Fluids & Electrolytes Lecture PDF

Summary

This lecture covers fluids and electrolytes, including their roles, functions, and implications for patient treatment, presented by Eiman Bakri, a Clinical Pharmacist from NUSU.

Full Transcript

Fluids & electrolytes
Presented by:
Eiman Bakri
Clinical Pharmacy, NUSU
 Objectives
Assess electrolyte abnormalities and
recommend an appropriate pharmacologic
treatment plan
Discuss the appropriate role and risks of
hypertonic and hypotonic saline
Recommend an appropriate intravenous fluid
regimen and monitoring parameters
Distribution of total body fluid
 Body Water Compartments and Electrolyte
Composition
Two thirds of the total body water resides in
the cells (intracellular water)
The extracellular water can be divided into
different compartments—the interstitial fluid
and the plasma
The kidneys play an important role in
maintaining a constant extracellular
environment by regulating the excretion of
water and various electrolytes
 Potassium, magnesium, and phosphate are
the major ions in the intracellular
compartment,
Whereas sodium, chloride, and bicarbonate
are predominant in the extracellular space
Water moves across the cell membrane from a
region of low osmolality to one of high
osmolality
Differences between ECF and ICF in a
70 Kg adult male
 Plasma Osmolality

It is determined by the number of particles in
solution
Plasma osmolality reflects the osmolality of
total body water
The osmolality of body fluid is maintained
between 280 and 295 mOsm/kg
 Volume regulation

Antidiuretic hormone (ADH) plays an
important role in maintaining fluid balance in
the body.
Aldosterone is the main regulatory hormone
for sodium homeostasis.
Fluid Management

Intravascular volume makes us
go…
 Fluid resuscitation
Is indicated in patients with signs and symptoms
of intravascular volume depletion.

The goal of fluid resuscitation is to restore
intravascular volume and prevent organ
hypoperfusion

Because intravascular volume depletion can
cause organ dysfunction and death, prompt
resuscitation is necessary
 Signs and Symptoms of Intravascular Volume
Depletion
Tachycardia (HR > 100 beats/min)
Hypotension (SBP < 80 mmHg)
Orthostatic changes in HR or BP
Increased BUN/SCr ratio > 20:1
Dry mucous membranes
Decreased skin turgor
Reduced urine output
Dizziness
Improvement in HR and BP after a 500-to 1000-
mL fluid bolus
 Crystalloids VERSUS Colloids

The most commonly used Crystalloids are:
Normal saline, Ringer lactate and Dextrose in water.

Crystalloids like Na and Cl do not freely cross into
cells, but they will distribute evenly in the EC
space

D5W is metabolized to water and carbon dioxide.
Water can cross any membrane in the
body; therefore, it is evenly distributed in TBF
▪ Colloids include:
Packed red blood cells,
Pooled human plasma (5% albumin, 25% albumin,
and 5% plasma protein fraction)
Semisynthetic glucose polymers (dextran)
Hetastarch
Colloids are too large to cross the capillary
membrane; therefore, they remain primarily in the
intravascular space
Distribution of IV fluids
 Crystalloids (0.9% sodium chloride or lactated
Ringer solution) are recommended for fluid
resuscitation in hypovolemia

Colloids may be considered after fluid
resuscitation with crystalloid (usually 4–6 L)
has failed to achieve hemodynamic goals or
after clinically significant edema limits the
further administration of crystalloid
Albumin (theoretically, 25% is preferred) may be
consideredin conjunction with diuretics for
patients with:
Clinically significant edema (e.g., pulmonary
edema causing respiratory failure)
An albumin concentration less than 2.5 g/dL
 The choice of replacement fluid to replenish the
extracellular volume depends on the sodium
status.
The treatment goal is to achieve a positive fluid
balance.
In patients who are neither hypo- nor
hypernatremic, normal saline should be used.
In patients who are hypernatremic, half-isotonic
saline or dextrose solutions should be used.
 Maintenance Intravenous Fluids

