Hypocalcemia

Last updated: July 21, 2023

Summary

Hypocalcemia is a state of low serum calcium levels (total Ca²⁺ < 8.5 mg/dL or ionized Ca²⁺ < 4.65 mg/dL). Total calcium comprises physiologically-active ionized calcium as well as anion-bound and protein-bound, physiologically-inactive calcium. Calcium plays an important role in various cellular processes in the body, such as stabilizing the resting membrane potential of cells, cell signaling, coagulation, and hormone release. In addition to hormonal control by parathyroid hormone (PTH) and calcitriol, calcium homeostasis is also influenced by serum protein levels and acid-base status, both of which impact the ratio of protein-bound Ca²⁺ to ionized Ca²⁺ in the serum. Severity and chronicity of calcium deficiency in addition to the patient's age and comorbidities contribute to the overall clinical presentation of hypocalcemia. Symptoms are variable; the most characteristic features include prolongation of the QT interval and signs of neuromuscular excitation (e.g., tetany, carpopedal spasm, paresthesias). Management consists of calcium supplementation and identifying and treating the underlying cause.

Definition

Hypocalcemia: total serum calcium concentration < 8.5 mg/dL (< 2.12 mmol/L), or ionized (free) calcium concentration < 4.65 mg/dL (< 1.16 mmol/L) ^[1]
Severe hypocalcemia: total serum calcium concentration ≤ 7.5 mg/dL (< 1.9 mmol/L), or ionized (free) calcium concentration < 3.6 mg/dL (< 0.9 mmol/L) ^[2]
Factitious hypocalcemia: an asymptomatic decrease in total calcium with a normal ionized Ca²⁺ level (typically occurs due to low serum protein levels)

Calcium homeostasis and calcium physiology

Total and ionized calcium concentrations

Total calcium: the total amount of calcium circulating in the serum, comprising protein-bound, anion-bound, and ionized calcium
- Approx. 40% of the total serum calcium is bound to proteins (mostly albumin) and is physiologically inactive. ^[3]
- Hypoproteinemia (due to, e.g., nephrotic syndrome, liver cirrhosis, severe malnutrition, malabsorption) → ↓ total Ca²⁺ level but ionized Ca²⁺ level is unaffected; → factitious hypocalcemia
- pH influences the binding of calcium to serum proteins.
  - ↑ pH → ↓ H⁺ in serum binding to proteins → ↑ Ca²⁺ binding to proteins → ↓ ionized Ca²⁺ concentration compensatory ↑ PTH
  - ↓ pH → ↑ H⁺ in serum binding to proteins → ↓ Ca²⁺ binding to proteins → ↑ ionized Ca²⁺ concentration compensatory ↓ PTH
Ionized calcium: the calcium fraction that is not bound to any proteins but is physiologically active
- ∼ 45% of the total serum calcium ^[3]
- Functions as the main regulator of PTH secretion
- PTH secretion is influenced by pH variations but not by changes in albumin levels.
- An excess causes true hypercalcemia whereas a deficiency causes true hypocalcemia.

To remember the effect pH has on PTH, think: ↑ pH = ↑ PTH and ↓ pH = ↓ PTH.

The physiological role of calcium ^[4]

Ionized Ca²⁺ is responsible for stabilizing the resting membrane potential of cells.
- ↓ Serum Ca²⁺ → ↑ membrane excitability
- ↑ Serum Ca²⁺ → ↓ membrane excitability
Acts as a second messenger in signaling pathways
Cofactor for several enzymes (e.g., phospholipase A, gamma-glutamyltransferase)
Required for the promotion of coagulation pathways

Calcium homeostasis

Calcium homeostasis is a complex process, involving many organs (kidneys, gastrointestinal tract, bones, liver, and skin) and hormones (PTH, calcitonin, vitamin D).

