Magnesium deficiency is a nutritional deficiency which can affect both plants and animals

Magnesium deficiency may refer to:

- Magnesium deficiency (plants)

- Magnesium deficiency (medicine)

- For the specific condition of low blood magnesium levels, see Hypomagnesemia

Diagnosis typically occurs during the first 6 months of life due to characteristic neurological symptoms. These symptoms include muscle spasms, tetany, and seizures. Laboratory testing indicates hypomagnesemia (decreased serum magnesium levels), hypocalcemia (decreased serum calcium levels), and little to no measurable parathyroid hormone levels. Diagnosis is confirmed with these symptoms and can be further solidified with genetic sequencing of the TRPM6 gene.

Hypomagnesemia with secondary hypocalcemia (HSH) is an autosomal recessive genetic disorder affecting intestinal magnesium absorption. Decreased intestinal magnesium reabsorption and the resulting decrease in serum magnesium levels is believed to cause lowered parathyroid hormone (PTH) output by the parathyroid gland. This results in decreased PTH and decreased serum calcium levels (hypocalcemia). This manifests in convulsions and spasms in early infancy which, if left untreated, can lead to mental retardation or death. HSH is caused by mutations in the TRPM6 gene.

Mild hypokalemia is often without symptoms, although it may cause elevation of blood pressure, and can provoke the development of an abnormal heart rhythm. Severe hypokalemia, with serum potassium concentrations of 2.5–3 meq/l (Nl: 3.5–5.0 meq/l), may cause muscle weakness, myalgia, tremor, and muscle cramps (owing to disturbed function of skeletal muscle), and constipation (from disturbed function of smooth muscle). With more severe hypokalemia, flaccid paralysis and hyporeflexia may result. Reports exist of rhabdomyolysis occurring with profound hypokalemia with serum potassium levels less than 2 meq/l. Respiratory depression from severe impairment of skeletal muscle function is found in many patients.

Hypokalemia can result from one or more of these medical conditions:

Abnormal heart rhythms and asystole are possible complications of hypermagnesemia related to the heart. Magnesium acts as a physiologic calcium blocker, which results in electrical conduction abnormalities within the heart.

Clinical consequences related to serum concentration:

- 4.0 mEq/l decreased reflexes

- >5.0 mEq/l Prolonged atrioventricular conduction

- >10.0 mEq/l Complete heart block

- >13.0 mEq/l Cardiac arrest

Note that the therapeutic range for the prevention of the pre-eclampsic uterine contractions is: 4.0-7.0 mEq/L. As per Lu and Nightingale, serum Mg concentrations associated with maternal toxicity (also neonate depression - hypotonia and low Apgar scores) are:

- 7.0-10.0 mEq/L - loss of patellar reflex

- 10.0-13.0 mEq/L - respiratory depression

- 15.0-25.0 mEq/L - altered atrioventricular conduction and (further) complete heart block

- >25.0 mEq/L - cardiac arrest

For a detailed description of magnesium homeostasis and metabolism see hypomagnesemia.

It can be asymptomatic, but these symptoms may be present:

- Fatigue

- Headache

- High blood pressure

- Hypokalemia

- Hypernatraemia

- Hypomagnesemia

- Intermittent or temporary paralysis

- Muscle spasms

- Muscle weakness

- Numbness

- Polyuria

- Polydipsia

- Tingling

- Metabolic alkalosis

Hyperaldosteronism, also aldosteronism, is a medical condition wherein too much aldosterone is produced by the adrenal glands, which can lead to lowered levels of potassium in the blood (hypokalemia) and increased hydrogen ion excretion (alkalosis).

This cause of mineralocorticoid excess is primary hyperaldosteronism reflecting excess production of aldosterone by adrenal zona glomerulosa. Bilateral micronodular hyperplasia is more common than unilateral adrenal adenoma.

Grass tetany or hypomagnesemic tetany, also known as grass staggers and winter tetany, is a metabolic disease involving magnesium deficiency, which can occur in such ruminant livestock as beef cattle, dairy cattle and sheep, usually after grazing on pastures of rapidly growing grass, especially in early spring.

