1.0. Fluids and electrolytes imbalances1.pptx

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Fluids and electrolytes
imbalances
NRSG 224
 Fluid and electrolyte
Balance
Fluid is found in the Intracellular (ICF)and
extracellular (ECF)compartments of the
body
ECF is composed of;
– Interstitial (water that surrounds the
body cells and includes lymph
– Intravascular-In the blood vessels
(plasma)
– Transcellular-fluids in specific
compartments of the body such as; CSF,
digestive juices and synovial fluid in the
 Control of Fluid Balance
Primary control is through pressure
sensors or vascular system which;
– Stimulate or inhibit the release of ADH
(Pituitary gland)
When Fluid in vascular system is
decreased more ADH is released and
water is retained
If pressure is increased, less ADH is
released and kidneys eliminate more
water
Movement of Fluids and Electrolytes in
the body
Movement of fluid and electrolytes in
the body is by;
– Active and passive transport systems
Active Transport: Depends on
Adenosine Triphosphate (ATP) for
energy e.g sodium-potassium pump
Passive transport: Diffusion, filtration
and osmosis
 Definition of Terms
Filtration is movement of both H20 and
smaller molecules through a semi-permeable
membrane.
– Promoted by hydrostatic pressure difference
between areas e.g. capillaries
Osmosis: lower substance concentration to
higher concentration.
The substance exert osmotic pressure
The term osmolarity refers to concentration of
substances in the body fluid
Normal osmolarity of blood is between270-300
milliosmoles per litre (mOsm/L)
 Osmolarity is tonicity.
Tonicity is the relative concentration of solutes dissolved in
solution which determine the direction and extent of
diffusion
Fluids or solutions can be classified as isotonic, hypotonic,
or hypertonic.
A fluid that has the same osmolarity as the blood is called
isotonic.
For example, a 0.9% saline solution (normal saline) is
isotonic to the blood and is often used as a solution for
intravenous (IV) therapy.
A solution that has a lower osmolarity than blood is called
hypotonic.
 When a hypotonic solution is given to a
patient, the water leaves the blood and
other ECF areas and enters the cells.
Hypertonic solutions exert greater osmotic
pressure than blood.
When a hypertonic solution is given to a
patient, water leaves the cells and enters
the bloodstream and other ECF spaces.
 Note:
In a healthy adult, nearly all fluid is
contained in the intracellular,
intravascular, or interstitial spaces, with
the intracellular space holding about two-
thirds of total body water
 Fluid-balance Assessment.
To get a complete picture, any assessment
must be broad yet thorough and be
founded on a good clinical knowledge base
Nurses must be responsive to Patients
anxieties as some may have conditions
they feel shy to share e.g. incontinence in
an older man
Interpersonal skills are vital because a
history is one of the main elements of a
fluid-balance assessment.
 Fluid-balance Assessment
Older patients with a fluid imbalance
present additional challenges when it
comes to assessment. The physiological
changes associated with ageing, such as
– decreases in their glomerular filtration rate,
ability to concentrate urine, thirst sensation
– and aldosterone secretion, affect older
patients’ ability to withstand changes in fluid
balance.
 In addition, two important assessment
tools are invalid in many older
patients.
– The first is skin turgor, which is not
reliable when the patient’s skin has lost
its elasticity.
– The second is the assessment of mucous
membranes in older people, which may
be dry as a result of decreased salivation
rather than a fluid deficit.
 History-taking is a key part of any fluid-balance assessment.
A range of factors could precipitate either fluid loss or fluid gain.
During the history-taking, any of the following conditions should
be noted and explored:
Fluid loss as a result of inadequate intake - this may be caused
by nausea, gastrointestinal complaints, social circumstances,
confusion or conditions such as arthritis or a cerebrovascular
accident, which can make it physically difficult to eat or take
fluids.
Older people may also restrict their fluid intake in an attempt to
alleviate continence problems or because mobility problems make
it difficult for them to get to a toilet;

- Excessive fluid loss as a result of vomiting, diarrhoea, increased
insensible losses or the excessive use of laxatives or diuretics;
 Fluid gain associated with renal, cardiac or hepatic insufficiency
or excess sodium in the diet or in medications.

Visual assessment

During conversation, is the patient constantly trying to moisten his
or her lips? This may be a sign of dry mucous membranes caused
by fluid deficit.

Nurses should also assess the patient’s skin turgor, as a loss of
elasticity may indicate a fluid deficit, but remember that this may
not be a reliable method of assessment for older patients.

