Magnesium deficiency
‘Hypomagnesemia is a relatively common occurrence in clinical medicine. That it often goes unrecognized is due to the fact that magnesium levels are rarely evaluated since few clinicians are aware of the many clinical states in which deficiency, or excess, of this ion may occur’.28
In developed countries, older data estimated that the prevalence of marginal magnesium deficit is 15%–20% of the population.15 This corroborates more recent data indicating that around 10%–30% of a given population has subclinical magnesium deficiency based on serum magnesium levels <0.80 mmol/L.29 The 2006 National Health and Nutrition Survey found low serum concentrations of magnesium in 36.3% and 31% of female and male Mexican adults, respectively.30 The authors of the study concluded: ‘Low serum concentrations of…magnesium are published for the first time and show significant prevalence of deficiencies’,30 and up to 20% of the general population has low serum magnesium levels.31 A systematic review of 37 articles discovered that magnesium deficiency was a possible public health concern for older adults.32
Magnesium deficiency has been found in 84% of postmenopausal women with osteoporosis diagnosed by low magnesium trabecular bone content and Thoren’s magnesium load test.33 Among apparently healthy university students in Brazil, 42% were found to have subnormal magnesium status (based on plasma or erythrocyte magnesium levels).13 The average magnesium intake was only around 215 mg/day. Magnesium depletion has been found in 75% and 30.8% of patients with poorly controlled type 2 diabetes based on serum and intracellular magnesium status, respectively.34
Magnesium deficiency can be present despite normal serum magnesium levels.6 Approximately 20% of 381 unselected elderly men and women (most of them in their 80s) were found to have low erythrocyte potassium and magnesium levels. The authors of the study concluded: ‘This study underlines the large prevalence of magnesium and potassium deficiencies in the elderly’.35 Another study concluded: ‘The commonly designated low limit of the normal range…is below levels that exist in patients with marginal deficiencies that can predispose to development of pathologic findings, so that the prevalence and importance of this disease is insufficiently considered…It is a statistical error to use the confidence limits of the normal population as the exclusion limit for those with abnormal Mg status’.36 In other words, our normal range of serum magnesium is inaccurate and that serum magnesium levels at the lower end of normal likely suggest marginal magnesium deficiency.29 Indeed, ‘The magnesium content of the plasma is an unreliable guide to body stores: muscle is a more accurate guide to the body content of this intracellular cation’.37
Another study highlighting the discrepancy between serum and body magnesium levels concluded: ‘Although serum-K and serum-Mg values in patients receiving long-term treatment for hypertension or incompensated heart disease usually are normal, muscle-Mg and muscle-K contents are reduced in around 50% of these patients…Evaluation of the K and Mg status during diuretic treatment should be preferentially based on tissue determinations. The muscle biopsy method is rapid, reliable and may reveal conditions of deficiency…oral supplements of Mg have proved to be adequate to restore the normal K/Mg status’.38
Among critically ill postoperative patients, 36.5% were found to have magnesium deficiency based on ionised magnesium levels in red blood cells.39 In one study of patients from a medical intensive care unit (ICU), 65% had hypomagnesaemia. The author concluded: ‘The prevalence of normomagnesemic Mg deficiency in critically ill patients may be even higher (than 65%, my insertion) and may contribute to the pathogenesis of hypocalcemia, cardiac arrhythmias and other symptoms of Mg deficiency’.40 Finally, 6.9%–11% of hospitalised patients have been noted to have hypomagnesaemia on routine exam posing on unrecognised need.41
The overall incidence of hypomagnesaemia in one study was noted to be between 5% and 8% of the overall population, and in young women (aged 18–22) the incidence was approximately 20%.5 One of the largest studies, a cross-sectional study in an unselected population of more than 16 000 subjects in Germany, found a prevalence of hypomagnesaemia (magnesium levels below 0.76 mmol/L) of 14.5%.5 42 Over 15% of hospitalised elderly patients have been found with low serum magnesium levels.43 Another study noted: ‘At ICU admission 52.5% had total hypomagnesemia and 13.5% total hypermagnesemia; with respect to the Mg(2+) 9.7% showed ionized hypomagnesemia and 23.6% ionized hypermagnesemia. Patients who developed ionized hypermagnesemia had higher mortality than patients without ionized hypermagnesemia development (P=0.04)’.44 And it has been noted that ‘Hypomagnesemia detected at the time of admission of acutely ill medical patients is associated with an increased mortality rate for both ward and medical ICU patients’.45 Magnesium depletion is present in about half of all ICU patients.46 More than 50% of those hospitalised with either of the following conditions are likely to be magnesium-deficient based on an intravenous retention >20%: hypertension, coronary artery disease, cerebrovascular event, gastrointestinal issues or alcoholism.47