Progressive symptoms may include grazing away from the herd, irritability, muscle twitching, staring, incoordination, staggering, collapse, thrashing, head thrown back, and coma, followed by death. However, clinical signs are not always evident before the animal is found dead.

The condition results from hypomagnesemia (low magnesium concentration in blood) which may reflect low magnesium intake, low magnesium absorption, unusually low retention of magnesium, or a combination of these. Commonly, apparent symptoms develop only when hypomagnesemia is accompanied by hypocalcemia (blood Ca below 8 mg/dL).

Low magnesium intake by grazing ruminants may occur especially with some grass species early in the growing season, due to seasonally low magnesium concentrations in forage dry matter. Some conserved forages are also low in magnesium and may be conducive to hypomagnesemia.

High potassium intake relative to calcium and magnesium intake may induce hypomagnesemia. A K/(Ca+Mg) charge ratio exceeding 2.2 in forages has been commonly considered a risk factor for grass tetany. Potassium fertilizer application to increase forage production may contribute to an increased K/(Ca+Mg) ratio in forage plants, not only by adding potassium to soil, but also by displacing soil-adsorbed calcium and magnesium by ion exchange, contributing to increased susceptibility of calcium and magnesium to leaching loss from the root zone during rainy seasons. In ruminants, high potassium intake results in decreased absorption of magnesium from the digestive tract.

Trans-aconitate, which accumulates in some grasses, can be a risk factor for hypomagnesemia in grazing ruminants. (Tetany has been induced in cattle by administration of trans-aconitate and KCl, where the amount of KCl used was, by itself, insufficient to induce tetany.) Relatively high levels of trans-aconitate have been found in several forage species on rangeland sites conducive to hypomagnesemia. Although at least one rumen organism converts trans-aconitate to acetate, other rumen organisms convert trans-aconitate to tricarballylate, which complexes with magnesium. Using rats as an animal model, oral administration of tricarballylate has been shown to reduce an animal's magnesium retention. Potassium fertilizer application results in increased concentration of aconitic acid in some grass species.

Ataxia can develop very abruptly or it can develop over time. Some signs and symptoms of ataxia are loss of balance, loss of muscle coordination in an arm, hand, or leg, difficulty walking, slur of speech, or difficulty swallowing. Ataxia is a non-specific condition characterized by a lack of voluntary movements to some degree. Rather than involving damage to the cerebellum, ataxia in EAST syndrome is due to the KCNJ10 mutation. In the brain, KCNJ10 is expressed in glial cells surrounding synapses and blood vessels as a K+ ion buffer. K+ is necessary to maintain a neuronal cell's membrane potential, and these glial cells are responsible for transferring K+ ions from sites of excess K+ to sites with deficient K+. KCNJ10 is a major potassium channel in these glial cells, and when this gene is mutated, these glial cells cannot properly clear K+ from the extracellular space and deliver K+ ions to places that need it. Excess K+ in these areas of synapse disturbs physiological excitability, resulting in symptoms of ataxia.

The treatment of ataxia depends on the cause, and there is not current research for EAST syndrome specific treatment; however, there are some general ways to improve disability from ataxia. The movement disorders associated with ataxia can be managed by pharmacological treatments and through physical therapy and occupational therapy to reduce disability. Physical therapy treatment is highly dependent on each individual and varies. A recent review states that physical therapy is effective, however, there is only moderate evidence to support this.

EAST syndrome is a syndrome consisting of epilepsy, ataxia (a movement disorder), sensorineural deafness (deafness because of problems with the hearing nerve) and salt-wasting renal tubulopathy (salt loss caused by kidney problems). The tubulopathy (renal tubule abnormalities) in this condition predispose to hypokalemic (low potassium) metabolic alkalosis with normal blood pressure. Hypomagnesemia (low blood levels of magnesium) may also be present.

