SERUM MAGNESIUM

Elevated
• Renal insufficiency.

Decreased
• Acute fluid loss from GI tract
• Chronic alcoholism
• Chronic hepatitis
• Chronic renal loss
• Hypervitaminosis D.

SERUM PHOSPHORUS: INORGANIC
Normal
Children – 4 to 7 mg/100 ml
Adults – 3 to 4 mg/100 ml.
Elevated
• Renal insufficiency
• Hypoparathyroidism
• Hypervitaminosis D

Decreased
• Hyperparathyroidism
• Rickets and osteomalacia
• Steatorrhoea
• Antacid ingestion.

SERUM CALCIUM
Normal 9.6 to 10.9 mg/100 ml.
Raised
• Hyperparathyroidism (20 mg%)
• Hypervitaminosis D (17 mg%)
• Multiple myeloma
• Cushing’s syndrome.

Decreased
• Hypoparathyroidism
• Osteomalacia, rickets
• Malabsorption syndrome
• Acute pancreatitis.

1. Fluid OverLoad;

IV fluid administration in excess of the child’s needs
Nephrotic syndrome
Cirrhosis
Heart Failure
Acute/ Chronic Renal Failure
Obstructive uropathy

2.Euvolaemic

Administration of enteral hypotonic fluids (including dilute formula, Oral Rehydration Solutions, excessive water intake)
Psychogenic Polydipsia
Increased ADH secretion
- Pulmonary: pneumonia, bronchiolitis, mechanical ventilation
- CNS: infections, injury, tumour
- Post-operative, trauma, pain
- Endocrine: Hypothyroid, low cortisol
Medications
- Chemotherapy (cyclophosphamide, vincristine, platinum based agents)
- Antiepileptics (valproate, carbamazepine, oxcarbazepine)
- Vasopressin

3. Dehydrated

GI losses and rehydration with free water
- Gastroenteritis
- Secretory/osmotic diarrhoeas
- Ostomies
Skin losses (CF / burns)
Abdominal 3rd spacing
High rate fluid consumption post exercise
Hyperglycaemia
Renal Losses
- Thiazide Diuretic
- Cerebral salt wasting
Primary renal Tubular Disorders
Hypoaldosteronism
Metabolic alkalosis

1.Water deficit

Common:

Gastrointestinal loss eg diarrhoea, stomal losses
Skin loss (excess sweating/burns)
Renal losses eg osmotic diuretics, diabetes mellitus, polyuria of acute tubular necrosis
Inability to obtain water, including breastfed babies due to inadequate milk supply

Less Common:

Diabetes insipidus (central, nephrogenic, systemic disease, drugs)
Increased insensible losses
Impaired thirst mechanism secondary to underlying neurological abnormalities or hypothalamic dysfunction

2.Sodium Excess

Ingestion of high sodium (inappropriate formula concentration, high osmolality rehydration solutions, salt poisoning)
Iatrogenic (hypertonic saline, sodium bicarbonate)
Hyperaldosteronism
- Primary (Conn’s)
- Secondary (CCF, nephrotic syndrome, steroids)

1.Decreased intake

Illness

Fasting

Prolonged IV fluids not containing potassium

Eating disorder

2.Increased losses

Gastrointestinal

Vomiting
Diarrhoea
Fistula

Renal

Diuretics
Osmotic diuresis
Aldosterone excess
Mineralocorticoid excess
Congenital disorders
Renal artery stenosis

3.Transcellular shifts

Alkalosis

Hypomagnesaemia

Hypernatraemia

Glucose/insulin infusion

Diabetic ketoacidosis

Refeeding syndrome

4.Medicines

Loop diuretics (eg frusemide)

Thiazide diuretics

Amphotericin

Cisplatin

Insulin

Salbutamol

Adrenaline

1.Increased potassium intake

High potassium load from intravenous fluids or total parenteral nutrition (TPN).
Blood transfusion.
Drugs containing a large amount of potassium.
In children with normal renal function and hormonal mechanisms dietary intake should not cause significant hyperkalaemia.

2.Movement of potassium from intracellular to extracellular space

Cellular injury - eg, rhabdomyolysis, trauma, burns, severe haemolysis, tumour lysis syndrome.
Metabolic or respiratory acidosis.
Hyperkalaemic periodic paralysis.
Insulin deficiency.
Drugs - eg, beta-blockers.

