The primary causes of EAH include excessive fluid retention during exercise with a significant sodium deficit and excessive fluid intake leading to an increase in total body water resulting in a reduction in blood sodium levels.

Athlete-specific risk factors are being of female gender, use of non-steroidal anti-inflammatory drugs or NSAIDs, slow running, excessive fluid ingestion, low body weight, and event inexperience. Event-specific risk factors are high availability of drinking fluids, duration of exercise exceeds 4 hours, unusually hot environmental conditions, and extreme cold temperature.

In a published statement of the Third International Exercise-Associated Hyponatremia Consensus Development Conference, researchers concluded that drinking in accordance with the sensation of thirst is sufficient for preventing both dehydration and hyponatremia. This advice is contradicted by the American College of Sports Medicine, which has previously recommended athletes drink "as much as tolerable. In October of 2015, ACSM President W. Larry Kenney stated that “[T]he clear and important health message should be that thirst alone is not the best indicator of dehydration or the body’s fluid needs.”

In a letter to the editors of The Journal of Wilderness and Environmental Medicine, Brad L. Bennett, PhD claimed "perpetuation of the myth that one needs to drink beyond the dictates of thirst can be deadly." Similarly, authors of the Statement of the Third International Exercise-Associated Hyponatremia Consensus Development Conference claim this advice has "facilitated inadvertent overdrinking and pathological dilutional EAH."

Critics of the ACSM's view have questioned their motives, pointing out that Gatorade is one of the organizations "platinum sponsors."

The hypovolemia (extracellular volume loss) is due to total body sodium loss. The hyponatremia is caused by a relatively smaller loss in total body water.

- any cause of hypovolemia such as prolonged vomiting, decreased oral intake, severe diarrhea

- diuretic use (due to the diuretic causing a volume depleted state and thence ADH release, and not a direct result of diuretic-induced urine sodium loss)

- Addison's disease and congenital adrenal hyperplasia in which the adrenal glands do not produce enough steroid hormones (combined glucocorticoid and mineralocorticoid deficiency)

- pancreatitis

Prolonged periods of exercise may be a cause, known as exercise-associated hyponatremia (EAH). It is common in marathon runners and participants of other endurance events. The use of MDMA can result in hyponatremia. This likely occurs as a result of fluid loss via sweating and replacement with water without electrolytes.

There is volume expansion in the body, no edema, but hyponatremia occurs

- SIADH (and its many causes)

- Hypothyroidism

- Not enough ACTH

Excessive sodium and fluid intake:

- IV therapy containing sodium

- As a Transfusion reaction to a rapid blood transfusion.

- High intake of sodium

Sodium and water retention:

- Heart failure

- Liver cirrhosis

- Nephrotic syndrome

- Corticosteroid therapy

- Hyperaldosteronism

- Low protein intake

Fluid shift into the intravascular space:

- Fluid remobilization after burn treatment

- Administration of hypertonic fluids, e.g. mannitol or hypertonic saline solution

- Administration of plasma proteins, such as albumin

The incidence of SIADH rises with increasing age. Residents of nursing homes are at highest risk.

Congestive heart failure is the most common result of fluid overload. Also, it may be associated with hyponatremia (hypervolemic hyponatremia).

Hahner et al. investigated the frequency, causes and risk factors for adrenal crisis in patients with chronic adrenal insufficiency. Annane et al.'s landmark 2002 study found a very high rate of relative adrenal insufficiency among the enrolled patients with septic shock.

The normal human kidney, through suppression of anti-diuretic hormone, is normally able to excrete vast amounts of dilute urine. Thus a normal adult can drink up to 20 liters per day of water without becoming hyponatremic. However, the intake of solutes is also necessary to excrete free water. Under normal circumstances, this is clinically irrelevant. In the lack of proper solute intake, the amount of free water excretion can be severely limited. Without adequate solute intake, the normal functioning electrolyte gradient that pulls water into urine will be effectively destroyed.

Briefly, to excrete free water from urine, the urine flow (which is solute clearance + free water clearance) will equal the rate of solute excretion divided by the urine osmolality. With a diet of only solute poor beer, only about 200-300 mOSM (normal 750 mOSM to greater than 900 mOSM) of solute will be excreted per day, capping the amount of free water excretion at four liters. Any intake above 4 liters would lead to a dilution of the serum sodium concentration and thus hyponatremia.