EAST syndrome is also called SeSAME syndrome, as a syndrome of seizures, sensorineural deafness, ataxia, intellectual disability (mental retardation), and electrolyte imbalances. It is an autosomal recessive genetic disorder caused by mutations in the KCNJ10 gene, as discovered by Bockenhauer and co-workers. The KCNJ10 gene encodes the K+ channel Kir.4 (allowing K+ to flow into a cell rather than out) and is present in the brain, ear, and kidney.

Chvostek's sign is not a very specific sign of tetany as it may be seen in 10% to 25% of healthy adults. It is therefore not a reliable clinical sign for diagnosing latent tetany. The sensitivity is lower than that in the corresponding Trousseau sign as it is negative in 30% of patients with hypocalcemia. Due to the combination of poor sensitivity and specificity the clinical utility of this sign is reduced.

Hitting a point between the middle third and upper third of the line joining the angle of the mouth to the zygomatic process gives rise to only a contraction of the muscles of the mouth and nose.

Megaloblastic anemia (MA) is associated with GSE and is believed to be the result of B and folate deficiency. In GSE, it appears to be associated with the IgA-less phenotype. Unlike other forms of megaloblastic anemia, GSEA MA is not a form of autoimmune gastritis.

Pernicious anemia (PA). Pernicious anemia is associated with GSE and is believed to result primarily from malabsorption phenomena.

Iron-deficiency anemia. Iron-deficiency anemia (IDA) may be the only symptom for CD, detected in subclinical CD and is accompanied by a decrease in serum ferritin levels. This can cause addition problems (see:symptoms of IDA and certain conditions like such as Paterson-Brown Kelly (Plummer-Vinson). Whereas IDA is corrected on GF diet, refractory disease or gluten-sensitive malignancies can cause persistent IDA.

According to recent studies, calcifications of channels seen in dementia can also occur in specific brain areas such as the visual complex in the occipital lobe. Such calcium channel blockages can cause visual problems or partial field hallucinations (Paroxysmal visual manifestations). Other papers show a link between migraine, visual aura and cerebral calcifications. Disturbances may be followed by

convulsions and associated with gastrointestinal phenomena.

A common cause of chondrocalcinosis is calcium pyrophosphate dihydrate crystal deposition disease (CPPD).

Excessive calcium (due to hypomagnesemia) has a potential relationship with chondrocalcinosis, and magnesium supplementation may reduce or alleviate symptoms. In some cases, arthritis from injury can cause chondrocalcinosis.

Other causes of chondrocalcinosis include:

- Hypercalcaemia, especially when caused by hyperparathyroidism

- Arthritis

- Gout

- Wilson disease

- Hemochromatosis

- Ochronosis

- Hypothyroidism

- Hyperoxalemia

- Acromegaly

- osteoarthritis

Gestational diabetes is formally defined as "any degree of glucose intolerance with onset or first recognition during pregnancy". This definition acknowledges the possibility that a woman may have previously undiagnosed diabetes mellitus, or may have developed diabetes coincidentally with pregnancy. Whether symptoms subside after pregnancy is also irrelevant to the diagnosis.

A woman is diagnosed with gestational diabetes when glucose intolerance continues beyond 24–28 weeks of gestation.

The White classification, named after Priscilla White, who pioneered research on the effect of diabetes types on perinatal outcome, is widely used to assess maternal and fetal risk. It distinguishes between gestational diabetes (type A) and pregestational diabetes (diabetes that existed prior to pregnancy). These two groups are further subdivided according to their associated risks and management.

The two subtypes of gestational diabetes under this classification system are:

- Type A1: abnormal oral glucose tolerance test (OGTT), but normal blood glucose levels during fasting and two hours after meals; diet modification is sufficient to control glucose levels

- Type A2: abnormal OGTT compounded by abnormal glucose levels during fasting and/or after meals; additional therapy with insulin or other medications is required

Diabetes which existed prior to pregnancy is also split up into several subtypes under this system:

- Type B: onset at age 20 or older and duration of less than 10 years.

- Type C: onset at age 10–19 or duration of 10–19 years.

- Type D: onset before age 10 or duration greater than 20 years.

