Fluid and Electrolytes PDF

Summary

This document provides a detailed analysis of fluid and electrolyte balance in the human body. It explains the physiology of these crucial substances along with the role of various organs in maintaining homeostasis. It also discusses different types of fluid and electrolytes, their concentration, movements, and imbalances, affecting the body's equilibrium.

Full Transcript

Fundamental Concepts
Nurses need to understand the physiology of fluid and electrolyte balance and acid–base
balance to anticipate, identify, and respond to possible imbalances. Nurses use effective
education and communication skills to help prevent and treat various fluid and electrolyte
disturbances.

Amount and Composition of Body Fluids
Approximately 60% of a typical adult’s weight consists of fluid (water and electrolytes)
(see Fig. 13-1). Factors that influence the amount of body fluid are age, gender, and body
fat. In general, younger people have a higher percentage of body fluid than older adults,
and men have proportionately more body fluid than women. People who are obese have
less fluid than those who are thin, because fat cells contain little water. The skeleton also
has low water content. Muscle, skin, and blood contain the highest amounts of water
(Grossman & Porth, 2014). Body fluid is located in two fluid compartments: the
intracellular space (fluid in the cells) and the extracellular space (fluid outside the cells).
Approximately two thirds of body fluid is in the intracellular fluid (ICF) compartment and
is located primarily in the skeletal muscle mass

Approximately one third is in the extracellular fluid (ECF) compartment (Grossman &
Porth, 2014). The ECF compartment is further divided into the intravascular, interstitial,
and transcellular fluid spaces: The intravascular space (the fluid within the blood vessels)
contains plasma, the effective circulating volume. Approximately 3 L of the average 6 L
of blood volume in adults is made up of plasma. The remaining 3 L is made up of
erythrocytes, leukocytes, and thrombocytes. The interstitial space contains the fluid that
surrounds the cell and totals about 11 to 12 L in an adult. Lymph is an interstitial fluid.
The transcellular space is the smallest division of the ECF compartment and contains
approximately 1 L. Examples of transcellular fluids include cerebrospinal, pericardial,
synovial, intraocular, and pleural fluids, sweat, and digestive secretions.

The ECF transports electrolytes; it also carries other substances, such as enzymes and
hormones. Body fluid normally moves between the two major compartments or spaces in
an effort to maintain equilibrium between the spaces. Loss of fluid from the body can
disrupt this equilibrium. Sometimes fluid is not lost from the body but is unavailable for
use by either the ICF or ECF. Loss of ECF into a space that does not contribute to
equilibrium between the ICF and the ECF is referred to as a third-space fluid shift, or third
spacing (Papadakis & McPhee, 2016). Early evidence of a third-space fluid shift is a
decrease in urine output despite adequate fluid intake. Urine output decreases because
fluid shifts out of the intravascular space; the kidneys then receive less blood and attempt
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to compensate by decreasing urine output. Other signs and symptoms of third spacing
that indicate an intravascular fluid volume deficit (FVD) include increased heart rate,
decreased blood pressure, decreased central venous pressure, edema, increased body
weight, and imbalances in fluid intake and output (I&O). This fluid will be reabsorbed back
into the extracellular space over a period of a few days to a few weeks. However, the
acute volume depletion must be restored to prevent further complications. Examples of
causes of third-space fluid losses include intestinal obstruction, pancreatitis, crushing
traumatic injuries, bleeding (trauma or dissected aortic aneurysm), peritonitis, and major
venous obstruction (Sterns, 2014a)

Electrolytes
Electrolytes in body fluids are active chemicals (cations that carry positive charges and
anions that carry negative charges). The major cations in body fluid are sodium,
potassium, calcium, magnesium, and hydrogen ions. The major anions are chloride,
bicarbonate, phosphate, sulfate, and proteinate ions. These chemicals unite in varying
combinations. Therefore, electrolyte concentration in the body is expressed in terms of
milliequivalents (mEq) per liter, a measure of chemical activity, rather than in terms of
milligrams (mg), a unit of weight. More specifically, a milliequivalent is defined as being
equivalent to the electrochemical activity of 1 mg of hydrogen. In a solution, cations and
anions are equal in milliequivalents per liter. Electrolyte concentrations in the ICF differ
from those in the ECF. Because special techniques are required to measure electrolyte
concentrations in the ICF, it is customary to measure the electrolytes in the most
accessible portion of the ECF—namely, the plasma. Sodium ions, which are positively
charged, far outnumber the other cations in the ECF. Because sodium concentration
affects the overall concentration of the ECF, sodium is important in regulating the volume
of body fluid. Retention of sodium is associated with fluid retention, and excessive loss of
sodium is usually associated with decreased volume of body fluid.