Any vomiting or GI absorptive problems due to alcohol intoxication can also compound the effect of potomania due to additional electrolyte and acid-base disturbances.

While CSWS usually appears within the first week after brain injury and spontaneously resolves in 2–4 weeks, it can sometimes last for months or years. In contrast to the use of fluid restriction to treat SIADH, CSWS is treated by replacing the urinary losses of water and sodium with hydration and sodium replacement. The mineralocorticoid medication fludrocortisone can also improve the low sodium level.

Signs and symptoms of CSWS include large amounts of urination (at least 3 liters of urine output over a 24-hour period for adults) due to inadequate sodium retention in the body, high amounts of sodium in the urine, low blood sodium concentration, excessive thirst, extreme salt cravings, dysfunction of the autonomic nervous system, and dehydration. Patients often self-medicate by naturally gravitating toward a high-sodium diet and by dramatically increasing their water intake. Advanced symptoms include muscle cramps, lightheadedness, dizziness or vertigo, feelings of anxiety or panic (not mentally induced), increased heart rate or slowed heart rate, low blood pressure and orthostatic hypotension sometimes resulting in fainting. Other symptoms frequently associated with dysautonomia include: headaches, pallor, malaise, facial flushing, constipation or diarrhea, nausea, acid reflux, visual disturbances, numbness, nerve pain, trouble breathing, chest pains, loss of consciousness and seizures.

As with all cases of hyponatremia, extreme caution must be taken to avoid the fatal consequences of rapidly correcting electrolytes (e.g. Central pontine myelinolysis, edema). Special considerations with the treatment of potomania are needed. Because this could be a chronic condition, low sodium may be normal for the patient, so an especially careful correction is warranted. It is also very important to note that due to the normal kidney function, and lack of other intrinsic or toxic cause of the electrolyte disturbance, restoration of dietary solutes will correct the electrolytes to normal serum levels. This again must be done with caution.

A common pathological cause for a high BMR is fever, since a rise in body temperature increases the rate of cellular metabolic reactions. It is estimated that for every degree Fahrenheit of rise in body temperature, the BMR increases by 7 percent.

Thyroid disease also has a marked effect on BMR, since thyroid hormones regulate the rate of cellular metabolism. Hyperthyroidism—in which there is an increase in the production of thyroid hormones—leads to a high BMR, while hypothyroidism—in which thyroid hormones are depleted—causes a low BMR.

Prolonged periods of abnormal nutrition cause an adaptive change in BMR; this helps the body to maintain a stable body weight in response to the change in food supply. In prolonged malnutrition, the BMR declines, while in prolonged overnutrition, the BMR is increased. Cancer sometimes causes an increase in BMR, perhaps because the cancer cells that form tumors have a high level of metabolic activity.

An abnormal basal metabolic rate is not necessarily indicative of disease; a number of physiological factors can alter the BMR by influencing cellular metabolic activity. For instance, males are more likely than females to have a high BMR, and in women, the BMR may rise to abnormal levels during pregnancy or lactation. An individual's BMR varies greatly with age: infants and children typically have a high BMR, required for growth, while the elderly have a low BMR. Tall, thin people have a higher BMR than their shorter counterparts, even with the same weight, due to the greater surface area of their skin. The metabolic rate also decreases during sleep and increases in exercise, and individuals who exercise regularly have a higher BMR than those who are sedentary. Environmental temperature also has an effect: the BMR is increased in both heat and cold.

Adrenal crisis is triggered by physiological stress (such as trauma). Activities that have an elevated risk of trauma are best avoided. Treatment must be given within two hours of trauma and consequently it is advisable to carry injectable hydrocortisone in remote areas.

The most common cause of is overly rapid correction of low blood sodium levels (hyponatremia). Apart from rapid correction of hyponatraemia, there are case reports of central pontine myelinolysis in association with hypokalaemia, anorexia nervosa when feeding is started, patients undergoing dialysis and burns victims. There is a case report of central pontine myelinolysis occurring in the context of re-feeding syndrome, in the absence of hyponatremia.

It has also been known to occur in patients suffering withdrawal symptoms of chronic alcoholism. In these instances, occurrence may be entirely unrelated to hyponatremia or rapid correction of hyponatremia. It could affect patients who take some prescription medicines that are able to cross the blood-brain barrier and cause abnormal thirst reception - in this scenario the CPM is caused by polydipsia leading to low blood sodium levels (hyponatremia).