3.Impaired renal excretion of potassium

Chronic kidney disease (CKD) or acute kidney injury (AKI).
Dehydration, hypovolaemia.
Aldosterone deficiency: primary adrenal insufficiency, congenital adrenal hyperplasia, aldosterone synthase deficiency.
Aldosterone resistance: pseudohypoaldosteronism, renal tubular acidosis.

4.Pseudohyperkalaemia

Prolonged tourniquet time; difficulty collecting the sample.
Haemolysed blood sample.
Hereditary spherocytosis and familial pseudohyperkalaemia (potassium leaks from cells as a result of cooling).
Use of the wrong anticoagulant, especially EDTA contamination of the blood sample.
Excessive cooling of a specimen.
Length of storage of the specimen.
Marked leukocytosis and thrombocytosis.
Hyperventilation - eg, due to crying. Acute respiratory alkalosis may cause potassium to shift out of cells.
Sample from arm receiving intravenous fluids containing potassium.

Electrolytes imbalance

Protocols

SERUM MAGNESIUM

Elevated
• Renal insufficiency.

Decreased
• Acute fluid loss from GI tract
• Chronic alcoholism
• Chronic hepatitis
• Chronic renal loss
• Hypervitaminosis D.

1.Increased potassium intake

High potassium load from intravenous fluids or total parenteral nutrition (TPN).
Blood transfusion.
Drugs containing a large amount of potassium.
In children with normal renal function and hormonal mechanisms dietary intake should not cause significant hyperkalaemia.

2.Movement of potassium from intracellular to extracellular space

Cellular injury - eg, rhabdomyolysis, trauma, burns, severe haemolysis, tumour lysis syndrome.
Metabolic or respiratory acidosis.
Hyperkalaemic periodic paralysis.
Insulin deficiency.
Drugs - eg, beta-blockers.

3.Impaired renal excretion of potassium

Chronic kidney disease (CKD) or acute kidney injury (AKI).
Dehydration, hypovolaemia.
Aldosterone deficiency: primary adrenal insufficiency, congenital adrenal hyperplasia, aldosterone synthase deficiency.
Aldosterone resistance: pseudohypoaldosteronism, renal tubular acidosis.

4.Pseudohyperkalaemia

Electrolytes imbalance

Protocols

SERUM MAGNESIUM

Elevated• Renal insufficiency.

Decreased• Acute fluid loss from GI tract• Chronic alcoholism• Chronic hepatitis• Chronic renal loss• Hypervitaminosis D.

1.Increased potassium intake

High potassium load from intravenous fluids or total parenteral nutrition (TPN).Blood transfusion.Drugs containing a large amount of potassium.In children with normal renal function and hormonal mechanisms dietary intake should not cause significant hyperkalaemia.

2.Movement of potassium from intracellular to extracellular space

Cellular injury - eg, rhabdomyolysis, trauma, burns, severe haemolysis, tumour lysis syndrome.Metabolic or respiratory acidosis.Hyperkalaemic periodic paralysis.Insulin deficiency.Drugs - eg, beta-blockers.

3.Impaired renal excretion of potassium

Chronic kidney disease (CKD) or acute kidney injury (AKI).Dehydration, hypovolaemia.Aldosterone deficiency: primary adrenal insufficiency, congenital adrenal hyperplasia, aldosterone synthase deficiency.Aldosterone resistance: pseudohypoaldosteronism, renal tubular acidosis.

4.Pseudohyperkalaemia

Elevated
• Renal insufficiency.

Decreased
• Acute fluid loss from GI tract
• Chronic alcoholism
• Chronic hepatitis
• Chronic renal loss
• Hypervitaminosis D.

High potassium load from intravenous fluids or total parenteral nutrition (TPN).
Blood transfusion.
Drugs containing a large amount of potassium.
In children with normal renal function and hormonal mechanisms dietary intake should not cause significant hyperkalaemia.

Cellular injury - eg, rhabdomyolysis, trauma, burns, severe haemolysis, tumour lysis syndrome.
Metabolic or respiratory acidosis.
Hyperkalaemic periodic paralysis.
Insulin deficiency.
Drugs - eg, beta-blockers.

Chronic kidney disease (CKD) or acute kidney injury (AKI).
Dehydration, hypovolaemia.
Aldosterone deficiency: primary adrenal insufficiency, congenital adrenal hyperplasia, aldosterone synthase deficiency.
Aldosterone resistance: pseudohypoaldosteronism, renal tubular acidosis.