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Causes of increased anion gap include:
- Lactic acidosis
- Ketoacidosis
- Chronic renal failure (accumulation of sulfates, phosphates, urea)
- Intoxication:
- Organic acids, salicylates, ethanol, methanol, formaldehyde, ethylene glycol, paraldehyde, isoniazid
- Sulfates, metformin
- Massive rhabdomyolysis
A mnemonic can also be used - MUDPILES
- M-Methanol
- U-Uremia (chronic kidney failure)
- D-Diabetic ketoacidosis
- P-Paraldehyde
- I-Infection, Iron, Isoniazid, Inborn errors of metabolism
- L-Lactic acidosis
- E-Ethylene glycol (Note: Ethanol is sometimes included in this mnemonic, as well, although the acidosis caused by ethanol is actually primarily due to the increased production of lactic acid found in such intoxication.)
- S-Salicylates
In the fetus, the normal range differs based on which umbilical vessel is sampled (umbilical vein pH is normally 7.25 to 7.45; umbilical artery pH is normally 7.20 to 7.38). In the fetus, the lungs are not used for ventilation. Instead, the placenta performs ventilatory functions (gas exchange). Fetal respiratory acidemia is defined as an umbilical vessel pH of less than 7.20 and an umbilical artery PCO of 66 or higher or umbilical vein PCO of 50 or higher.
Metabolic acidosis occurs when the body produces too much acid, or when the kidneys are not removing enough acid from the body. Several types of metabolic acidosis occur. The main causes are best grouped by their influence on the anion gap.
The anion gap can be spuriously normal in sampling errors of the sodium level, e.g. in extreme hypertriglyceridemia. The anion gap can be increased due to relatively low levels of cations other than sodium and potassium (e.g. calcium or magnesium).
Respiratory acidosis results from a build-up of carbon dioxide in the blood (hypercapnia) due to hypoventilation. It is most often caused by pulmonary problems, although head injuries, drugs (especially anaesthetics and sedatives), and brain tumors can cause this acidemia. Pneumothorax, emphysema, chronic bronchitis, asthma, severe pneumonia, and aspiration are among the most frequent causes. It can also occur as a compensatory response to chronic metabolic alkalosis.
One key to distinguish between respiratory and metabolic acidosis is that in respiratory acidosis, the CO is increased while the bicarbonate is either normal (uncompensated) or increased (compensated). Compensation occurs if respiratory acidosis is present, and a chronic phase is entered with partial buffering of the acidosis through renal bicarbonate retention.
However, in cases where chronic illnesses that compromise pulmonary function persist, such as late-stage emphysema and certain types of muscular dystrophy, compensatory mechanisms will be unable to reverse this acidotic condition. As metabolic bicarbonate production becomes exhausted, and extraneous bicarbonate infusion can no longer reverse the extreme buildup of carbon dioxide associated with uncompensated respiratory acidosis, mechanical ventilation will usually be applied.
Respiratory alkalosis is caused by hyperventilation, resulting in a loss of carbon dioxide. Compensatory mechanisms for this would include increased dissociation of the carbonic acid buffering intermediate into hydrogen ions, and the related excretion of bicarbonate, both of which lower blood pH. Hyperventilation-induced alkalosis can be seen in several deadly central nervous system diseases such as strokes or Rett syndrome.
Metabolic alkalosis can be caused by repeated vomiting, resulting in a loss of hydrochloric acid in the stomach contents. Severe dehydration, and the consumption of alkali are other causes. It can also be caused by administration of diuretics and endocrine disorders such as Cushing's syndrome. Compensatory mechanism for metabolic alkalosis involve slowed breathing by the lungs to increase serum carbon dioxide, a condition leaning toward respiratory acidosis. As respiratory acidosis often accompanies the compensation for metabolic alkalosis, and vice versa, a delicate balance is created between these two conditions.
Metabolic alkalosis is usually accompanied by low blood potassium concentration, causing, e.g., muscular weakness, muscle pain, and muscle cramps (from disturbed function of the skeletal muscles), and muscle spasms (from disturbed function of smooth muscles).
It may also cause low blood calcium concentration. As the blood pH increases, blood transport proteins, such as albumin, become more ionized into anions. This causes the free calcium present in blood to bind more strongly with albumin. If severe, it may cause tetany.
Compensation for metabolic alkalosis occurs mainly in the lungs, which retain carbon dioxide (CO) through slower breathing, or hypoventilation (respiratory compensation). CO is then consumed toward the formation of the carbonic acid intermediate, thus decreasing pH. Respiratory compensation, though, is incomplete. The decrease in [H+] suppresses the peripheral chemoreceptors, which are sensitive to pH. But, because respiration slows, there's an increase in pCO which would cause an offset of the depression because of the action of the central chemoreceptors which are sensitive to the partial pressure of CO in the cerebral spinal fluid. So, because of the central chemoreceptors, respiration rate would be increased.