The major electrolytes in the ICF are potassium and phosphate. The ECF has a low
concentration of potassium and can tolerate only small changes in potassium
concentrations. Therefore, the release of large stores of intracellular potassium, typically
caused by trauma to the cells and tissues, can be extremely dangerous.

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The body expends a great deal of energy maintaining the high extracellular concentration
of sodium and the high intracellular concentration of potassium. It does so by means of
cell membrane pumps that exchange sodium and potassium ions. Normal movement of
fluids through the capillary wall into the tissues depends on hydrostatic pressure (the
pressure exerted by the fluid on the walls of the blood vessel) at both the arterial and the
venous ends of the vessel and the osmotic pressure exerted by the protein of plasma.
The direction of fluid movement depends on the differences in these two opposing forces
(hydrostatic vs. osmotic pressure).

Regulation of Body Fluid Compartments
Osmosis and Osmolality When two different solutions are separated by a membrane that
is impermeable to the dissolved substances, fluid shifts through the membrane from the
region of low solute concentration to the region of high solute concentration until the
solutions are of equal concentration. This diffusion of water caused by a fluid
concentration gradient is known as osmosis (see Fig. 13-2A). The magnitude of this force
depends on the number of particles dissolved in the solutions, not on their weights. The
number of dissolved particles contained in a unit of fluid determines the osmolality of a
solution, which influences the movement of fluid between the fluid compartments. Tonicity
is the ability of all solutes to cause an osmotic driving force that promotes water movement
from one compartment to another. The control of tonicity determines the normal state of
cellular hydration and cell size. Sodium, mannitol, glucose, and sorbitol are effective
osmoles (capable of affecting water movement). Three other terms are associated with
osmosis—osmotic pressure, oncotic pressure, and osmotic diuresis: Osmotic pressure is
the amount of hydrostatic pressure needed to stop the flow of water by osmosis. It is
primarily determined by the concentration of solutes. Oncotic pressure is the osmotic
pressure exerted by proteins (e.g., albumin). Osmotic diuresis is the increase in urine
output caused by the excretion of substances, such as glucose, mannitol, or contrast
agents in the urine. Diffusion Diffusion is the natural tendency of a substance to move
from an area of higher concentration to one of lower concentration (see Fig. 13-2B). It
occurs through the random movement of ions and molecules (Grossman & Porth, 2014).
Examples of diffusion are the exchange of oxygen and carbon dioxide (CO2) between the
pulmonary capillaries and alveoli and the tendency of sodium to move from the ECF
compartment, where the sodium concentration is high, to the ICF, where its concentration
is low.

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Filtration
Hydrostatic pressure in the capillaries tends to filter fluid out of the intravascular
compartment into the interstitial fluid. Movement of water and solutes occurs from an area
of high hydrostatic pressure to an area of low hydrostatic pressure. The kidneys filter
approximately 180 L of plasma per day. Another example of filtration is the passage of
water and electrolytes from the arterial capillary bed to the interstitial fluid; in this instance,
the hydrostatic pressure results from the pumping action of the heart.

Sodium–Potassium Pump
The sodium concentration is greater in the ECF than in the ICF; because of this, sodium
tends to enter the cell by diffusion. This tendency is offset by the sodium–potassium pump
that is maintained by the cell membrane and actively moves sodium from the cell into the
ECF. Conversely, the high intracellular potassium concentration is maintained by
pumping potassium into the cell. By definition, active transport implies that energy must
be expended for the movement to occur against a concentration gradient.

Systemic Routes of Gains and Losses Water and electrolytes are gained in various ways.
Healthy people gain fluids by drinking and eating, and their daily average I&O of water
are approximately equal

Kidneys
The usual daily urine volume in the adult is 1 to 2 L (Grossman & Porth, 2014; Sterns,
2014a). A general rule is that the output is approximately 1 mL of urine per kilogram of
body weight per hour (1 mL/kg/h) in all age groups.