In the absence of any other causative factors, such as low plasma-
albumin levels, peripheral oedema may indicate fluid overload.
 Clinical signs
Postural hypotension may become evident when the
patient moves from a lying to a standing position.
To be significant and to suggest fluid depletion, a drop
of at least 15mmHg will be noted in the systolic
pressure, with a drop of 10mmHg in the diastolic
pressure.

Serial bodyweights are an accurate method of
monitoring fluid status.
Nurses must ensure that patients use the same scales,
wear the same amount of clothing and weigh
themselves at the same time every day.
 Extracellular Fluid Volume Imbalances

ECF volume deficit (hypovolemia) and ECF volume
excess (hypervolemia) are common clinical conditions.

ECF volume imbalances are typically accompanied by
one or more electrolyte imbalances, particularly
changes in the serum sodium level.

Fluid Volume Deficit (FVD)

Fluid volume deficit can occur with abnormal loss of
body fluids (e.g., diarrhoea, fistula drainage,
haemorrhage, polyuria), inadequate intake, or a shift
of fluid from plasma into interstitial fluid.
 The term fluid volume deficit is not
interchangeable with the term
dehydration.
Dehydration refers to loss of pure water
alone without a corresponding loss of
sodium.
 ECF Volume Deficit

Causes
– Insensible water loss or perspiration (high fever, heatstroke)

– Diabetes insipidus (DI) ( there is either decreased production of ADH (central DI),
or normal ADH secretion with resistance in the kidneys to its effects
(nephrogenic DI).)

– Osmotic diuresis

– Haemorrhage

– GI losses: vomiting, NG suction, diarrhoea, fistula drainage

– Overuse of diuretics

– Inadequate fluid intake

– Third-space fluid shifts: burns, intestinal obstruction
 Clinical Manifestations
– Restlessness, drowsiness, lethargy, confusion

– Thirst, dry mucous membranes

– Decreased skin turgor, ↓ capillary refill

– Postural hypotension, weak rapid pulse,

– ↓ CVP- central venous pressure is a measure of pressure in the vena cava, can be used as an estimation of
preload and right atrial pressure ( an important assessment of haemodynamic status in ICU)

– ↓ Urine output, concentrated urine

– ↑ Respiratory rate

– Weakness, dizziness

– Weight loss

– Seizures, coma
 ECF Volume Excess

Fluid volume excess may result from excessive intake of fluids,
abnormal retention of fluids (e.g., heart failure, renal failure), or a
shift of fluid from interstitial fluid into plasma fluid.

Although fluid shifts between the interstitial space and plasma do not
alter the overall volume of ECF, these shifts result in changes in the
intravascular volume

Note: osmolarity refers to the number of particles of solute per liter of solution,
whereas the term osmolality refers to the number of particles of solute per
kilogram of solvent.
Causes
Excessive isotonic or hypotonic IV fluids

Heart failure

Renal failure

Primary polydipsia

SIADH (syndrome of inappropriate antidiuretic hormone.)

Cushing syndrome (S&S due to exposure to glucocorticoids as cortisol)

Long-term use of corticosteroids
 Clinical Manifestations
Headache, confusion, lethargy

Peripheral edema

Jugular venous distention

Bounding pulse, ↑ BP, ↑ CVP

Polyuria (with normal renal function)

Dyspnea, crackles, pulmonary edema

Muscle spasms

 Collaborative Management

The goal of treatment for fluid volume excess is
removing fluid without producing abnormal changes in
the electrolyte composition or osmolality of ECF.

The primary cause must be identified and treated.
Diuretics and fluid restriction are the primary forms of
therapy.

Restriction of sodium intake may also be indicated.

If the fluid excess leads to ascites or pleural effusion,
an abdominal paracentesis or thoracentesis may be
necessary.
 Collaborative Management
Laboratory evaluation include:
– Blood urea nitrogen (BUN) level and its
relationship with serum creatinine
– FVD patient-BUN will be elevated out of
proportion to the serum creatinine level (10:1),
haematocrit level is greater then normal as red
cell become suspended in a decreased plasma
volume
– Urine concentration is evaluated by Specific
gravity (SG) in FVD it will be above 1.20
(indicating healthy renal conservation of fluid)
– Replacement of vital electrolytes and essential
minerals that enable the body to function
properly
 Nursing Management Extracellular Fluid Volume
Imbalances

Nursing Diagnoses
Nursing diagnoses and collaborative
problems for the patient with fluid
imbalances include, but are not limited to,
the following:
ECF volume deficit:
Deficient fluid volume related to excessive
ECF losses or decreased fluid intake
Potential complication: hypovolemic shock
Nursing Management Extracellular
Fluid Volume Imbalances
ECF volume excess:

– Excess fluid volume related to increased water and/or sodium retention

– Impaired gas exchange related to water retention leading to pulmonary
edema

– Risk for impaired skin integrity related to edema

– Activity intolerance related to increased water retention, fatigue, and
weakness

– Disturbed body image related to altered body appearance secondary to
edema

– Potential complications: pulmonary edema, ascites
 Nursing Implementation

Intake and Output.
Use 24-hour intake and output records to give
valuable information regarding fluid and
electrolyte problems.
Accurately record intake-and-output flow sheet
to identify sources of excessive intake or fluid
losses.
Intake should include oral, IV, and tube feedings
and retained irrigants.
Output includes urine, excess perspiration,
wound or tube drainage, vomitus, and
diarrhoea.
 Estimate fluid loss from wounds and
perspiration.
Measure the urine specific gravity
according to agency policy.
Readings of greater than 1.025 indicate
concentrated urine, whereas those of less
than 1.010 indicate dilute urine.
Cardiovascular Changes.
Monitor patient for
– cardiovascular changes to prevent or
detect complications from fluid and
electrolyte imbalances.
– Signs and symptoms of ECF volume excess
and deficit are reflected in changes in blood
pressure, pulse force, and jugular venous
distention.
– In fluid volume excess the pulse is full,
bounding, and not easily obliterated.
– Increased volume causes distended neck
veins (jugular venous distention) and
increased blood pressure
– In mild to moderate fluid volume deficit,
compensatory mechanisms include
sympathetic nervous system stimulation of
the heart and peripheral vasoconstriction.
– Stimulation of the heart increases the heart
rate and, combined with vasoconstriction,
maintains the blood pressure within normal
limits.
– A change in position from lying to sitting or
standing may elicit a further increase in the
heart rate or a decrease in the blood pressure
(orthostatic hypotension).
– If vasoconstriction and tachycardia provide
inadequate compensation, hypotension
occurs when the patient is recumbent.
– Severe fluid volume deficit can cause flattened
neck veins and a weak, thready pulse that is
easily obliterated.
– Severe, untreated fluid deficit will result in shock.

Respiratory Changes.
– Both fluid excess and fluid deficit affect
respiratory status.
– ECF excess can result in pulmonary congestion
and pulmonary edema as increased hydrostatic
pressure in the pulmonary vessels forces fluid
into the alveoli
– The patient will experience shortness of breath and moist
crackles on auscultation.
– The patient with ECF deficit will demonstrate an increased
respiratory rate because of decreased tissue perfusion and
resultant hypoxia.

Neurologic Changes.

– Changes in neurologic function may occur with fluid volume
excesses or deficits.
– ECF excess may result in cerebral edema from increased
hydrostatic pressure in cerebral vessels.
– Alternatively, profound volume depletion may cause an
alteration in sensorium secondary to reduced cerebral tissue
perfusion.
Assessment of neurologic function includes
evaluation of
– level of consciousness, which includes responses
to verbal and painful stimuli and determination of
a person’s orientation to time, place, and person;
– pupillary response to light and equality of pupil
size; and
– voluntary movement of the extremities, degree of
muscle strength, and reflexes.
– Nursing care focuses on maintaining patient
safety.
 Daily Weights.
– Accurate daily weights provide the easiest measurement
of volume status.
– An increase of 1 kg (2.2 lb) is equal to 1000 mL (1 L) of
fluid retention (provided the person has maintained
usual dietary intake or has not been on nothing-by-
mouth [NPO] status).
– Obtain the weight under standardized conditions, that is,
weigh the patient at the same time every day, wearing
the same garments, and on the same carefully
calibrated scale.
– Remove excess bedding and empty all drainage bags
before the weighing.
– Remove excess bedding and empty all
drainage bags before the weighing.
– If the patient has items present that are
not there every day, such as bulky
dressings or tubes, note this along with
the weight.
Skin Assessment and Care.
– Detect clues to ECF volume deficit and
excess by inspecting the skin.
– Examine the skin for turgor and mobility.
Normally a fold of skin, when pinched, will
readily move and, on release, rapidly
return to its former position.
– Skin areas over the sternum, abdomen,
and anterior forearm are the usual sites
for evaluation of tissue turgor
– In older people, decreased skin turgor is less
predictive of fluid deficit because of the loss of
tissue elasticity.
– In ECF volume deficit, skin turgor is diminished,
and there is a lag in the pinched skinfold’s
return to its original state (referred to as
tenting).
– The skin may be cool and moist if there is
vasoconstriction to compensate for the
decreased fluid volume.
– Mild hypovolemia usually does not stimulate
this compensatory response
 Consequently, the skin will be warm and dry.
Volume deficit may also cause the skin to appear dry
and wrinkled.
These signs may be difficult to evaluate in the older
adult because the patient’s skin may be normally dry,
wrinkled, and non-elastic.
Oral mucous membranes will be dry, the tongue may
be furrowed, and the individual often complains of
thirst.
Routine oral care is critical for the comfort of a patient
who is dehydrated or fluid restricted for management
of fluid volume excess.
– Edematous skin may feel cool because of fluid
accumulation and a decrease in blood flow
secondary to the pressure of the fluid.
– The fluid can also stretch the skin, causing it to
feel taut and hard.
– Assess edema by pressing with a thumb or
forefinger over the edematous area.
– A grading scale is used to standardize the
description if an indentation (ranging from 1+
[slight edema; 2-mm indentation] to 4+ [pitting
edema; 8-mm indentation]) remains when
pressure is released.
– Evaluate for edema in areas where soft
tissues overlie a bone, with preferred sites
being the tibia, fibula, and sacrum
– Good skin care for the person with ECF
volume excess or deficit is important.
– Protect edematous tissues from extremes
of heat and cold, prolonged pressure, and
trauma.
– Frequent skin care and changes in position
will prevent skin breakdown.
– Elevate edematous extremities to
promote venous return and fluid
reabsorption.
– Dehydrated skin needs frequent care
without the use of soap.
– Applying moisturizing creams or oils
increases moisture retention and
stimulates circulation.
 Other Nursing Measures