Based on 183 peer-reviewed studies published from 1990 to 2008, one group of authors concluded: ‘The perception that ‘normal’ serum magnesium excludes deficiency is common among clinicians. This perception is probably enforced by the common laboratory practice of highlighting only abnormal results. A health warning is therefore warranted regarding potential misuse of ‘normal’ serum magnesium because restoration of magnesium stores in deficient patients is simple, tolerable, inexpensive and can be clinically beneficial’.48
One study found that 10 out of 11 apparently healthy women were magnesium-deficient based on the oral magnesium load test. The authors concluded: ‘The results showed there are more frequent deficiencies of magnesium in organisms than it is generally assumed’.49 Another study showed that 37.6% of patients with type 2 diabetes and 10.9% of age-matched and sex-matched healthy controls have low plasma magnesium levels.50
Of patients with severe chronic airway obstruction, 11.6% have serum magnesium levels less than the lower normal limit. The authors of the study concluded: ‘…routine serum magnesium determination is recommended in patients with chronic obstructive lung disease taking diuretic drugs or corticosteroids’.51
Hypomagnesaemia was identified in 47% of 1033 samples based on both routine magnesium determinations as well as physician-initiated requests for magnesium measurements.52 Importantly, only 10% of the hypomagnesaemia findings were found by physician-initiated requests, underscoring the fact that low magnesium blood levels are an overlooked issue by medical doctors.
About 80% of patients with hypertension treated for at least 6 months with either hydrochlorothiazide or a single non-diuretic drug have been found to have magnesium depletion based on retention of a parenterally administered magnesium load.53 More troubling is that despite being magnesium-depleted, patients treated with hydrochlorothiazide had high normal serum magnesium. This study underlines how patients can have normal or even higher magnesium levels in the blood despite magnesium depletion. Another study confirmed these findings that ‘thiazides induce a magnesium depletion not detectable by monitoring serum levels’.54 There is a correlation between low magnesium bone concentrations and increased magnesium retention after an intravenous magnesium load, suggesting that magnesium is retained in the bone after the test.55
After several weeks of strenuous physical activity, serum magnesium can increase with no change in erythrocyte magnesium levels despite a reduction in mononuclear cell magnesium levels. The authors of a study concluded that the reduction in mononuclear cell magnesium content ‘reflects a reduction in exchangeable magnesium body stores, and the onset of a magnesium deficiency state’.56 This study also indicates that just 6–12 weeks of strenuous physical activity can lead to magnesium deficiency. Another study concluded: ‘Serum and urinary magnesium concentrations decrease during endurance running, consistent with the possibility of magnesium deficiency. This may be related to increased demand in skeletal muscle’.57
One study found low levels of erythrocyte magnesium in 119 of 179 (66%) patients admitted consecutively to the ICU.58 The prevalence of hypomagnesaemia at ICU admission has been estimated at around 51.3%, with a prevalence of ionised hypomagnesaemia at ICU admission ranging between 14.4% and 22%.44
While a normal serum magnesium is considered to be 0.7–1 mmol/L, the optimal serum magnesium concentration has been proposed to be >0.80 mmol/L.59 Chronic latent magnesium deficiency has been defined as ‘…a serum magnesium concentration of between 0.75 and 0.849 mmol/L (within the reference interval), with a positive magnesium load test indicating magnesium deficiency’.14
In summary
‘Abnormalities of serum Mg may be the most underdiagnosed serum electrolyte abnormality in clinical practice today. The incidence appears to range from 12.5% to 20% on routine determination’.41