Fluid and Electrolytes PDF

Summary

This document provides notes on fluid and electrolyte balance in the body. It covers the different compartments of bodily fluids, the functions of electrolytes, and the mechanisms that regulate these processes. Topics like osmosis, diffusion, and active transport are included in the context of fluid balance.

Full Transcript

FLUID AND ELETROLYTES

PROF O.A AKPOR
 OBJECTIVES
At the end of this unit, you should be able to:
Identify body fluid compartment
Describe the mechanism regulatory fluid and
electrolyte balance
Identify the factors affecting fluid and electrolyte
balances
Explain route by which water and Electrolyte
leave and enter the body
Describe the types of electrolytes in the body
Distinguish between electrolyte balance and
imbalance
 INTRODUCTION
All bodily functions rely on the proper
distribution of fluids and electrolytes between
the intracellular and extracellular compartments
Fluid and electrolyte balance is maintained by the
interaction of renal, hormonal, and metabolic
mechanisms
Imbalances can occur secondary to other
disorders or as complications of therapy
The major objective of fluid and electrolyte
distribution is the replacement for prior deficits
and continuing losses, and nutrition
 FLUIDS
The fluids system plays an important role in the
body. The principal functions of body fluids are:
1. Maintains of blood volume
2. Aids digestion
3. Transports material to and from body cells
4. Acts as a medium for cellular metabolism
5. Excretes of waste
6. Regulation body temperature
 FLUIDS
Water is the largest single constituent of the
human body and forms about 50-70% of the total
body weight (TBW) of the average young to
middle age adult and 75-80% of total body
weight of an infant

By the age of two, the percentage of total body
weight that is fluid is the same as that of a young
to middle aged adult (60%).
The total body fluid drops about 45-60% in the
elderly because of changes on the body tissue.
 BODY FLUID COMPARTMENTS
In the adult, 60% of body weight consists of
water, of which 45% is intracellular fluid (ICF).
The remaining 15% is distributed between the
intravascular and interstitial compartments
and is considered extracellular fluid (ECF)

Body fluids are found in two major
compartments of the body. These are
a. Intracellular fluid
b. Extracellular fluid
 THE INTRACELLULAR FLUID
It is found within the cells of the body
It accounts for approximately 40-50% of the
total body weight

The main electrolyte is potassium (K) and this
provides the cells with aqueous medium for
its chemical functions
 THE EXTRACELLULAR FLUID
This is found outside the cells
The main electrolyte is sodium (Na)
The extracellular fluid is made up of two
compartments:

a. Interstitial Fluid
This is found in the spaces between the cells and
accounts for approximately 15% of total body
weight of an adult
b. Intravascular Fluid
This is found in the blood and lymph vessels and
makes up about 5% of the total body weight
 DISTRIBUTION AND CONCENTRATION
OF ELECTROLYTES IN BODY FLUID

Distribution and concentration of electrolytes
in the body fluids are regulated by:
Osmosis
Diffusion
Active transport
Filtration
Pinocytosis (absorption of liquids by cells with
phagocytic properties such as the
macrophage)
 OSMOSIS
Is the process by which water passes through
a semi-permeable membrane from a lower
concentrations of solution to higher
concentrations

This continues until equilibrium is achieved
on both sides of the membrane.
Simply stated, in osmosis, water passes from a
more dilute solution to a more concentrated
one, water goes where the electrolytes go
 OSMOSIS

If blood cells are suspended in an isotonic
solution (a solution having the same osmotic
pressure as the cells), the osmotic pressure
will remain the same inside and outside the
cell. In this case, no movement occurs.
 OSMOSIS AND DIFFUSION
If the blood cells are placed in a hypotonic
solution (much less concentrated than the
cellular contents), water will flow into the cells
until they swell and burst. In a hypertonic
solution (more concentrated than the cellular
contents), water flows out of the cells and they
shrink