– Carefully monitor the rates of infusion of IV
fluid solutions.
– Be cautious about any attempts to “catch
up,” particularly when large volumes of fluid
or certain electrolytes are involved.
– This is especially true in patients with
cardiac, renal, or neurologic problems.
– Patients receiving tube feedings need
supplementary water added to their enteral
formula.
– The amount of additional water depends on the
osmolarity of the feeding and the patient’s
condition.
– Do not allow the patient with nasogastric
suction to drink water because it will increase
the loss of electrolytes.
– Occasionally the patient may be given small
amounts of ice chips to suck.
– Irrigate nasogastric tubes with isotonic saline
solution, not with water
 Water causes diffusion of electrolytes
into the gastric lumen from mucosal
cells. The suction then removes the
electrolytes, increasing the risk of
electrolyte imbalances.
 Electrolyte Imbalances
Sodium Imbalances

Sodium, the main cation of ECF, plays a
major role in maintaining the concentration
and volume of ECF and influencing water
distribution between ECF and ICF.
Sodium plays an important role in the
generation and transmission of nerve
impulses, muscle contractility, and the
regulation of acid-base balance.
 Because sodium is the primary
determinant of ECF osmolality,
Sodium imbalances are typically
associated with parallel changes in
osmolality.
Serum sodium is measured in
milliequivalents per liter (mEq/L) or
millimoles per liter (mmol/L).
 The serum sodium level reflects the ratio
of sodium to water, not necessarily the
loss or gain of sodium.
Changes in the serum sodium level may
reflect a primary water imbalance, a
primary sodium imbalance, or a
combination of the two.
Sodium imbalances are typically
associated with imbalances in ECF volume
 The GI tract absorbs sodium from foods. Typically, daily intake
of sodium far exceeds the body’s daily requirements.

Sodium leaves the body through urine, sweat, and feces.

The kidneys are the primary regulator of sodium balance.

The kidneys regulate the ECF concentration of sodium by
excreting or retaining water under the influence of ADH.

Aldosterone also plays a role in sodium regulation by
promoting sodium reabsorption from the renal tubules.
 Hypernatremia

Hypernatremia, an elevated serum sodium, may occur
with water loss or sodium gain.

Because sodium is the major determinant of the ECF
osmolality, hypernatremia causes hyperosmolality.

In turn, ECF hyperosmolality causes a shift of water out
of the cells, which leads to cellular dehydration.

The primary protection against the development of
hyperosmolality is thirst..
 Normal level of sodium in blood is 135-
145mmol/L or mEq /L.