In schizophrenic patients with psychogenic polydipsia, inadequate thirst reception leads to excessive water intake, severely diluting serum sodium. With this excessive thirst combined with psychotic symptoms, brain damage such as CPM may result from hyperosmolarity caused by excess intake of fluids, (primary polydipsia) although this is difficult to determine because such patients are often institutionalised and have a long history of mental health conditions.

It has been observed following hematopoietic stem cell transplantation.

CPM may also occur in patients prone to hyponatraemia affected by

- severe liver disease

- liver transplant

- alcoholism

- severe burns

- malnutrition

- anorexia

- severe electrolyte disorders

- AIDS

- hyperemesis gravidarum

- hyponatremia due to Peritoneal Dialysis

- Wernicke encephalopathy

How to manage SIADH depends on whether symptoms are present, the severity of the hyponatremia, and the duration. Management of SIADH includes:

- Removing the underlying cause when possible.

- Mild and asymptomatic hyponatremia is treated with adequate solute intake (including salt and protein) and fluid restriction starting at 500 ml per day of water with adjustments based on serum sodium levels. Long-term fluid restriction of 1,200–1,800 mL/day may maintain the person in a symptom free state.

- Moderate and symptomatic hyponatremia is treated by raising the serum sodium level by 0.5 to 1 mmol per liter per hour for a total of 8 mmol per liter during the first day with the use of furosemide and replacing sodium and potassium losses with 0.9% saline.

- For people with severe symptoms (severe confusion, convulsions, or coma) hypertonic saline (3%) 1–2 ml/kg IV in 3–4 h should be given.

- Drugs

- Demeclocycline can be used in chronic situations when fluid restrictions are difficult to maintain; demeclocycline is the most potent inhibitor of Vasopressin (ADH/AVP) action. However, demeclocycline has a 2–3 day delay in onset with extensive side effect profile, including skin photosensitivity, and nephrotoxicity.

- Urea: oral daily ingestion has shown favorable long-term results with protective effects in myelinosis and brain damage. Limitations noted to be undesirable taste and is contraindicated in people with cirrhosis to avoid initiation or potentiation of hepatic encephalopathy.

- Conivaptan – an antagonist of both V and V vasopressin receptors.

- Tolvaptan – an antagonist of the V vasopressin receptor.

Raising the serum sodium concentration too rapidly may cause central pontine myelinolysis. Avoid correction by more than 12 mEq/L/day. Initial treatment with hypertonic saline may abruptly lead to a rapid dilute diuresis and fall in ADH.

Though traditionally, the prognosis is considered poor, a good functional recovery is possible. All patients at risk of developing refeeding syndrome should have their electrolytes closely monitored, including sodium, potassium, magnesium, glucose and phosphate.

Recent data indicate that the prognosis of critically ill patients may even be better than what is generally considered, despite severe initial clinical manifestations and a tendency by the intensivists to underestimate a possible favorable evolution.

While some patients die, most survive and of the survivors, approximately one-third recover; one-third are disabled but are able to live independently; one-third are severely disabled. Permanent disabilities range from minor tremors and ataxia to signs of severe brain damage, such as spastic quadriparesis and locked-in syndrome. Some improvements may be seen over the course of the first several months after the condition stabilizes.

The degree of recovery depends on the extent of the original axonal damage.

A study, in community dwelling older adults with an average age of 67 years, found the UK prevalence of sarcopenia to be 4.6% in men and 7.9% in women using the EWGSOP approach. Another study, conducted in the United States among older adults with an average age of 70.1 years, found the prevalence of sarcopenia to be 36.5%. Sarcopenia affects about half of people over 80 in one state in the USA.

While exercise is used to maintain muscle, bone and cardiac health during spaceflight, its effects on ICP and IOP have yet to be determined. The effects of resistive exercise on the development of ICP remains controversial. An early investigation showed that the brief intrathoractic pressure increase during a Valsalva maneuver resulted in an associated rise in ICP. Two other investigations using transcranial Doppler ultrasound techniques showed that resistive exercise without a Valsalva maneuver resulted in no change in peak systolic pressure or ICP. The effects of resistive exercise in IOP are less controversial. Several different studies have shown a significant increase in IOP during or immediately after resistive exercise.

