Phosphorus

Phosphorus in the form of inorganic or organic phosphate is a major component of all tissues and is essential for many vital functions. It is a major constituent of the skeleton, cell membranes and nucleic acids. Cellular metabolic pathways including glycolysis and oxidative phosphorylation require phosphate. Phosphate in the form of 2,3 diphosphogycerate regulates dissociation of oxygen from hemoglobin. Protein phosphorylation is an important control mechanism for the action of many enzymes. Many physiologic functions such as muscle contractility, neurologic function, and electrolyte transport require phosphate in the form of ATP. Phosphate is also a constituent of NADP, cyclic AMP, and guanine nucleotides. Intracellular phosphate is important in the regulation of the intermediary metabolism of protein, fats, and carbohydrates as well as glucose transport and cell growth.  

Approximately 85% of total body phosphate is located in bone, 10% in skeletal muscle, and less than 1% in extracellular fluid. Most dietary phosphate comes from dairy products and meat. The average Western diet provides 20 mg of phosphorus per kg of body weight. Dietary intake greatly exceeds the normal daily requirement. Nonabsorbed dietary phosphorus is excreted in feces. The duodenum and jejunum are the major sites of phosphate absorption. Intestinal absorption is mediated by an active sodium dependent cotransporter and paracellular sodium independent transport. Absorbed phosphorus enters the extracellular fluid and moves in and out of skeletal bone under the influence of parathyroid hormone.

The kidneys maintain phosphate balance. Phosphorus is freely filtered at the glomerulus and reabsorbed mainly in the proximal tubule by sodium-phosphate cotransporters. Only 10 to 20% of phosphorus is excreted in urine. Phosphorus reabsorption is mediated by parathyroid hormone, FGF23, and dietary phosphorus intake. Decreased plasma phosphate concentration promotes the the synthesis of sodium-phosphorus cotransporters, resulting in increased proximal reabsorption and an increase in plasma phosphorus concentration. Conversely, both parathyroid hormone and FGF23 are phosphaturic and decrease the number of phosphorus transporters, which in turn leads to increased phosphorus excretion and a decrease in plasma phosphorus concentration.

In healthy individuals, plasma phosphate concentration displays a marked diurnal variation, being lowest in the morning and highest during the night. The intra-individual variation of plasma phosphate is 15%. If fasting samples are drawn at the same time of the day, intraindividual variation decreases to 7%. Phosphate levels are lower immediately after a meal because of insulin release. Phosphate levels are higher in summer and lower in winter due to changes in vitamin D levels. Plasma phosphate levels are high at birth and remain higher in children than adults. Levels are lower in elderly men. Prolonged bed rest causes a significant rise in phosphate concentration, that gradually decreases following mobilization. Plasma phosphate levels do not change significantly during pregnancy but tend to be higher in lactating women. Serum phosphate levels may be higher in patients with thrombocytosis due to release of intracellular phosphate from platelets during specimen clotting.

Mild hypophosphatemia (<2.5 mg/dL) is present in about 3% of general hospital admissions but is much more common in patients who are acutely ill, malnourished, or in ketoacidosis. Symptomatic hypophosphatemia is usually observed when plasma phosphate levels fall below 1.0 mg/dL for several days. Severe hypophosphatemia can cause muscle weakness, bone pain, tremors, seizures, cardiomyopathy, respiratory insufficiency, hypercalcuria, and decreased platelet and granulocyte function.

Hyperventilation and respiratory alkalosis are the major causes of hypophosphatemia in patients with pain, anxiety, sepsis, alcoholism, severe liver disease, salicylate toxicity, head injury, heat stroke, and mechanical ventilation. Respiratory alkalosis causes increased intracellular pH, which stimulates phosphofructokinase activity resulting in increased glycolysis and incorporation of phosphate into organic intermediates. As a consequence, phosphate shifts into cells. Infusion of 5% dextrose can cause a significant decrease in plasma phosphate, due to increased insulin secretion and uptake of phosphate into cells. Life threatening hypophosphatemia may occur in malnourished patients who are rapidly administered carbohydrates. Diabetic ketoacidosis causes reduced phosphate intake because of anorexia and vomiting and increased phosphate excretion due to osmotic diuresis. Primary hyperparathyroidism can cause hypophosphatemia secondary to increased urinary excretion of phosphate. Vitamin D deficiency causes hypocalcemia, secondary hyperparathyroidism, increased urinary phosphate excretion and decreased intestinal phosphate absorption. Hepatic insufficiency contributes to hypophosphatemia by decreased 25-hydroxylation of vitamin D, leading to reduced synthesis of 1,25 dihyroxy vitamin D3 Chronic diarrhea and steatorrhea may reduce intestinal phosphate absorption. Antacids such as aluminum hydroxide bind phosphate in the gut and prevent phosphate absorption. Other drugs such as sucralfate contain aluminum hydroxide and have a similar effect.

The incidence of mild hyperphosphatemia in a general hospital population is about 1.5%. Acute hyperphosphatemia can lead to hypocalcemia, tetany, and hypotension. A rise in the plasma calcium x phosphate product above 70 results in soft tissue calcium deposition. Renal failure accounts for more than 90% of hyperphosphatemia cases. Plasma phosphate levels begin to rise when the GFR falls below 25 to 40 mL/min/1.73 m2.

Metabolic acidosis causes hyperphosphatemia by promoting a shift of phosphate out of cells and into the extracellular fluid. Tissue hypoxia increases plasma phosphate concentration due to accelerated ATP breakdown. Rhabdomyolysis, tumor lysis syndrome, and hemolysis produce severe hyperphosphatemia because of the massive release of intracellular phosphate. Hypoparathyroidism, acromegaly, and thyrotoxicosis cause hyperphosphatemia by reducing urinary phosphate excretion. Oral or parenteral phosphate administration can cause hyperphosphatemia, especially if renal function is compromised. Enemas with a high phosphate content can cause hyperphosphatemia, hypocalcemia, and tetany.

High doses of liposomal drug formulations may cause falsely elevated results for plasma phosphorus. Some of the most commonly used liposomal formulations are;

Amphotericin B AmBisome
Cytarabine DepoCyt
Doxorubicin Doxil

 

The interference has been attributed to the phospholipid bilayer in the liposomal envelope that is used to facilitate drug delivery.

Prolonged blood sample storage and in vitro hemolysis can cause artifactual hyperphosphatemia. Some patients with multiple myeloma have a spuriously high plasma phosphate concentration due to interference with the test method.

Reference range is age dependent: 2.5 - 5.8 mg/dL for 0 to 18 years and 2.5 - 4.5 for adults >18 years. Levels below 1.0 mg/dL are considered critical values.