Hormone
Hormone	Effect on serum [calcium]	Effect on serum [phosphate]	Mechanism of action	Regulation
Parathyroid hormone	↑	↓	Kidneys Increases Ca²⁺ reabsorption in the distal tubule Decreases phosphate reabsorption in the proximal convoluted tubules Increases active vitamin D (calcitriol) production via stimulation of 1-alpha-hydroxylase synthesis in the kidneys Gastrointestinal tract: indirectly increases Ca²⁺ absorption via increased 1,25-dihydroxyvitamin D (calcitriol) synthesis in the kidneys Bone: releases Ca²⁺ and phosphate from the bones PTH increases the expression of RANKL on osteoblasts. RANKL binds the osteoclastic RANK receptor, which increases osteoclast activity, and results in increased bone resorption and calcium release.	PTH secretion is stimulated by: Decrease in serum Ca²⁺ Hyperphosphatemia Mild hypomagnesemia (e.g., due to chronic diarrhea, IBD, loop diuretics, alcohol) Low calcitriol levels PTH secretion is inhibited by: Increase in serum Ca²⁺ Marked hypomagnesemia
Calcitriol (vitamin D₃)	↑	↑	Gastrointestinal tract: increases Сa²⁺ and phosphate absorption Kidneys: increases phosphate and Сa²⁺ reabsorption Bone: enhances bone mineralization For more information, see vitamin D synthesis and vitamin D deficiency.	A decrease in serum Ca²⁺ indirectly ↑ calcitriol via ↑ PTH.
Calcitonin	↓	↓	Opposes the effects of PTH Inhibits bone resorption, decreasing serum Ca²⁺	An increase in serum Ca²⁺ results in ↑ calcitonin secretion.

The acronym “PTH” describes the action of parathyroid hormone: P = Phosphate T = Trashing H = Hormone.

To remember that calcitonin keeps the calcium in the bones, think: Calci-bone-in! Regulation of calcium and phosphate metabolism

References:^[5]^[6]^[7]^[8]^[9]^[10]

Etiology

Types of hypocalcemia	Etiology	Pathophysiology
Low PTH	Hypoparathyroidism	Surgical removal of the parathyroid glands (thyroidectomy, parathyroidectomy) Autoimmune destruction of the parathyroid glands (e.g., in autoimmune polyglandular syndrome) Congenital disorders of the parathyroid gland (e.g., DiGeorge syndrome)
High PTH (secondary hyperparathyroidism)	Vitamin D deficiency	Malnutrition and malabsorption (e.g., alcoholism, chronic IBD, cystic fibrosis, gastric-bypass) Lack of sunlight exposure Decreased enzymatic hydroxylation to active form (e.g., cirrhosis/liver disease, chronic kidney disease) Vitamin D-dependent rickets (type 1 and type 2)
	Chronic kidney disease	↓ Renal excretion of phosphate → hyperphosphatemia → calcium-phosphate precipitation in tissues → ↓ Ca²⁺ ↓ Renal hydroxylation of vitamin D → ↓ 1,25-(OH)₂ vitamin D₃ → ↓ intestinal Ca²⁺ absorption → ↓ Ca²⁺
	Pseudohypoparathyroidism	PTH resistance
	Hyperphosphatemia	↓ Renal excretion of phosphate (e.g., impaired renal function) Increased phosphate intake (e.g., oral supplements, enemas) Increased tissue breakdown (e.g., tumor lysis syndrome, rhabdomyolysis, crush injury)
	Acute necrotizing pancreatitis (see acute pancreatitis)	Calcium soap precipitation in the abdomen
Other	Medications	Loop diuretics increase renal calcium excretion. Calcitonin Bisphosphonates Glucocorticoids Denosumab Foscarnet Phosphate L-asparaginase Doxorubicin Cisplatin Ketoconazole Pentamidine Cytosine arabinoside Gallium nitrate Plicamycin
	Multiple blood transfusions and hemolysis	Citrate in blood products chelates serum calcium.
	Hypomagnesemia (see magnesium)	Hypomagnesemia → ↓ PTH secretion or induces PTH resistance → hypocalcemia
	Hyperventilation	Redistribution of calcium
	Osteoblastic metastases	Metastases of primary malignancies (e.g., prostate cancer, small cell lung cancer) in the bone with rapid new bone formation
	Renal tubular disorders	See RTA type 1.
	Pseudohypocalcemia	Due to gadolinium contrast agent or hypoalbuminemia
	Neonatal hypocalcemia	Due to cessation of placental Ca²⁺ transfer at birth
	Hungry bone syndrome	Hypocalcemia following parathyroidectomy or thyroidectomy despite normal or increased PTH

Hypocalcemia is most often due to hypoparathyroidism or vitamin D deficiency (e.g., malabsorption, chronic kidney disease).