Skin
Sensible perspiration refers to visible water and electrolyte loss through the skin
(sweating). The chief solutes in sweat are sodium, chloride, and potassium. Actual sweat
losses can vary from 0 to 1000 mL or more every hour, depending on factors such as the
environmental temperature. Continuous water loss by evaporation (approximately 500
mL/day) occurs through the skin as insensible perspiration, a nonvisible form of water
loss (Grossman & Porth, 2014). Fever and exercise greatly increase insensible water loss
through the lungs and the skin, as does the loss of the natural skin barrier (e.g., through
major burns) (Earhart, Weiss, Rahman, et al., 2015; Sterns, 2014b).

Lungs
The lungs normally eliminate water vapor (insensible loss) at a rate of approximately 300
mL every day (Grossman & Porth, 2014). The loss is much greater with increased
respiratory rate or depth, or in a dry climate.

Gastrointestinal Tract
The usual loss through the gastrointestinal (GI) tract is 100 to 200 mL daily, even though
approximately 8 L of fluid circulates through the GI system every 24 hours. Because the
bulk of fluid is normally reabsorbed in the small intestine, diarrhea and fistulas cause large
losses.

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Homeostatic Mechanisms
The body is equipped with remarkable homeostatic mechanisms to keep the composition
and volume of body fluid within narrow limits of normal. Organs involved in homeostasis
include the kidneys, heart, lungs, pituitary gland, adrenal glands, and parathyroid glands
(Grossman & Porth, 2014).

Kidney Functions
Vital to the regulation of fluid and electrolyte balance, the kidneys normally filter 180 L of
plasma every day in the adult and excrete 1 to 2 L of urine (Inker & Perrone, 2014). They
act both autonomously and in response to bloodborne messengers, such as aldosterone
and antidiuretic hormone (ADH) (Grossman & Porth, 2014). Major functions of the kidneys
in maintaining normal fluid balance include the following:
Regulation of ECF volume and osmolality by selective retention and excretion of body
fluids
Regulation of normal electrolyte levels in the ECF by selective electrolyte retention and
excretion
Regulation of pH of the ECF by retention of hydrogen ions
Excretion of metabolic wastes and toxic substances (Inker & Perrone, 2014)

Given these functions, failure of the kidneys results in multiple fluid and electrolyte
abnormalities.

Heart and Blood Vessel Functions
The pumping action of the heart circulates blood through the kidneys under sufficient
pressure to allow for urine formation. Failure of this pumping action interferes with renal
perfusion and thus with water and electrolyte regulation.

Lung Functions
The lungs are also vital in maintaining homeostasis. Through exhalation, the lungs
remove approximately 300 mL of water daily in the normal adult (Sterns, 2014d).
Abnormal conditions, such as hyperpnea (abnormally deep respiration) or continuous
coughing, increase this loss; mechanical ventilation with excessive moisture decreases
it. The lungs also play a major role in maintaining acid–base balance.

Pituitary Functions
The hypothalamus manufactures ADH, which is stored in the posterior pituitary gland and
released as needed to conserve water. Functions of ADH include maintaining the osmotic
pressure of the cells by controlling the retention or excretion of water by the kidneys and
by regulating blood volume

Adrenal Functions
Aldosterone, a mineralocorticoid secreted by the zona glomerulosa (outer zone) of the
adrenal cortex, has a profound effect on fluid balance. Increased secretion of aldosterone
causes sodium retention (and thus water retention) and potassium loss. Conversely,
decreased secretion of aldosterone causes sodium and water loss and potassium
retention.

Cortisol, another adrenocortical hormone, has less mineralocorticoid action. However,
when secreted in large quantities (or given as corticosteroid therapy), it can also produce
sodium and fluid retention.

Parathyroid Functions
The parathyroid glands, embedded in the thyroid gland, regulate calcium and phosphate
balance by means of parathyroid hormone (PTH). PTH influences bone reabsorption,
calcium absorption from the intestines, and calcium reabsorption from the renal tubules.

Other Mechanisms
Changes in the volume of the interstitial compartment within the ECF can occur without
affecting body function. However, the vascular compartment cannot tolerate change as
readily and must be carefully maintained to ensure that tissues receive adequate
nutrients
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Baroreceptors
The baroreceptors are located in the left atrium and the carotid and aortic arches. These
receptors respond to changes in the circulating blood volume and regulate sympathetic
and parasympathetic neural activity as well as endocrine activities.