Hypernatremia refers to sodium level or
concentration ˃145mEq/L in blood.
Hypernatremia is not a problem in an alert
person who has access to water, can
sense thirst, and is able to swallow.
 Hypernatremia secondary to water deficiency is often
the result of an impaired level of consciousness or an
inability to obtain fluids

Several clinical states can produce hypernatremia
from water loss
A deficiency in the synthesis or release of ADH from
the posterior pituitary gland (central diabetes
insipidus) or
a decrease in kidney responsiveness to ADH
(nephrogenic diabetes insipidus) can result in
profound diuresis, thus producing a water deficit and
hypernatremia.
 several causes for hypernatremia
disease;
Inadequate water Nasogastric tube
intake feed
Diabetes insipidus Use of hypertonic
Burns saline
Excessive sweating, Intravenous
Severe watery sodium
bicarbonate
diarrhoea, Hypertonic dialysis
Vomiting
Hyper
Excessive use of
Aldosteronism.
laxative,
 Sign and symptoms for
hypernatremia
Weakness
Confusion
Irritability
Oedema
Dry mouth (Dry oral mucosa)
Tachycardia
Low Skin turgor,
Oliguria.
In severe elevation of sodium seizures and
coma
 Diagnosis and Treatment for Hypernatremia Disease:

Diagnosis;
Sodium / Electrolytes,
Urine Osmolality / Serum Osmolality

Note: An osmole is the number of moles in a
compound that contributes to the osmotic
pressure. The main difference between osmolarity
and osmolality is that osmolarity is a measure
considering the volume of a solution whereas
osmolality is measured considering the mass of a
solution
Treatment for Hypernatremia Disease:

Stop underlying cause such as –
vomiting, diarrheal, sweating.
Stop use of laxatives.
Withhold diuretics.
Correction of hyperglycaemia. (ask class why)
Use isotonic fluid (0.9% saline) to restore
circulating volume in Hypovolemic shock.
Correction of the water loss requires an
assessment of the current water deficit and
ongoing rate of water losses.
 Hyponatremia
Generally defined when the sodium in blood
falls below 135mEq/L.
Severe Hyponatremia considered when the
serum sodium level is less than 125mEq/L.
Hyponatremia is frequently related to
hypovolemia or fluid overload.
Sharp nursing assessment skills and proper
care can prove invaluable in the treatment
of patient and prevention of complication
 Signs and symptoms

Clinical picture can be confusing, because mild
hyponatraemia can cause significant symptoms
if the drop in sodium level is sudden, whereas
severe chronic hyponatraemia can cause no
symptoms, due to cerebral adaption.
However, the following symptoms may
occur:
Mild - anorexia, headache, nausea, vomiting,
lethargy.
Moderate - personality change, muscle cramps
and weakness, confusion, ataxia.
Severe - drowsiness.
 Signs
These are again highly variable and depend on the
level and rate of fall of the serum sodium. They may
include:
Neurological signs:
– Decreased level of consciousness.
– Cognitive impairment (eg, short-term memory loss,
disorientation, confusion, depression).
– Focal or generalised seizures.
– Brainstem herniation - seen in severe acute
hyponatraemia; signs include coma; fixed, unilateral,
dilated pupil; respiratory arrest.
 Signs of hypovolaemia –
– dry mucous membranes,
– tachycardia,
– diminished skin turgor.
Signs of hypervolemia –
– pulmonary rales
– jugular venous distention
– peripheral oedema
– ascites.
 Nursing Intervention for
Hyponatremia Patient:
Strictly maintain fluid intake and output of
patient hourly.
Check weight everyday to monitor the
fluid volume status.
Monitor and observe skin turgor to identify
dehydration and accurately record state of
hydration.
Monitor vital signs carefully and note
respiratory rate and depth to identify
pulmonary oedema.
 Check and monitor the hyponatremia patient for
signs of oedema and hypertension.
Monitor for signs of circulatory overload, as
indicated
Ensure high sodium containing food such as milk,
meat, eggs, carrots, beets and celery.
Ensure adequate dietary sodium intake of 90 to
250 mEq Day.
Monitor and observe for neuromuscular changes
such as declining levels of consciousness, fatigue
and muscular weakness.
 Give supplemental oxygen to lethargy or
unconscious patient as needed.
Patient with sodium imbalances often are
confused and act as crazy.
Ensure safety measure;
– Maintain quiet environment.
– Keep bed in low locked position.
– Keep side rails up to prevent fall.
– Keep nurse call within reach and instruct
patient to call nurse for any assistance.
 Carefully monitor hyponatremia patient for
any sign of convulsion and notify to
physician.
Take seizure precautions as order.
Monitor laboratory serum sodium levels as
ordered to determine the effectiveness of IV
fluids.
Administer prescribed medication as order.
Carefully administer the 3% or 5% sodium
containing fluid by using infusion pump as
prescribed.
 Monitor IV site for patency, signs of infiltration
such as redness or irritation.
Identify the specific cause of hyponatremia such
as sodium loss or fluid excess.
Give mouth care frequently as dry mouth and
saliva production decreased.
Irrigate nasogastric tube with normal saline
instead of plain water.
Prepare patient for dialysis as indicated.
Address acute life threatening conditions and
initiate supportive care