Water and electrolyte balance
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Transcript of Water and electrolyte balance
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Water and Electrolyte Balance
R. C. GuptaM.D. (Biochemistry)
Jaipur (Rajasthan), India
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Water is the most abundant component ofour body
Need for water is more urgent than that forany other nutrient
Humans beings can live one month without food but only six days without water
EMB-RCG
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EMB-RCG
In adults, water accounts for:
70% of the total body weight in males
60% of the total body weight in females
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EMB-RCG
Water content depends on age:
Infants: 75%
Adults: 60-70%
Elderly: 45%
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EMB-RCG
Water content differs in different tissues:
Muscles: 70%
Adipose tissue: 30%
Bones: 10%
Water content is more in muscular
persons than in obese persons
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Water:
Bathes all cells
Gives shape and form to cells
Serves as a lubricant
Is the solvent for all ions and molecules
Transports materials to and from cells
Is the medium for all biochemical reactions
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Latent heat of evaporation
Specific heat
Dielectric constant
Solvent power
Some properties of water which make it
an ideal medium for body fluids are its:
Water has been chosen as the universal
solvent for all living organisms
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Solvent power
Water is an efficient and suitable solvent for most of the solutes present in our
body
Some compounds which do not dissolve readily in water can form colloidal
solutions
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Water has a high dielectric constant
A large number of oppositely charged particles can co-exist in water due to this
Dielectric constant
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Specific heat
Water has a very high specific heat which means that a large amount of heat is
required to raise the temperature of water
Due to this, body temperature doesn’t rise appreciably when thermal energy is
released during oxidation of nutrients
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Latent heat of evaporation
Water has a high latent heat of evaporation relative to other liquids
A large amount of thermal energy is required for evaporation of water
When water evaporates from skin and lungs, a large amount of heat is lost
This prevents a rise in body temperature
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Distribution of water
Compartment Water
Total water in an
average man 50 litres
Water in intra-cellular
compartment 35 litres
Water in extra-cellular
compartment 15 litres
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Un-exchangeable fluid
The water present outside the cells is
known as extra-cellular fluid (ECF)
The ECF is further distributed into some
sub-compartments:
Trans-cellular fluid
Interstitial fluid
Plasma
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Sub-compartment Volume
3 litresPlasma (vascular compartment)
Interstitial fluid (in between cells) 7 litres
Trans-cellular fluid (in cavities) 1 litre
4 litres
Un-exchangeable fluid (in bones,
cartilages, dense connective tissue etc)
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Osmolality
Concentration of solutes/particles in fluid, expressed in milliosmol (mosm) per kg
Determines distribution of water in different compartments
Water moves from lower to higher osmolality
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The major osmotically active solutes in
body fluids are:
Electrolytes have more osmotic power asthey dissociate into at least two particles
Non-electrolytes e.g. glucose, lipids etc
Electrolytes e.g. inorganic salts and proteins
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Intracellular Interstitial Plasma
fluid fluid
CATIONS (mEq/L)
Sodium 10 137 142
Potassium 160 5 5
Magnesium 24 3 3
Calcium 6 5 5
Total 200 150 155
ANIONS (mEq/L)
Chloride 5 113 100
Bicarbonate 5 27 27
Sulphate 15 1 1
Inorganic phosphate 25 2 2
Organic phosphates 70 – –
Organic anions 15 5 5
Proteins 65 2 20
Total 200 150 155
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Effective osmolality of a compartment isdetermined by the solutes restricted tothat compartment
Effective osmolality of the compartment isalso known as its tonicity
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Selective distribution of ions in differentcompartments is maintained by specificion channels and ion pumps
A lot of energy is spent for maintaining thedifferential distribution of ions in differentcompartments
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Cations
Sodium is the major cation in extracellularfluid
Potassium is the major cation in intracellularfluid
This differential is maintained by Na+, K+-exchanging ATPase
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Anions