DIFFUSION:
Diffusion is a process whereby molecules move
from higher concentrations of solution to lower
concentrations
Oxygen and carbon dioxide exchange in the lungs
occurs through diffusion
 ACTIVE TRANSPORT
Active transport is a mechanism, still not fully
understood, whereby ions move from areas of
lesser concentration to areas of greater
concentration
It involves the release of energy by the action of
adenosine triphosphate (ATP), which supplies
the necessary “uphill movement,” enabling
certain substances to pass through the cell
membrane
Sodium, potassium, and amino acids are
probably carried through all cell membranes by
active transport
 FILTRATION
Filtration is related to hydrostatic pressure
produced by the pumping action of the heart.
(Hydrostatic pressure is the pressure of water or
other liquids)

It involves the transfer of both solute and solvent
through a permeable membrane from a region of
higher hydrostatic pressure to a region of lower
pressure
An example is the passage of water and
electrolytes from the capillary beds to the
interstitial fluid
PINOCYTOSIS AND PHAGOCYTOSIS
Pinocytosis is the process by which substances
of higher molecular weight, such as protein,
enter the body
In this process, the cell membrane folds
inward to incorporate the substances

In phagocytosis, foreign particles are
engulfed or digested by specialized cells
called phagocytes
COMMON SOURCES OF FLUID AND
ELECTROLYTE IMBALANCE
1. Vomiting and Gastric Suction:
When the quantity of acidic gastric juices is
reduced through vomiting or by gastric
suction, a number of vital electrolytes is lost.
These usually include hydrogen, chloride,
potassium, and sodium.
The total amount of fluid in the body is
decreased, and the client may develop
metabolic alkalosis from the resulting excess
of base bicarbonate
1. Vomiting and Gastric Suction contd

The symptoms of metabolic alkalosis include:
Slow, shallow respiration
Muscle hypertonicity and tetany, and
Personality changes.
The client may become disoriented, irritable,
or uncooperative
 2. DIARRHOEA, AND OTHER SOURCES
OF GASTROINTESTINAL FLUID LOSS
In a 24-hour period, 17,000 ml of fluid can be
lost through diarrhoea
With intestinal suction, 3,000 ml of fluid per
day can be lost

Prolonged use of laxatives and enemas can
result in serious water and electrolyte
disturbances
2. DIARRHOEA, AND OTHER SOURCES
OF GASTROINTESTINAL FLUID LOSS

Gastrointestinal fluids can also be lost through
fistulas or drainage tubes

Gastrointestinal obstruction also produces
fluid loss because the fluids are trapped within
the intestine and cannot be used by the body.
 OTHER SOURCES OF GASTROINTESTINAL
FLUID LOSS
In addition to fluid volume loss, gastrointestinal
disturbances can result in metabolic acidosis
(because the intestinal secretions are primarily
alkaline). Symptoms of metabolic acidosis include
shortness of breath, deep, rapid breathing,
weakness, malaise, and stupor progressing to
coma

3. Wound Exudates:
This can result in losses of protein and sodium
and a deficit in the extracellular fluid volume
 4. EXCESSIVE PERSPIRATION

This can lead to abnormal losses of water,
sodium, and chloride
If fluid intake of both water and electrolytes is
not continued, the fluid volume and
proportion of electrolytes decrease

The client with this condition may even
develop sodium excess if insufficient water is
ingested during a period of heavy perspiration
 5. INSENSIBLE
Water loss occurs through the lungs and skin
It totals approximately 600 to 1,000 ml per
day in the average adult
If respiratory activity is increased, more water
vapour is lost, and if there is damage to the
skin, still more loss occurs
Because only water, and not electrolytes, is
lost through the skin, water deficit and
sodium excess will develop
 6. HYPERVENTILATION
Results in respiratory alkalosis due to
excessive elimination of carbon dioxide

7. HYPOVENTILATION:
Is more dangerous than hyperventilation,
causes retention of excessive amounts of
carbon dioxide
This condition results in respiration acidosis
 ELECTROLYTES
Electrolytes are chemicals that when
dissolved, dissociate into positively and
negatively charged ions (cations and anions).
Total cation always equals total anions.