Renal compensation for metabolic alkalosis, less effective than respiratory compensation, consists of increased excretion of HCO (bicarbonate), as the filtered load of HCO exceeds the ability of the renal tubule to reabsorb it.
To calculate the expected pCO2 in the setting of metabolic alkalosis, the following equations are used:
- pCO2 = 0.7 [HCO3] + 20 mmHg +/- 5
- pCO2 = 0.7 [HCO3] + 21 mmHg
Respiratory alkalosis may be produced as a result of the following causes:
The causes of metabolic alkalosis can be divided into two categories, depending upon urine chloride levels.
In the United States, hyperkalemia is induced by lethal injection in capital punishment cases. Potassium chloride is the last of the three drugs administered and actually causes death. Injecting potassium chloride into the heart muscle disrupts the signal that causes the heart to beat. This same amount of potassium chloride would do no harm if taken orally and not injected directly into the blood.
Decreased kidney function is a major cause of hyperkalemia. This is especially pronounced in acute kidney injury where the glomerular filtration rate and tubular flow are markedly decreased, characterised by reduced urine output. This can be further intensified by active cellular breakdown which causes increase in serum potassium levels. In chronic kidney disease, hyperkalemia occurs as a result of reduced aldosterone responsiveness and reduced sodium and watery deliveries in distal tubules.
Medications that interferes with urinary excretion by inhibiting the renin–angiotensin system is one of the most common causes of hyperkalemia. Examples of medications that can cause hyperkalemia include ACE inhibitors, angiotensin receptor blockers, beta blockers, and calcineurin inhibitor immunosuppressants such as ciclosporin and tacrolimus. For potassium-sparing diuretics, such as amiloride and triamterene; both the drugs block epithelial sodium channels in the collecting tubules, thereby preventing potassium excretion into urine. Spironolactone acts by competitively inhibiting the action of aldosterone. NSAIDs such as ibuprofen, naproxen, or celecoxib inhibit prostaglandin synthesis, leading to reduced production of renin and aldosterone, causing potassium retention. The antibiotic trimethoprim and the antiparasitic medication pentamidine inhibits potassium excretion, which is similar to mechanism of action by amiloride and triamterene.
Mineralocorticoid (aldosterone) deficiency or resistance can also cause hyperkalemia. Primary adrenal insufficiency are: Addison's disease and congenital adrenal hyperplasia (CAH) (including enzyme deficiencies such as 21α hydroxylase, 17α hydroxylase, 11β hydroxylase, or 3β dehydrogenase).
- Type IV renal tubular acidosis (aldosterone resistance of the kidney's tubules)
- Gordon's syndrome (pseudohypoaldosteronism type II) ("familial hypertension with hyperkalemia"), a rare genetic disorder caused by defective modulators of salt transporters, including the thiazide-sensitive Na-Cl cotransporter.
There are two types of respiratory alkalosis: chronic and acute as a result of the 3-5 day delay in kidney compensation of the abnormality.
- "Acute respiratory alkalosis" occurs rapidly, have a high pH because the response of the kidneys is slow.
- "Chronic respiratory alkalosis" is a more long-standing condition, here one finds the kidneys have time to decrease the bicarbonate level.
A more common cause is excessive loss of potassium, often associated with heavy fluid losses that "flush" potassium out of the body. Typically, this is a consequence of diarrhea, excessive perspiration, or losses associated with muscle-crush injury, or surgical procedures. Vomiting can also cause hypokalemia, although not much potassium is lost from the vomitus. Rather, heavy urinary losses of K in the setting of postemetic bicarbonaturia force urinary potassium excretion (see Alkalosis below). Other GI causes include pancreatic fistulae and the presence of adenoma.
Perhaps the most obvious cause is insufficient consumption of potassium (that is, a low-potassium diet) or starvation. However, without excessive potassium loss from the body, this is a rare cause of hypokalemia.
Usually only seen in anorexia nervosa patients and people on a ketogenic diet.
In general, the cause of a hyperchloremic metabolic acidosis is a "loss of base", either a gastrointestinal loss or a renal loss.