Suspect hypocalcemia in the postoperative thyroidectomy patient with new-onset paresthesias and muscle spasms or cramping.

References:^[6]^[8]^[11]^[12]

Clinical features

Manifestations of hypocalcemia are influenced by the severity and chronicity of the hypocalcemia as well as by the patient's age and comorbidities.

Neurological manifestations ^[1]^[13]^[14]^[15]

Tetany: increased neuromuscular excitability (when caused by respiratory alkalosis = hyperventilation-induced tetany)
- Paresthesias: typically tingling or pins-and-needles sensation in extremities and/or in the perioral area
- Spasms (e.g., carpopedal spasm , bronchospasm or laryngospasm ), and cramps (possible in any muscle)
- Stiffness, myalgia
- Maneuvers to elicit latent tetany on physical exam
  - Chvostek sign: short contractions (twitching) of the facial muscles elicited by tapping the facial nerve below and in front of the ear (∼ 2 cm ventral to the ear lobe) ^[1]
  - Trousseau sign: ipsilateral carpopedal spasm occurring several minutes after inflation of a blood pressure cuff to pressures above the systolic blood pressure ^[1]
Seizure: may be the initial or only symptom ^[14]

Signs of neuromuscular irritability (e.g., paresthesias, spasms and cramps) are the most characteristic features of hypocalcemia.

Chvostek's Sign and Trousseau's Sign due to hypocalcemia | External video

Cardiovascular manifestations ^[1]^[13]^[14]^[15]

Congestive heart failure
Hypotension
Cardiac arrhythmias (symptoms may include palpitations, irregular pulse, syncope)

Manifestations of chronic hypocalcemia ^[1]^[13]^[14]^[15]

Psychiatric manifestations (variable and usually mild; may be reversible), such as emotional instability, anxiety, depression, confusion/delirium, hallucinosis, or psychosis
Ophthalmologic manifestations: papilledema (in severe cases), cataracts, calcifications of the cornea
Neurological manifestations: pseudotumor cerebri, paradoxical CNS calcifications
Dental changes: altered morphology, dental enamel hypoplasia
Growth plate abnormalities and osteomalacia

Hypocalcemia fact sheet

Diagnostics

Approach

Confirm hypocalcemia: Order total and ionized calcium or correct serum calcium for albumin level
Determine etiology: Obtain serum intact PTH level.
- Elevated PTH levels: Consider and investigate other causes (e.g., renal failure, vitamin D deficiency, medication side effects, familial or genetic disorders).
- Normal or low PTH levels: hypoparathyroidism is the likely cause.

Diagnosis of hypocalcemia

Acute symptomatic hypocalcemia is a medical emergency that is potentially fatal, diagnostics should not delay treatment.

Laboratory studies ^[2]^[13]

Routine studies

Confirm true hypocalcemia
- Measure total and ionized calcium
- AND/OR check serum albumin and calculate corrected calcium
Evaluate for other electrolyte abnormalities
- BMP
- Serum phosphate and magnesium
ABG/VBG

Calcium correction for hypoalbuminemia

Additional studies

Serum intact PTH:
- Indication: best initial study for confirmed hypocalcemia with no clear etiology
- Interpretation
  - Low (or normal) PTH suggests hypoparathyroidism
  - High PTH suggests parathyroid gland function is preserved
Further serum studies: conducted based on clinical suspicion
Urine studies: 24-hour urinary excretion of calcium and magnesium