They are important constituents of
intracellular and extracellular fluids, serving
vital functions in maintaining fluid and acid –
base balance, neuromuscular excitability,
blood clotting, and protein and cellular
metabolism
 ELECTROLYTES
The composition and concentration of
electrolytes in each fluid compartment vary

Measurement of electrolytes is usually
expressed in mill equivalents per liter
(mEq/L).
 ELECTROLYTES
The electrolytes in the body fluid are involved in
chemical reaction such as:

i. Regulating the permeability of cell membranes
thus, controlling the transfer of various
materials across the membrane
ii. Maintenance of the body acid-base balance
iii. Promotion of neuro-muscular irritability by
transmission of electrical energy within the
body e.g. without calcium muscle contraction
cannot occur
iv. Maintenance of fluids osmolarity (the osmotic
pull of all particles per kg of H2O)
MECHANISMS REGULATING FLUID AND
ELECTROLYTE BALANCE

Proteins and electrolytes are the main forces
holding H2O within the various compartments
of the fluid system in the body

In the intravascular compartments the force is
by the serum albumin, whereas in the
interstitial fluid is by Sodium (Na+) ions and in
the intracellular by potassium
 MECHANISMS REGULATING FLUID
AND ELECTROLYTE BALANCE
These substances exact an osmotic pressure
which holds the H2O in their respective
compartments

For example a patient who has lost a great
deal of serum albumin through malnutrition
tends to become oedematous, since fluid is
drawn from the blood plasma into the
intracellular space because the main force
holding the H2O in the blood vessels has been
lost
 MECHANISMS REGULATING FLUID
AND ELECTROLYTE BALANCE

1. Kidneys
2. Gastro-intestinal tract
3. Thirst
4. Lungs
5. Skin
6. Hormonal control
 1. KIDNEYS
This is the most important regulatory mechanism
This function is regulated by the action of two
hormones – Anti Diuretic Hormone (ADH) which
controls H2O reabsorption and Aldesterone which
promotes the retention of Sodium (N+) and the
excretion of Potasium (K+)

Under the influence of these hormones the
kidney assists in regulating:
a. Total value of extracellular fluid
b. Electrolyte concentrate
c. Acid-base balance
d. Blood pressure
 2. GASTRO-INTESTINAL TRACT
This is done through the selective reabsorption
of water and solutes which occur principally in
the small intestine
The gastrointestinal tract absorbs about 7-9 litres
of glandular and gastrointestinal secretions per
day

About 100mls of H2O are excreted from the
bowel daily, the rest are reabsorbed
Both fluids and electrolytes may be lost in
considerable quantities in conditions as vomiting
and diarrhoea
 3. THIRST
This is stimulated by a decrease in
extracellular fluid volume
Thirst indicates a basic physiological need for
H2O
The thirst mechanism is stimulated by:
a. Increase osmotic pressure
b. Decrease ECF
c. Dry mucous membrane in the mouth
 4. LUNGS
H2O is lost during expiration and inspiration,
although amount of H2O lost is small
Whenever respiration increases in rate and
depth, the amount of lost H2O via this route
increased
This is seen in strenuous muscular exercise,
fever or any condition in which respiration is
increased or when the air that is breathed is
very dry
5. Skin:
H2O is lost through perspiration
 6. HORMONAL CONTROL
Three hormones play a particularly vital role in maintaining
fluid and electrolyte balances:
1. Antidiuretic hormone (ADH)
a. Is produced in the hypothalamus and stored and
released from the posterior pituitary gland
b. Acts on the renal tubules to retain water and to
decrease urinary output

2. Aldosterone
a. Is secreted by the adrenal cortex
b. Acts on the renal tubules to reabsorb sodium and to
excrete potassium
c. Increase circulatory volume by reabsorbing water along
with sodium.
6. HORMONAL CONTROL CONT

3. Parathormone:
a. Produced by the parathyroid glands
b. Promotes absorption of calcium from the
intestine
c. Promotes release of calcium from bone
d. Increases the excretion of phosphate ions by
the kidneys
 FACTORS AFFECTING FLUID AND
ELECTROLYTE BALANCE
1. Insufficient intake of fluid
2. Disturbance of the gastrointestinal tract such as
diarrhoea and vomiting, gastric suction and
wash out
3. Disturbances of kidney function e.g. cardio
vascular dysfunction or imbalance in antidiuretic
hormone
4. Excessive perspiration and evaporation
5. Lost of body fluid as occurs with haemorrhage,
burns and body trauma including surgical
trauma
 MECHANISM IN WHICH H2O AND ELECTROLYTE
ENTER AND LEAVES THE BODY