There is much more information available regarding aerobic exercise and ICP. The only known study to examine ICP during aerobic exercise by invasive means showed that ICP decreased in patients with intracranial hypertension and those with normal ICP. They suggested that because aerobic exercise is generally done without Valsalva maneuvers, it is unlikely that ICP will increase during exercise. Other studies show global brain blood flow increases 20-30% during the transition from rest to moderate exercise.

More recent work has shown that an increase in exercise intensity up to 60% VOmax results in an increase in CBF, after which CBF decreases towards (and sometimes below) baseline values with increasing exercise intensity.

A link between increased ICP and altered sodium and water retention was suggested by a report in which 77% of IIH patients had evidence of peripheral edema and 80% with orthostatic retention of sodium and water. Impaired saline and water load excretions were noted in the upright position in IIH patients with orthostatic edema compared to lean and obese controls without IIH. However, the precise mechanisms linking orthostatic changes to IIH were not defined, and many IH patients do not have these sodium and water abnormalities. Astronauts are well known to have orthostatic intolerance upon reentry to gravity after long-duration spaceflight, and the dietary sodium on orbit is also known to be in excess of 5 grams per day in some cases. The Majority of the NASA cases did have high dietary sodium during their increment. The ISS program is working to decrease in-flight dietary sodium intake to less than 3 grams per day. Prepackaged foods for the International Space Station were originally high in sodium at 5300 mg/d. This amount has now been substantially reduced to 3000 mg/g as a result of NASA reformulation of over ninety foods as a conscious effort to reduce astronaut sodium intake.

Due to the lessened physical activity and increased longevity of industrialized populations, sarcopenia is emerging as a major health concern. Sarcopenia may progress to the extent that an older person may lose his or her ability to live independently. Furthermore, sarcopenia is an important independent predictor of disability in population-based studies, linked to poor balance, gait speed, falls, and fractures. Sarcopenia can be thought of as a muscular analog of osteoporosis, which is loss of bone, also caused by inactivity and counteracted by exercise. The combination of osteoporosis and sarcopenia results in the significant frailty often seen in the elderly population.

Obese women have an increased risk of pregnancy-related complications, including hypertension, gestational diabetes, and blood clots. Also, the mother is at risk of going into preterm labor. Maternal obesity is also known to be associated with increased rates of complications in late pregnancy such as cesarean delivery, and shoulder dystocia. A meta-analysis estimated that Cesarean delivery rates increased with odds ratios of 1.5 among overweight, 2 among obese, and 3 among severely obese women, compared with normal weight pregnant women. In addition, morbidly obese women who have not had children before are at increased risk of all–cause preterm deliveries. It is well recognized that obese women are at increased risk of preeclampsia and that women who have never been pregnant are at higher risk of preeclampsia than women who have had children in the past.

Since hyperinsulinemia and obesity are so closely linked it is hard to determine whether hyperinsulinemia causes obesity or obesity causes hyperinsulinemia, or both.

Obesity is characterized by an excess of adipose tissue – insulin increases the synthesis of fatty acids from glucose, facilitates the entry of glucose into adipocytes and inhibits breakdown of fat in adipocytes.

On the other hand, adipose tissue is known to secrete various metabolites, hormones and cytokines that may play a role in causing hyperinsulinemia. Specifically cytokines secreted by adipose tissue directly affect the insulin signalling cascade, and thus insulin secretion. Adiponectins are cytokines that are inversely related to percent body fat; that is people with a low body fat will have higher concentrations of adiponectins where as people with high body fat will have lower concentrations of adiponectins. Weyer "et al." (2011) reported that hyperinsulinemia is strongly associated with low adiponectin concentrations in obese people, though whether low adiponectin has a causal role in hyperinsulinemia remains to be established.

- May lead to hypoglycemia or diabetes

- Increased risk of PCOS

- Increased synthesis of VLDL (hypertriglyceridemia)

- Hypertension (insulin increases sodium retention by the renal tubules)

- Coronary Artery Disease (increased insulin damages endothelial cells)

- Increased risk of cardiovascular disease

- Weight gain and lethargy (possibly connected to an underactive thyroid)

Researchers from the NIH's National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK) conducted a study and found that early-onset paternal obesity is connected with an increased risk of liver disease in their kin. Researchers found that obese fathers had an elevated level of serum alanine aminotransferase (ALT), a liver enzyme, compared to fathers who were not obese. They did a secondary analysis that excluded obese offspring. Children who were a normal weight but had obese fathers still had elevated ALT levels, which indicated that a child's ALT levels are not dependent upon the child's own BMI.