- Gastrointestinal loss of bicarbonate ()
- Severe diarrhea (vomiting will tend to cause hypochloraemic alkalosis)
- Pancreatic fistula with loss of bicarbonate rich pancreatic fluid
- Nasojejunal tube losses in the context of small bowel obstruction and loss of alkaline proximal small bowel secretions
- Chronic laxative abuse
- Renal causes
- Proximal renal tubular acidosis with failure of resorption
- Distal renal tubular acidosis with failure of secretion
- Long-term use of a carbonic anhydrase inhibitor such as acetazolamide
- Other causes
- Ingestion of ammonium chloride, hydrochloric acid, or other acidifying salts
- The treatment and recovery phases of diabetic ketoacidosis
- Volume resuscitation with 0.9% normal saline provides a chloride load, so that infusing more than 3-4L can cause acidosis
- Hyperalimentation ("i.e.", total parenteral nutrition)
Familial disorders
- Cystinosis
- Galactosemia
- Glycogen storage disease (type I)
- Hereditary fructose intolerance
- Lowe syndrome
- Tyrosinemia
- Wilson's disease
Acquired disorders
- Amyloidosis
- Multiple myeloma
- Paroxysmal nocturnal hemoglobinuria
- Toxins, such as HAART, ifosfamide, lead, and cadmium
Hyperchloremic acidosis is a form of metabolic acidosis associated with a normal anion gap, a decrease in plasma bicarbonate concentration, and an increase in plasma chloride concentration (see anion gap for a fuller explanation). Although plasma anion gap is normal, this condition is often associated with an "increased" urine anion gap, due to the kidney's inability to secrete ammonia.
Attacks of DKA can be prevented in those known to have diabetes to an extent by adherence to "sick day rules"; these are clear-cut instructions to person on how to treat themselves when unwell. Instructions include advice on how much extra insulin to take when sugar levels appear uncontrolled, an easily digestible diet rich in salt and carbohydrates, means to suppress fever and treat infection, and recommendations when to call for medical help.
People with diabetes can monitor their own ketone levels when unwell and seek help if they are elevated.
In endocrinology, the terms 'primary' and 'secondary' are used to describe the abnormality (e.g., elevated aldosterone) in relation to the defect, "i.e.", the tumor's location. Hyperaldosteronism can also be caused by plant poisoning, where the patient has been exposed to too much licorice. Licorice is a perennial herb that is used in making candies and in cooking other desserts because of its sweet taste. It contains the chemical glycyrrhizin, which has medicinal uses, but at higher levels it can be toxic. It has the potential for causing problems with sodium and potassium in the body. It also interferes with the enzyme in the kidneys that converts cortisol to cortisone.
Treatment consists of oral bicarbonate supplementation. However, this will increase urinary bicarbonate wasting and may well promote a bicarbonate . The amount of bicarbonate given may have to be very large to stay ahead of the urinary losses. Correction with oral bicarbonate may exacerbate urinary potassium losses and precipitate hypokalemia. As with dRTA, reversal of the chronic acidosis should reverse bone demineralization.
Thiazide diuretics can also be used as treatment by making use of contraction alkalosis caused by them.
Among people hospitalized with high blood calcium, milk-alkali syndrome is the third most common cause, after hyperparathyroidism and cancer.
DKA most frequently occurs in those who already have diabetes, but it may also be the first presentation in someone who had not previously been known to be diabetic. There is often a particular underlying problem that has led to the DKA episode; this may be intercurrent illness (pneumonia, influenza, gastroenteritis, a urinary tract infection), pregnancy, inadequate insulin administration (e.g. defective insulin pen device), myocardial infarction (heart attack), stroke or the use of cocaine. Young people with recurrent episodes of DKA may have an underlying eating disorder, or may be using insufficient insulin for fear that it will cause weight gain.
Diabetic ketoacidosis may occur in those previously known to have diabetes mellitus type 2 or in those who on further investigations turn out to have features of type 2 diabetes (e.g. obesity, strong family history); this is more common in African, African-American and Hispanic people. Their condition is then labeled "ketosis-prone type 2 diabetes".
Drugs in the gliflozin class (SGLT2 inhibitors), which are generally used for type 2 diabetes, have been associated with cases of diabetic ketoacidosis where the blood sugars are not significantly elevated ("euglycemic DKA"). This may be because they were being used in people with type 1 diabetes, but in those with type 2 diabetes it may be as a result of an increase in glucagon levels.
When taking a blood test, the aldosterone-to-renin ratio is abnormally increased in primary hyperaldosteronism, and decreased or normal but with high renin in secondary hyperaldosteronism.
Gitelman syndrome is estimated to have a prevalence of 1 in 40,000 people.
Hypophosphatemia is caused by the following three mechanisms:
- Inadequate intake (often unmasked in refeeding after long-term low phosphate intake)
- Increased excretion (e.g. in hyperparathyroidism, hypophosphatemic rickets)
- Shift from extracellular to intracellular space. This can be seen in treatment of diabetic ketoacidosis, refeeding, short-term increases in cellular demand (e.g. hungry bone syndrome) and acute respiratory alkalosis.