Water enters the body through
a. Oral liquids = 1,500ml
b. Water in fluids = 700ml
c. Water from oxidation = 200ml
Total =2,400ml
 MECHANISM IN WHICH H2O AND
ELECTROLYTE ENTER AND LEAVES
THE BODY
Water leaves the body by several routes
a. Skin diffusion 350ml
b. Skin by perspiration 100ml
c. Lungs 350ml
d. Feaces 200ml
e. Kidneys 1400ml
= 2,400ml

As long as all organs are functioning normally, the
body is able to maintain balance in its fluid
contents. i.e. the intake of fluid must balance the
output
 FLUID BALANCE
Electrolytes must be balanced within a
narrow margin to maintain homeostasis

Primary and secondary imbalances exist
While primary imbalances occur on their own,
secondary electrolyte imbalance occur as a
result of another pathophysiologic situation
 SODIUM
Is the major cation in the ECF: Regulates fluid
volume within compartments
Is the principal regulator of the osmotic
pressure of the ECF
Maintains cellular membrane potential
(transfers neuromuscular impulses)
Maintains blood volume and regulates size of
vascular bed
Normal level : 135-145mEq/L
 SODIUM DEFICIT(HYPONATREMIA)

Abnormal decrease in plasma sodium levels: <
135mEq/L. In severe cases: 145mEq/L
Serum osmolality: >295mOsm/kg rise
CLINICAL MANIFESTATIONS CONT

Firm, rubbery tissue turgor
(increase in Na draws H2O from ICF)
In severe hypernatremia; depression, fatigue
and coma
Intracranial hemorrhage
Oliguria and anuria (increase in ADH)
 HYPERNATREMIA
INTERVENTIONS AND TREATMENT

High oral intake of water to decrease
osmolality of ECF
Hypotonic IVs
Monitor weight
Intake and output
Inspect oedema: dependent edema (sacrum,
feet)
 POTASSIUM
Potassium is the main cation in ICF
Normal concentration: 3.5 to 5.0 mEq/L
Functions:
Maintains intracellular homeostasis and
determines the cells resting membrane potential
Helps promote conduction of nerve impulses
Promotes skeletal muscle impulses
Promotes heart muscle function
Catalyzes many reactions and participates in
protein synthesis and CHO metabolism
Kidney excretes 90 to 95% of all potassium
 POTASSIUM CONTD
Potassium moves into the cell when glucose is
being metabolized
Potassium moves out of the cell during
strenuous exercise, impaired cell metabolism,
cells destruction (burns, major trauma, serious
infections, chemotherapy)
When potassium is lost, sodium and
hydrogen ions shift into the cell to maintain
cellular tonicity and cells become more acidic.
POTASSIUM DEFICIT ( HYPOKALEMIA)
Serum potassium 5.3 mEq/L
Hyperparathyroidism(due to excessive parathormone
secretion
Widespread bone metastasis with calcium resorption
Prolonged immobilization: (decreased bone
formation and bone resorption)
Hypervitaminosis D (increased bone resorption of vit D)
Multiple myeloma (bone destruction liberates Ca), CA
breast, leukemia, lymphoma
Kidney stones: when the rate of demineralization exceeds
kidneys excretion of excess calcium. Kidney stones forms
 HYPERCALCEAMIA: CLINICAL
OBSERVATION
Decreased neuromuscular excitability with
reduced muscle tone
Fatigue
Nausea, vomiting anorexia and weight loss
Deep bone pain elated to pathological
fractures
Flank pain (calcium renal stones)
Prolonged Q-T interval on ECG
 HYPERCALCEAMIA: TREATMENT
Promote urinary excretion of calcium: diuretics
(Lasix)

– Hydration with sufficient fluids (3000 to
4000ml/day) while restricting calcium
Synthetic Calcitonin
Calcium-free diet
Mobilization of an immobilized person
Pamidronate (Aredia ) to inhibit osteoclasts for
malignancy