As arterial pressure decreases, baroreceptors transmit fewer impulses from the carotid
and the aortic arches to the vasomotor center. A decrease in impulses stimulates the
sympathetic nervous system and inhibits the parasympathetic nervous system. The
outcome is an increase in cardiac rate, conduction, and contractility and an increase in
circulating blood volume. Sympathetic stimulation constricts renal arterioles; this
increases the release of aldosterone, decreases glomerular filtration, and increases
sodium and water reabsorption (Hall, 2015).

Renin–Angiotensin–Aldosterone System
Renin is an enzyme that converts angiotensinogen, a substance formed by the liver,
into angiotensin I (Grossman & Porth, 2014). Renin is released by the juxtaglomerular
cells of the kidneys in response to decreased renal perfusion (McGloin, 2015).
Angiotensin-converting enzyme (ACE) converts angiotensin I to angiotensin II.
Angiotensin II, with its vasoconstrictor properties, increases arterial perfusion pressure
and stimulates thirst. As the sympathetic nervous system is stimulated, aldosterone is
released in response to an increased release of renin. Aldosterone is a volume
regulator and is also released as serum potassium increases, serum sodium decreases,
or adrenocorticotropic hormone (ACTH) increases.

Antidiuretic Hormone and Thirst ADH and the thirst mechanism have important roles in
maintaining sodium concentration and oral intake of fluids (Sterns, 2014e). Oral intake
is controlled by the thirst center located in the hypothalamus (Grossman & Porth, 2014).
As serum concentration or osmolality increases or blood volume decreases, neurons in
the hypothalamus are stimulated by intracellular dehydration; thirst then occurs, and the
person increases their intake of oral fluids. Water excretion is controlled by ADH,
aldosterone, and baroreceptors, as mentioned previously. The presence or absence of
ADH is the most significant factor in determining whether the urine that is excreted is
concentrated or dilute.

Osmoreceptors Located on the surface of the hypothalamus, osmoreceptors sense
changes in sodium concentration. As osmotic pressure increases, the neurons become
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dehydrated and quickly release impulses to the posterior pituitary, which increases the
release of ADH, which then travels in the blood to the kidneys, where it alters
permeability to water, causing increased reabsorption of water and decreased urine
output. The retained water dilutes the ECF and returns its concentration to normal.
Restoration of normal osmotic pressure provides feedback to the osmoreceptors to
inhibit further ADH release

Natriuretic Peptides
Natriuretic peptide hormones affect fluid volume and cardiovascular function through the
excretion of sodium (natriuresis), direct vasodilation, and the opposition of the rennin–
angiotensin–aldosterone system. Four peptides have been identified. The first is atrial
natriuretic peptide (ANP) produced by the atrial myocardium with tissue distribution in
the cardiac atria and ventricles. The second is brain natriuretic peptide (BNP) produced
by the ventricular myocardium with tissue distribution in the brain and cardiac ventricles
(Colucci & Chen, 2014). ANP, also called atrial natriuretic factor, atrial natriuretic
hormone, or atriopeptin, is a peptide that is synthesized, stored, and released by muscle
cells of the atria of the heart in response to several factors. These factors include
increased atrial pressure, angiotensin II stimulation, endothelin (a powerful
vasoconstrictor of vascular smooth muscle that is a peptide released from damaged
endothelial cells in the kidneys or other tissues), and sympathetic stimulation. Any
condition that results in volume expansion (exercise, pregnancy), calorie restriction,
hypoxia, or increased cardiac filling pressures (e.g., high sodium intake, heart failure,
chronic kidney disease, atrial tachycardia, or use of vasoconstrictor agents such as
epinephrine) increases the release of ANP and BNP. ANP’s action decreases water,
sodium, and adipose loads on the circulatory system to decrease blood pressure. The
action of ANP is therefore directly opposite of the renin angiotensin–aldosterone
system. The ANP measured in plasma is normally 20 to 77 pg/mL (20 to 77 ng/L). This
level increases in acute heart failure, paroxysmal supraventricular tachycardia,
hyperthyroidism, subarachnoid hemorrhage, and small cell lung cancer. The level
decreases in chronic heart failure and with the use of medications such as enalapril
(Vasotec) (Frandsen & Pennington, 2014). The third peptide is C-type natriuretic
peptide (CNP), which has tissue distribution in the brain, ovary, uterus, testis, and
epididymis. The fourth peptide is D-type natriuretic peptide (DNP)—the newest peptide
with structural similarities to ANP, BNP, and CNP.

