25-hydroxyvitamin D, 1,25-dihydroxyvitamin D and osteocalcin were measured at baseline and monthly thereafter. Eight patients who had documented Mg depletion (RBC Mg2+<150 µM) underwent bone density measurements of the lumbar spine and proximal femur, and 5 of these patients were followed for 2 years on Mg therapy. The mean serum Mg, calcium, phosphorus and alkaline phosphatase concentrations were in the normal range. Most serum calcium values fell below mean normal and the baseline serum PTH was high normal or slightly elevated in 7 of the 14 subjects who completed the 3-month treatment period. No correlation with the serum calcium was noted, however. Mean serum 25-hydroxyvitamin D, 1,25-dihydroxyvitamin D and osteocalcin concentrations were also normal. Despite only 1 patient having hypomagnesemia, the RBC Mg2+ (153±6.2 µM; mean ± SEM) and lymphocyte Mg2+ (182±5.5 µM) were significantly lower than normal (202±6.0 µM,p<0.001, and 198±6.8 µM,p<0.05, respectively). Bone densitometry revealed that 4 of 8 patients had osteoporosis of the lumbar spine and 5 of 8 had osteoporosis of the proximal femur (T-scores ≥−2.5). Mg therapy resulted in a significant rise in the mean serum PTH concentration from 44.6±3.6 pg/ml to 55.9±5.6 pg/ml (p<0.05). In the 5 patients given Mg supplements for 2 years, a significant increased in bone mineral density was observed in the femoral neck and total proximal femur. This increase in bone mineral density correlated positively with a rise in RBC Mg2+. This study demonstrates that GSE patients have reduction in intracellular free Mg2+, despite being clinically asymptomatic on a gluten-free diet. Bone mass also appears to be reduced. Mg therapy resulted in a rise in PTH, suggesting that the intracellular Mg deficit was impairing PTH secretion in these patients. The increase in bone density in response to Mg therapy suggests that Mg depletion may be one factor contributing to osteoporosis in GSE.