Maintenance intravenous fluids are indicated in
patients who are unable to tolerate oral fluids.
The goal of maintenance intravenous fluids is to
prevent dehydration and maintain a normal fluid
and electrolyte balance.
Maintenance intravenous fluids are typically
administered as a continuous infusion through a
peripheral or central intravenous catheter.
 Common methods of estimating the daily
volume in children and adults

Administer 100 mL/kg for first 10 kg
+ 50 mL/kg for the next 10–20 kg (i.e., 1500 mL so
far)
+ 20 mL/kg for every kilogram greater than 20 kg
= (~2500ml/day)
Or
Administer 20–40 mL/kg/day (for adults only).
 Disorders in Osmoregulation

❖Hyponatremia:
A patient may have hypotonic, isotonic, or
hypertonic hyponatremia depending on
plasma osmolality.
❖ According to volume status, hyponatremia is
divided into:
1. Hypovolemic hypotonic hyponatremia
2. Hypervolemic hypotonic hyponatremia
3. Normovolemic hypotonic hyponatremia
 Hypovolemic hypotonic hyponatremia can
occur with volume depletion and extracellular
fluid depletion
Treatment involves sodium replacement to
correct the deficit
 Hypervolemic hypotonic hyponatremia is
caused by excess water intake relative to
sodium.
It is also seen in patients with heart failure,
liver or renal failure, and nephrotic syndrome.
Water restriction is the mainstay of therapy.
 Normovolemic hypotonic hyponatremia can
be caused by syndrome of inappropriate
antidiuretic hormone (SIADH).
Persistent ADH secretion together with water
ingestion results in hyponatremia.
All fluids should be reduced.
Diuretics furosemide or demeclocycline are
treatment options
 Disorders in Osmoregulation(cont)

❖Hypernatremia:
Occur with:
Normal total body sodium and pure water loss
Low total body sodium with hypotonic fluid
loss
High total body sodium as a result of salt gain
 Hypernatremia(cont)
Management includes
Correcting the underlying cause of the
hypertonic state
Replacing water deficits
Administering adequate water to match
ongoing losses
 Clinical Use of Diuretics
o Diuretics reduce sodium and chloride
reabsorption in the renal tubules, thereby
increasing urine volume.

o Individual diuretics can be categorized
according to their site of action in the renal
tubules
 Loop diuretics(e.g., furosemide, bumetanide,
torsemide, ethacrynic acid) are the most
potent diuretics.
Thiazide diuretics and other sulfonamide
diuretics (e.g., chlorthalidone) are less potent
than loop diuretics. They can enhance
reabsorption of calcium, so are useful in
patients with kidney stones. Magnesium
excretion is increased by thiazides.
 Potassium-sparing diuretics (e.g.
spironolactone, triamterene, amiloride) are
less potent but offer the advantage of sparing
potassium loss.
Acetazolamide inhibits carbonic anhydrase. It
has limited diuretic and natriuretic effects. ?
Osmotic diuretics (e.g., mannitol, urea) are
non resorbable solutes.
 Clinical case
Q.B., a 30-year-old male athlete who has had
multiple bouts of diarrhea for the last several
days, has been drinking a sports drink to keep
himself from getting dehydrated.
His vital signs include supine BP, 145/80 mm Hg,
and pulse, 70 beats/minute; standing BP, 128/68
mm Hg, and pulse, 90 beats/minute.
Respiratory rate (RR) is 12 breaths/minute, and
he is afebrile.
His skin turgor is mildly decreased and
laboratory data are the following:
Na, 128 mEq/L K, 3.0 mEq/L
Cl, 100 mEq/L Bicarbonate, 17 mEq/L
BUN, 27 mg/dL Creatinine, 1.2 mg/dL
Urinary sodium and chloride were both less than
10 mEq/L.
 Assess Q.B.’s electrolyte and fluid status. What
is the etiology of Q.B.’s hyponatremia?
How should Q.B.’s hyponatremia be treated?