FLUID VOLUME DISTURBANCES
Hypovolemia FVD, or hypovolemia, occurs when loss of ECF volume exceeds the
intake of fluid. It occurs when water and electrolytes are lost in the same proportion as
they exist in normal body fluids; thus, the ratio of serum electrolytes to water remains
the same. FVD should not be confused with dehydration, which refers to loss of water
alone, with increased serum sodium levels. FVD may occur alone or in combination with
other imbalances. Unless other imbalances are present concurrently, serum electrolyte
concentrations remain essentially unchanged.

Pathophysiology
FVD results from loss of body fluids and occurs more rapidly when coupled with
decreased fluid intake. FVD can also develop with a prolonged period of inadequate
intake. Causes of FVD include abnormal fluid losses, such as those resulting from
vomiting, diarrhea, GI suctioning, and sweating; decreased intake, as in nausea or lack
of access to fluids; and third-space fluid shifts, or the movement of fluid from the
vascular system to other body spaces (e.g., with edema formation in burns, ascites with
liver dysfunction). Additional causes include diabetes insipidus (a decreased ability to
concentrate urine owing to a defect in the kidney tubules that interferes with water
reabsorption), adrenal insufficiency, osmotic diuresis, hemorrhage, and coma.

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Clinical Manifestations
FVD can develop rapidly, and its severity depends on the degree of fluid loss.

Assessment and Diagnostic Findings
Laboratory data useful in evaluating fluid volume status include BUN and its relation to
serum creatinine concentration. Normal BUN to serum creatinine concentration ratio is
10:1. A volume-depleted patient has a BUN elevated out of proportion to the serum
creatinine (ratio greater than 20:1) (Sterns, 2014a). The presence and cause of
hypovolemia may be determined through the health history and physical examination. In
addition, the hematocrit level is greater than normal because there is a decreased
plasma volume.
Serum electrolyte changes may also exist. Potassium and sodium levels can be
reduced (hypokalemia, hyponatremia) or elevated (hyperkalemia, hypernatremia).
Hypokalemia occurs with GI and renal losses.
Hyperkalemia occurs with adrenal insufficiency.
Hyponatremia occurs with increased thirst and ADH release
Hypernatremia results from increased insensible losses and diabetes insipidus.

There may or may not be a decrease in urine (oliguria) in hypovalemia. Urine specific
gravity is increased in relation to the kidneys’ attempt to conserve water and is
decreased with diabetes insipidus. Aldosterone is secreted when fluid volume is low
causing reabsorption of sodium and chloride, resulting in decreased urinary sodium and
chloride. Urine osmolality can be greater than 450 mOsm/kg because the kidneys try to
compensate by conserving water.

Medical Management
When planning the correction of fluid loss for the patient with FVD, the primary provider
considers the patient’s maintenance requirements and other factors (e.g., fever) that
can influence fluid needs. If the deficit is not severe, the oral route is preferred, provided
the patient can drink. However, if fluid losses are acute or severe, the IV route is
required. Isotonic electrolyte solutions (e.g., lactated Ringer solution, 0.9% sodium
chloride) are frequently the first-line choice to treat the hypotensive patient with FVD
because they expand plasma volume (Sterns, 2014e). As soon as the patient becomes
normotensive, a hypotonic electrolyte solution (e.g., 0.45% sodium chloride) is often
used to provide both electrolytes and water for renal excretion of metabolic wastes.

Accurate and frequent assessments of I&O, weight, vital signs, central venous pressure,
level of consciousness, breath sounds, and skin color are monitored to determine when
therapy should be slowed to avoid volume overload. The rate of fluid administration is
based on the severity of loss and the patient’s hemodynamic response to volume
replacement.

If the patient with severe FVD is not excreting enough urine and is therefore oliguric, the
primary provider needs to determine whether the depressed renal function is caused by
reduced renal blood flow secondary to FVD (prerenal azotemia) or, more seriously, by
acute tubular necrosis from prolonged FVD. The test used in this situation is referred to
as a fluid challenge test. During a fluid challenge test, volumes of fluid are given at
specific rates and intervals while the patient’s hemodynamic response to this treatment
is monitored (i.e., vital signs, breath sounds, orientation status, central venous pressure,
urine output).
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Shock can occur when the volume of fluid lost exceeds 25% of the intravascular volume
or when fluid loss is rapid.