Interpretation of laboratory findings in hypocalcemia ^[1]
PTH level	Additional findings	Conditions
Low PTH	↑ Phosphate	Hypoparathyroidism (e.g., postsurgical)
High PTH	Low or normal phosphate ↓ 25-hydroxyvitamin D (calcidiol) ^[16]	Vitamin D deficiency
	↑ Phosphate	Hyperphosphatemia Pseudohypoparathyroidism
	↑ Phosphate ↑ Creatinine	Chronic kidney disease
	↓ Magnesium	Malabsorption or alcoholism

The typical laboratory findings of vitamin D deficiency are ↓ calcium, ↓ (or normal) phosphate, and ↑ PTH.

ECG

Indication: acute, severe, and/or symptomatic hypocalcemia
ECG findings of hypocalcemia include: ^[14]
- Prolonged QT interval
- Ventricular arrhythmias: torsades de pointes, ventricular tachycardia, ventricular fibrillation
- QRS complex and ST-segment changes (may mimic myocardial infarction)
- AV block

ECG in hypocalcemia

Fundoscopy

Recommended in severe/symptomatic cases
Possible findings: papilledema ^[15]

Treatment

The mainstay of therapy of hypocalcemia consists of calcium supplementation and the treatment of the underlying cause.

Calcium supplementation ^[2]

Calcium supplementation should be provided based on severity. See “Repletion regimens for hypocalcemia” for more details on calcium supplementation with specific dosages.

Severe and/or symptomatic hypocalcemia: e.g., tetany, seizures, prolonged QT interval, serum calcium ≤ 7.5 mg/dL (< 1.9 mmol/L)
- IV calcium supplementation: calcium gluconate or calcium chloride
- Continuous telemetry ^[2]
- Consider transfer to critical care unit
Mild and/or chronic hypocalcemia: no symptoms or only mild neuromuscular irritability (e.g., paresthesias), serum calcium 7.6–8.4 mg/dL (1.9–2.12 mmol/L)
- Oral calcium supplementation: calcium citrate, calcium carbonate

IV calcium can trigger life threatening arrhythmias in patients simultaneously receiving cardiac glycosides (digoxin or digitoxin). ^[1]

Treatment of the underlying condition

Hypoparathyroidism
- Calcium supplementation (See “Repletion regimens for hypocalcemia” and “Treatment” in “Hypoparathyroidism”)
- PLUS vitamin D supplementation
Secondary to loop diuretics: consider discontinue loop diuretic and change medication to thiazides
Vitamin D deficiency: vitamin D supplementation
Hypomagnesemia-induced hypocalcemia: magnesium supplementation (See “Repletion regimens for hypomagnesemia”)
Hyperphosphatemia in chronic kidney disease: calcium supplementation

Loop diuretics Lose calcium. Discontinue them in hypocalcemia.

Special patient groups

Neonatal hypocalcemia

Overview of neonatal hypocalcemia ^[17]^[18]^[19]
Types		Early hypocalcemia	Late hypocalcemia
Onset		< 2–3 days after birth	> 2–3 days after birth Most commonly at the beginning of the second week ^[20]
Etiology	Maternal	Diabetes Hyperparathyroidism	Vitamin D deficiency (rare)
	Fetal	Prematurity Birth asphyxia Fetal growth restriction Hypomagnesemia	Increased phosphate intake Acute renal failure
	Fetal	DiGeorge syndrome
Clinical features		Usually asymptomatic	Usually symptomatic
Clinical features		Neuromuscular excitability (e.g., muscle spasms) Seizures See “Clinical features of hypocalcemia” for details.
Diagnosis ^[21]	Preterm infants < 1500 g	Total serum calcium < 1.75 mmol/L/< 7 mg/dL OR Ionized fraction < 1 mmol/L/< 4 mg/dL
Diagnosis ^[21]	Preterm infants ≥ 1500 g and term infants	Total serum calcium < 2 mmol/L/< 8 mg/dL OR Ionized fraction < 1.1 mmol/L/< 4.4 mg/dL
Management		Calcium substitution Treatment of the underlying condition

References

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