001024

Phosphorus Serum (Patient should be fasting)



Product Description

Patient Preparation:

Patient should be fasting.

Synonyms:

  • Inorganic Phosphate, Blood
  • P
  • Phos
  • PO4

Use:

Causes of high phosphorus: Youth; exercise; dehydration and hypovolemia; high phosphorus content enema; acromegaly; hypoparathyroidism; pseudohypoparathyroidism; bone metastases; hypervitaminosis D; sarcoidosis; milk-alkali syndrome; liver disease, such as portal cirrhosis; catastrophic events such as cardiac resuscitation, pulmonary embolism, renal failure; diabetes mellitus with ketosis; serum artifact − sample not refrigerated; overheated, hemolyzed sample, or serum allowed to remain too long on the clot.

Although phosphate accumulation occurs as renal disease progresses, hyperphosphatemia is not a feature of early renal failure;1 it does not usually develop before renal function has diminished to about 25% of normal.2 Osteitis fibrosa in uremic subjects, from excessive bone turnover, relates to hyperphosphatasia. The role of hyperphosphatemia in promotion of such secondary hyperparathyroidism is well established.3 A relationship to osteomalacia in hemodialysis patients exists.3

Causes of low phosphorus: (Hypophosphatemia may occur with or without phosphate depletion. Serum levels vary as much as 2.0 mg/dL during the day.)

Very severely malnourished subjects may have low phosphate levels, but even in starvation, phosphorus levels usually are normal. Antacids, diuretics, and long term steroids are among the common agents bearing a relationship to severe hypophosphatemia.4 Recent carbohydrate ingestion decreases phosphorus, as does intravenous glucose administration; cases of hypophosphatemia relate to I.V. carbohydrate,4 dialysis, hyperalimentation, prolonged intravenous administration of phosphate-free fluids, metabolic states involving glucose, potassium, and pH. Depletion of phosphate occurs in diabetic ketoacidosis. Like potassium, phosphorus returns to the cell with therapy of diabetic ketoacidosis and serum levels may diminish significantly during treatment. Osmotic diuresis induced by glycosuria in poorly controlled diabetes may lead to urinary phosphate losses with negative phosphorus balance. PO4 levels may prove useful in initiation of insulin therapy, in diabetic ketoacidosis and other situations of insulin lack; with hyperglucagonemia, corticosteroid and epinephrine use, and in respiratory alkalosis. Association of hypophosphatemia with impaired glucose metabolism is thought to reflect decreased tissue sensitivity to insulin.5 Alcoholism and other hepatic disorders are found very frequently among patients with low PO4. Alcoholic ketosis and alcohol withdrawal are among causes of hypophosphatemia. There is a slight decrease in serum phosphorus in the last trimester of pregnancy.

Primary hyperparathyroidism and other causes of calcium elevation, including ectopic hyperparathyroidism (pseudohyperparathyroidism).

Patients with sepsis, including Legionnaires’ disease and other respiratory infections. Twenty-two percent of instances of respiratory infections had serum phosphorous ≤2.4.6 Halevy and Bulvik report gram-negative septicemia as a common cause of severe hypophosphatemia among 55,000 chemistry profiles of hospitalized patients they studied.4 (Hypophosphatemia impairs bactericidal activity).

Vitamin D deficiency; osteomalacia, inherited and sporadic forms of hypophosphatemic rickets. In work-up for osteomalacia, look for decreased calcium and phosphorus and increased alkaline phosphatase. Biopsy, however, can be abnormal even when these biochemical parameters are within normal limits.

Renal tubular disorders (Fanconi syndrome, renal tubular acidosis); use of antacids that bind phosphorus (look for hypercalciuria, low urinary phosphorus, high alkaline phosphatase);7 dialysis, vomiting; saline or lactate I.V.; steatorrhea, malabsorption, severe diarrhea, nasogastric suction; hypokalemia; negative nitrogen balance; decreased dietary PO4 intake; recovery from severe burn injury; salicylate poisoning; acute gout; tumor-related: described as including hemangiopericytomas (uncommon pathologic entities) and neurofibromatosis; transfusion of blood; arteriography.

The signs and symptoms of phosphate depletion may include neuromuscular, neuropsychiatric, gastrointestinal, skeletal, and cardiopulmonary systems. Manifestations usually are accompanied by serum levels <1.0 mg/dL.

Severe hypophosphatemia is most common in elderly patients and is often found in postoperative subjects.4

Complications of hypophosphatemia: Effect on RBC 2,3-diphosphoglycerate and oxygen dissociation.8 Depression of myocardial function (contractibility), decreased cardiac output; respiratory failure and respiratory muscle weakness; increased incidence of sepsis, impairment of bactericidal activities.9 CNS consequences: polyradiculopathy, paresthesias, tremor, ataxia, weakness, slurred speech, stupor, coma, seizure; joint stiffness; myopathy; renal stones, hypercalciuria secondary to renal phosphate leak; insulin resistance, glucose intolerance. Rhabdomyolysis may complicate marked hypophosphatemia. A mortality rate of 20% is described in patients whose phosphorus concentration was 1.1-1.5 mg/dL.4

Footnotes:

1. Hakim RM, Lazarus JM, “Biochemical Parameters in Chronic Renal Failure,” Am J Kidney Dis, 1988, 11(3):238-47. PubMed 3125741

2. Coburn JW, Salusky IB, “Control of Serum Phosphorus in Uremia,” N Engl J Med, 1989, 320(17):1140-2 (editorial). PubMed 2710175

3. Delmez JA, Fallon MD, Harter HR, et al, “Does Strict Phosphorus Control Precipitate Renal Osteomalacia?” J Clin Endocrinol Metab, 1986, 62(4):747-52 (review). PubMed 3949954

4. Halevy J, Bulvik S, “Severe Hypophosphatemia in Hospitalized Patients,” Arch Intern Med, 1988, 148(1):153-5. PubMed 3122679