Nursing Management
To assess for FVD, the nurse monitors and measures fluid I&O at least every 8 hours,
and sometimes hourly. Researchers have reported that maintaining an accurate I&O is
a particular challenge with patients in critical care settings (Diacon & Bell, 2014) (see
Chart 13-1). As FVD develops, body fluid losses exceed fluid intake through excessive
urination (polyuria), diarrhea, vomiting, or other mechanisms. Once FVD has developed,
the kidneys attempt to conserve body fluids, leading to a urine output of less than 1
mL/kg/h in an adult. Urine in this instance is concentrated and represents a healthy
renal response. Daily body weights are monitored; an acute loss of 0.5 kg (1.1 lb)
represents a fluid loss of approximately 500 mL (1 L of fluid weighs approximately 1 kg,
or 2.2 lb).
Vital signs are closely monitored. The nurse observes for a weak, rapid pulse and
orthostatic hypotension (i.e., a decrease in systolic pressure exceeding 20 mm Hg when
the patient moves from a lying to a sitting position. A decrease in body temperature
often accompanies FVD, unless there is a concurrent infection.

Skin and tongue turgor are monitored on a regular basis. In a healthy person, pinched
skin immediately returns to its normal position when released (Weber & Kelley, 2014).
This elastic property, referred to as turgor, is partially dependent on interstitial fluid
volume. In a person with FVD, the skin flattens more slowly after the pinch is released.
In a person with severe FVD, the skin may remain elevated for many seconds. Tissue
turgor is best measured by pinching the skin over the sternum, inner aspects of the
thighs, or forehead. Tongue turgor is not affected by age (see previous Gerontologic
Considerations), and evaluating this may be more valid than evaluating skin turgor
(Sterns, 2014a). In a normal person, the tongue has one longitudinal furrow. In the
person with FVD, there are additional longitudinal furrows and the tongue is smaller
because of fluid loss. The degree of oral mucous membrane moisture is also assessed;
a dry mouth may indicate either FVD or mouth breathing.

Hypervolemia
Fluid volume excess (FVE), or hypervolemia, refers to an isotonic expansion of the ECF
caused by the abnormal retention of water and sodium in approximately the same
proportions in which they normally exist in the ECF. It is most often secondary to an
increase in the total-body sodium content, which, in turn, leads to an increase in total-
body water. Because there is isotonic retention of body substances, the serum sodium
concentration remains essentially normal

Pathophysiology
FVE may be related to simple fluid overload or diminished function of the homeostatic
mechanisms responsible for regulating fluid balance. Contributing factors can include
heart failure, kidney injury, and cirrhosis of the liver. Another contributing factor is
consumption of excessive amounts of table or other sodium salts. Excessive
administration of sodium-containing fluids in a patient with impaired regulatory
mechanisms may predispose him or her to a serious FVE as well

Clinical Manifestations
Clinical manifestations of FVE result from expansion of the ECF and may include
edema, distended neck veins, and crackles (abnormal lung sounds).
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Assessment and Diagnostic Findings
Laboratory data useful in diagnosing FVE include BUN and hematocrit levels. In FVE,
both of these values may be decreased because of plasma dilution, low protein intake,
and anemia. In chronic kidney disease, both serum osmolality and the sodium level are
decreased owing to excessive retention of water. The urine sodium level is increased if
the kidneys are attempting to excrete excess volume. A chest x-ray may reveal
pulmonary congestion. Hypervolemia occurs when aldosterone is chronically stimulated
(i.e., cirrhosis, heart failure, and nephrotic syndrome). Therefore, the urine sodium level
does not increase in these conditions.

Medical Management
Management of FVE is directed at the causes, and if related to excessive administration
of sodium-containing fluids, discontinuing the infusion may be all that is needed.
Symptomatic treatment consists of administering diuretics and restricting fluids and
sodium.

Pharmacologic Therapy
Diuretics are prescribed when dietary restriction of sodium alone is insufficient to reduce
edema by inhibiting the reabsorption of sodium and water by the kidneys. The choice of
diuretic is based on the severity of the hypervolemic state, the degree of impairment of
renal function, and the potency of the diuretic. Thiazide diuretics block sodium
reabsorption in the distal tubule, where only 5% to 10% of filtered sodium is reabsorbed.
Loop diuretics, such as furosemide (Lasix) or torsemide (Demadex), can cause a
greater loss of both sodium and water because they block sodium reabsorption in the
ascending limb of Henle loop, where 20% to 30% of filtered sodium is normally
reabsorbed. Generally, thiazide diuretics, such as hydrochlorothiazide (Microzide), are
prescribed for mild to moderate hypervolemia and loop diuretics for severe
hypervolemia (Comeford, 2015; Frandsen & Pennington, 2014).