- Type E: overt diabetes mellitus with calcified pelvic vessels.

- Type F: diabetic nephropathy.

- Type R: proliferative retinopathy.

- Type RF: retinopathy and nephropathy.

- Type H: ischemic heart disease.

- Type T: prior kidney transplant.

An early age of onset or long-standing disease comes with greater risks, hence the first three subtypes.

Two other sets of criteria are available for diagnosis of gestational diabetes, both based on blood-sugar levels.

Criteria for diagnosis of gestational diabetes, using the 100 gram Glucose Tolerance Test, according to Carpenter and Coustan:

- Fasting 95 mg/dl

- 1 hour 180 mg/dl

- 2 hours 155 mg/dl

- 3 hours 140 mg/dl

Criteria for diagnosis of gestational diabetes according to National Diabetes Data Group:

- Fasting 105 mg/dl

- 1 hour 190 mg/dl

- 2 hours 165 mg/dl

- 3 hours 145 mg/dl

Chondrocalcinosis can be visualized on projectional radiography, CT scan, MRI, US, and nuclear medicine. CT scans and MRIs show calcific masses (usually within the ligamentum flavum or joint capsule), however radiography is more successful. At ultrasound, chondrocalcinosis may be depicted as echogenic foci with no acoustic shadow within the hyaline cartilage. As with most conditions, chondrocalcinosis can present with similarity to other diseases such as ankylosing spondylitis and gout.

Gestational diabetes is a condition in which a woman without diabetes develops high blood sugar levels during pregnancy. Gestational diabetes generally results in few symptoms; however, it does increase the risk of pre-eclampsia, depression, and requiring a Caesarean section. Babies born to mothers with poorly treated gestational diabetes are at increased risk of being too large, having low blood sugar after birth, and jaundice. If untreated, it can also result in a stillbirth. Long term, children are at higher risk of being overweight and developing type 2 diabetes.

Gestational diabetes is caused by not enough insulin in the setting of insulin resistance. Risk factors include being overweight, previously having gestational diabetes, a family history of type 2 diabetes, and having polycystic ovarian syndrome. Diagnosis is by blood tests. For those at normal risk screening is recommended between 24 and 28 weeks gestation. For those at high risk testing may occur at the first prenatal visit.

Prevention is by maintaining a healthy weight and exercising before pregnancy. Gestational diabetes is a treated with a diabetic diet, exercise, and possibly insulin injections. Most women are able to manage their blood sugar with a diet and exercise. Blood sugar testing among those who are affected is often recommended four times a day. Breastfeeding is recommended as soon as possible after birth.

Gestational diabetes affects 3–9% of pregnancies, depending on the population studied. It is especially common during the last three months of pregnancy. It affects 1% of those under the age of 20 and 13% of those over the age of 44. A number of ethnic groups including Asians, American Indians, Indigenous Australians, and Pacific Islanders are at higher risk. In 90% of people gestational diabetes will resolve after the baby is born. Women, however, are at an increased risk of developing type 2 diabetes.

Many people with long QT syndrome have no signs or symptoms.

Some people may experience the following symptoms:

- Fainting (or syncope). This may occur when the patient is emotionally or physically stressed. It is unusual in QT syndrome to have any signs before the person actually faints.

- Seizures

- Sudden death. If there is sudden death, and doctors suspect long QT syndrome as the cause, they may recommend that the family members of the deceased get tested for the disease.

Long QT syndrome (LQTS) is a condition which affects repolarization of the heart after a heartbeat. This results in an increased risk of an irregular heartbeat which can result in fainting, drowning, or sudden death. These episodes can be triggered by exercise or stress. Other associated symptoms may include hearing loss.

Long QT syndrome may be present at birth or develop later in life. The inherited form may occur by itself or as part of larger genetic disorder. Onset later in life may result from certain medications, low blood potassium, low blood calcium, or heart failure. Medications that are implicated include certain antiarrhythmic, antibiotics, and antipsychotics. Diagnosis is based on an electrocardiogram (EKG) finding a corrected QT interval of greater than 440 to 500 milliseconds together with clinical findings.

