The ED management of hypernatremia revolves around 2 tasks: restoration of normal serum tonicity, and diagnosis and treatment of the underlying etiology. When possible, providing free water to a patient orally is preferred.
Hypernatremia should not be corrected at a rate greater than 1 mEq/L per hour.
Carefully monitor all patients' inputs and outputs during treatment.
Consider CNS imaging to exclude a central cause or to identify CNS bleeding from stretching of veins.
Using isotonic sodium chloride solution, stabilize hypovolemic patients who have unstable vital signs before correcting free water deficits because hypotonic fluids quickly leave the intravascular space and do not help to correct hemodynamics. Once stabilization has occurred, free water deficits can be replaced either orally or intravenously.
Euvolemic patients can be treated with hypotonic fluids, either orally or intravenously (ie, dextrose 5% in water solution [D5W], quarter or half isotonic sodium chloride solution), to correct free fluid deficits.
Hypervolemic patients require removal of excess sodium, which can be accomplished by a combination of diuretics and D5W infusion. Patients with acute renal failure may require dialysis.
Traditionally, correction of hypernatremia begins with a calculation of the fluid deficit as shown below. Predicted insensible and other ongoing losses are added to this number and the total is administered over 48 hours. Recheck serum electrolyte levels frequently during therapy. To avoid cerebral edema and associated complications, the serum sodium level should be raised by no more than 1 mEq/L every hour. In patients with chronic hypernatremia, an even more gradual rate is preferred.
An alternative method to plan the correction of sodium imbalances has been proposed by Adrogue and Madias. They have devised a formula that can be used to calculate the change in serum sodium level after the administration of 1 L of a given infusate. This formula has the advantages of taking into consideration the tonicity of the infusate and encouraging reassessment of the treatment plan with each liter of solution or new set of electrolytes.
Free Water Deficit = Body Weight (kg) X Percentage of Total Body Water (TBW) X ([Serum Na / 140] - 1)
The percentage of TBW should be as follows:
The Adrogue and Madias formula is as follows: Change in Serum Sodium = ([Na] Infused - [Na] serum) / (TBW + 1)
The "1" in the denominator represents the extra liter of infusate added to TBW. When TBW is calculated as above, TBW = Body Weight (kg) X Percent Water
An example is as follows: For the patient above, the expected change can be calculated with D5W or D5 half isotonic sodium chloride solution.
For D5W, Change = (0 - 155) / ([60 X 0.6] + 1) = -4.18 mEq/L
For half isotonic sodium chloride solution, Change = (77 - 155) / ([60 X 0.6] + 1) = -2.1 mEq/L
If D5W is chosen to avoid fluid overload, an infusion rate of 250 mL/h results in a correction just over 1 mEq/h. (Note: This assumes the patient has no other losses during this time. Intrinsic losses make the correction slower [more conservative] than calculated.)
Hypernatremia should not be corrected at a rate greater than 1 mEq/L per hour.
Carefully monitor all patients' inputs and outputs during treatment.
Consider CNS imaging to exclude a central cause or to identify CNS bleeding from stretching of veins.
Using isotonic sodium chloride solution, stabilize hypovolemic patients who have unstable vital signs before correcting free water deficits because hypotonic fluids quickly leave the intravascular space and do not help to correct hemodynamics. Once stabilization has occurred, free water deficits can be replaced either orally or intravenously.
Euvolemic patients can be treated with hypotonic fluids, either orally or intravenously (ie, dextrose 5% in water solution [D5W], quarter or half isotonic sodium chloride solution), to correct free fluid deficits.
Hypervolemic patients require removal of excess sodium, which can be accomplished by a combination of diuretics and D5W infusion. Patients with acute renal failure may require dialysis.
Traditionally, correction of hypernatremia begins with a calculation of the fluid deficit as shown below. Predicted insensible and other ongoing losses are added to this number and the total is administered over 48 hours. Recheck serum electrolyte levels frequently during therapy. To avoid cerebral edema and associated complications, the serum sodium level should be raised by no more than 1 mEq/L every hour. In patients with chronic hypernatremia, an even more gradual rate is preferred.
An alternative method to plan the correction of sodium imbalances has been proposed by Adrogue and Madias. They have devised a formula that can be used to calculate the change in serum sodium level after the administration of 1 L of a given infusate. This formula has the advantages of taking into consideration the tonicity of the infusate and encouraging reassessment of the treatment plan with each liter of solution or new set of electrolytes.
Free Water Deficit = Body Weight (kg) X Percentage of Total Body Water (TBW) X ([Serum Na / 140] - 1)
The percentage of TBW should be as follows:
- Young men - 0.6%
- Young women and elderly men - 0.5%
- Elderly women - 0.4%
The Adrogue and Madias formula is as follows: Change in Serum Sodium = ([Na] Infused - [Na] serum) / (TBW + 1)
The "1" in the denominator represents the extra liter of infusate added to TBW. When TBW is calculated as above, TBW = Body Weight (kg) X Percent Water
An example is as follows: For the patient above, the expected change can be calculated with D5W or D5 half isotonic sodium chloride solution.
For D5W, Change = (0 - 155) / ([60 X 0.6] + 1) = -4.18 mEq/L
For half isotonic sodium chloride solution, Change = (77 - 155) / ([60 X 0.6] + 1) = -2.1 mEq/L
If D5W is chosen to avoid fluid overload, an infusion rate of 250 mL/h results in a correction just over 1 mEq/h. (Note: This assumes the patient has no other losses during this time. Intrinsic losses make the correction slower [more conservative] than calculated.)
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