Electrolyte imbalances may result from side effects of diuretics. Hypokalemia can occur
with all diuretics except those that work in the last distal tubule of the nephrons.
Potassium supplements can be prescribed to avoid this complication. Hyperkalemia can
occur with diuretics that work in the distal tubule (e.g., spironolactone [Aldactone], a
potassium-sparing diuretic), especially in patients with decreased renal function.
Hyponatremia occurs with diuresis owing to increased release of ADH secondary to
reduction in circulating volume. Decreased magnesium levels occur with administration
of loop and thiazide diuretics due to decreased reabsorption and increased excretion of
magnesium by the kidney.
Azotemia (increased nitrogen levels in the blood) can occur with FVE when urea and
creatinine are not excreted owing to decreased perfusion by the kidneys and decreased
excretion of wastes. High uric acid levels (hyperuricemia) can also occur from increased
reabsorption and decreased excretion of uric acid by the kidneys.

Dialysis
If renal function is so severely impaired that pharmacologic agents cannot act efficiently,
other modalities are considered to remove sodium and fluid from the body.
Hemodialysis or peritoneal dialysis may be used to remove nitrogenous wastes and
control potassium and acid–base balance, and to remove sodium and fluid. Continuous
renal replacement therapy may also be required.

Nutritional Therapy
Treatment of FVE usually involves dietary restriction of sodium. An average daily diet
not restricted in sodium contains 6 to 15 g of salt, whereas low-sodium diets can range
from a mild restriction to as little as 250 mg of sodium per day, depending on the
patient’s needs. A mild sodium-restricted diet allows only light salting of food (about half
the usual amount) in cooking and at the table, and no addition of salt to commercially
prepared foods that are already seasoned. Foods high in sodium must be avoided. It is
the sodium salt (sodium chloride) rather than sodium itself that contributes to edema.
Therefore, patients are instructed to read food labels carefully to determine salt content.

Medical Surgical Nursing Fluids & Electrolytes
Because about half of ingested sodium is in the form of seasoning, seasoning
substitutes can play a major role in decreasing sodium intake. Lemon juice, onions, and
garlic are excellent substitute flavorings, although some patients prefer salt substitutes.
Most salt substitutes contain potassium and must therefore be used cautiously by
patients taking potassium-sparing diuretics (e.g., spironolactone, triamterene,
amiloride). They should not be used in conditions associated with potassium retention,
such as advanced renal disease. Salt substitutes containing ammonium chloride can be
harmful to patients with liver damage.

In some communities, drinking water may contain too much sodium for a sodium-
restricted diet. Depending on its source, water may contain as little as 1 mg or more
than 1500 mg of sodium per quart. Patients may need to use distilled water if the local
water supply is very high in sodium. Bottled water can have a sodium content that
ranges from 0 to 1200 mg/L; therefore, if sodium is restricted, the label must be carefully
examined for sodium content before purchasing and drinking bottled water. Also,
patients on sodium-restricted diets should be cautioned to avoid water softeners that
add sodium to water in exchange for other ions, such as calcium. Protein intake may be
increased in patients who are malnourished or who have low serum protein levels in an
effort to increase capillary oncotic pressure and pull fluid out of the tissues into vessels
for excretion by the kidneys

Nursing Management
To assess for FVE, the nurse measures I&O at regular intervals to identify excessive
fluid retention. The patient is weighed daily, and rapid weight gain is noted. An acute
weight gain of 1 kg (2.2 lb) is equivalent to a gain of approximately 1 L of fluid. Breath
sounds are assessed at regular intervals in at-risk patients, particularly if parenteral
fluids are being given. The nurse monitors the degree of edema in the most dependent
parts of the body, such as the feet and ankles in ambulatory patients and the sacral
region in patients confined to bed. Pitting edema is assessed by pressing a finger into
the affected part, creating a pit or indentation that is evaluated on a scale of 1+
(minimal) to 4+ (severe) (see Chapter 29, Fig. 29-2). Peripheral edema is monitored by
measuring the circumference of the extremity with a tape marked in millimeters (Weber
& Kelley, 2014).

Medical Surgical Nursing Fluids & Electrolytes