Management may include avoiding strenuous exercise, getting sufficient potassium in the diet, the use of beta blockers, or a implantable cardiac defibrillator. Without treatment there is a 50%, 10 year risk of death, for the inherited versions. With treatment this decreases to less than 1% over 20 years.

Long QT syndrome is estimated to affect 1 in 7,000 people. Females are affected more often than males. Most people with the condition develop symptoms before they are 40 years old. It is a relatively common cause of sudden death along with Brugada syndrome and arrhythmogenic right ventricular dysplasia. In the United States it results in about 3,500 deaths a year. The condition was first clearly described in 1957.

Although there are many signs and symptoms associated with PVCs, PVCs may have no symptoms at all. An isolated PVC is hard to catch without the use of a Holter monitor. PVCs may be perceived as a skipped heart beat, a strong beat, or a feeling of suction in the chest. They may also cause chest pain, a faint feeling, fatigue, or hyperventilation after exercise. Several PVCs in a row becomes a form of ventricular tachycardia (VT), which is a potentially fatal abnormal heart rhythm. Overall it has been seen that the symptom felt most by patients experiencing a PVC is the mere perception of a skipped heartbeat. The more frequently these contractions occur, the more likely there are to be symptoms, despite the fact that these beats have little effect of the pumping action of the heart and therefore cause minimal if any symptoms.

Some other possible signs and symptoms of PVCs:

- Abnormal ECG

- Irregular heart beat

- Dyspnea

- Dizziness

- Feeling your heart beat (palpitations)

- Feeling of occasional, forceful beats

- Increased awareness of your heart beat

- Perception of a skipped heartbeat

Anorexia nervosa is an eating disorder characterized by attempts to lose weight, to the point of starvation. A person with anorexia nervosa may exhibit a number of signs and symptoms, the type and severity of which may vary and may be present but not readily apparent.

Anorexia nervosa, and the associated malnutrition that results from self-imposed starvation, can cause complications in every major organ system in the body. Hypokalaemia, a drop in the level of potassium in the blood, is a sign of anorexia nervosa. A significant drop in potassium can cause abnormal heart rhythms, constipation, fatigue, muscle damage and paralysis.

Symptoms may include:

- A low body mass index for one's age and height.

- Amenorrhea, a symptom that occurs after prolonged weight loss; causes menses to stop, hair becomes brittle, and skin becomes yellow and unhealthy.

- Fear of even the slightest weight gain; taking all precautionary measures to avoid weight gain or becoming "overweight".

- Rapid, continuous weight loss.

- Lanugo: soft, fine hair growing over the face and body.

- An obsession with counting calories and monitoring fat contents of food.

- Preoccupation with food, recipes, or cooking; may cook elaborate dinners for others, but not eat the food themselves or consume a very small portion.

- Food restrictions despite being underweight or at a healthy weight.

- Food rituals, such as cutting food into tiny pieces, refusing to eat around others and hiding or discarding of food.

- Purging: May use laxatives, diet pills, ipecac syrup, or water pills to flush food out of their system after eating or may engage in self-induced vomiting though this is a more common symptom of bulimia.

- Excessive exercise including micro-exercising, for example making small persistent movements of fingers or toes.

- Perception of self as overweight, in contradiction to an underweight reality.

- Intolerance to cold and frequent complaints of being cold; body temperature may lower (hypothermia) in an effort to conserve energy due to malnutrition.

- Hypotension or orthostatic hypotension.

- Bradycardia or tachycardia.

- Depression, anxiety disorders and insomnia.

- Solitude: may avoid friends and family and become more withdrawn and secretive.

- Abdominal distension.

- Halitosis (from vomiting or starvation-induced ketosis).

- Dry hair and skin, as well as hair thinning.

- Chronic fatigue.

- Rapid mood swings.

- Having feet discoloration causing an orange appearance.

- Having severe muscle tension + aches and pains.

- Evidence/habits of self harming or self-loathing.

- Admiration of thinner people.