The major anions in extracellular fluid arechloride and bicarbonate
The major anions in intracellular fluid arephosphates and proteins
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Proteins
Proteins are present in a:
Fairly high concentration in intracellular fluid
Smaller but significant concentration in plasma
Negligible concentration in interstitial fluid
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Effective osmolality is determined by:
Sodium and its associated anions in the extracellular fluid
Potassium and its associated anions in the intracellular fluid
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The ions and molecules have specificdistribution in the intracellular fluid
These are vital for the functioning of thecells, and are zealously maintained
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Changes in osmolality are usually due toshift of salts (mainly sodium)
When salts shift, water follows salts
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Shrinkage of cells due to shifting of waterout of the cells can seriously affect thefunctioning of cells
Swelling of cells due to shifting of waterinto the cells can also seriously affect thefunctioning of cells
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Hyper-osmolality of extracellular fluiddraws water out of cells into the extra-cellular compartment
Hypo-osmolality of extracellular fluiddrives water from extracellular compart-ment into the cells
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Osmolality of plasma is 275-290 mosmol/kg
A 0.9% solution of NaCl in water hasthe same osmolality (or tonicity) as plasma
A 5% solution of glucose in water also hasthe same osmolality (or tonicity) as plasma
These two are said to be isosmotic orisotonic with plasma
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Oncotic pressure
Osmotic pressure exerted by proteins iscalled oncotic pressure
It is also known as colloid osmotic pressure
The normal oncotic pressure of plasma isabout 25 mm of Hg
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A decrease in the concentration of proteins inplasma decreases oncotic pressure of plasma
Water is forced out of capillaries at the arterialend due to greater hydrostatic pressure
It cannot re-enter at the venous end if the oncoticpressure is less than the hydrostatic pressure
This will result in oedema
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Water intake and output
Water balance of the body depends uponthe relative intake and output of water
Water is taken in as drinking water and inthe form of food and beverages
Some water is formed in the body duringoxidative reactions (metabolic water)
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Metabolic water
Oxidation of 1 gm of carbohydrate produces 0.60 gm of water
Oxidation of 1 gm of fat produces 1.07 gm of water
Oxidation of 1 gm of protein produces 0.41 gm of water
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In a temperate climate, intake of water is:
Source Volume
Drinking water about 1.5 L /day
Water in food and beverages about 1.0 L /day
Metabolic water about 0.3 L /day
Total intake about 2.8 L /day
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Route Volume
Urine about 1.5 L /day
Faeces about 0.1 L /day
Water vapour in expired air about 0.4 L /day
Water loss in the form of sweat about 0.8 L /day
Total output about 2.8 L /day
Water is lost from the body in the form of:
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In hot climates, sweat loss is much more
This is compensated by increased intake ofdrinking water
If it is not compensated, urine output willdecrease
However, urine output cannot decreasebelow a certain level
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Normal excretion of solutes by the kidneysis about 600 milliosmol/day
Minimum water required to dissolve 600milliosmol solutes is 500 ml
If urine output is below 500 ml/day,excretion of metabolic waste decreases
A urine output below 500 ml/day is calledoliguria
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Regulation of water balance
Water balance is maintained by:
The thirst centre in hypothalamus
Antiduretic hormone of posterior pituitary
These two receive signals about osmolality of plasma from osmoreceptors located in
the hypothalamus
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Osmo-receptors can perceive a change of
even 1-2% in the osmolality of plasma
If there is an increase in the osmolality of plasma:
Thirst centre is stimulated which increases water
intake
Posterior pituitary secretes anti-
diuretic hormone which decreases
urine output
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ADH secretion begins when the osmolalityof plasma reaches about 285 mosmol/kg
The thirst centre is stimulated when theosmolality of plasma reaches about 295mosmol/kg
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When blood circulates through the kidneys,125 ml of glomerular filtrate is formed perminute
About 180 litres of glomerular filtrate isformed in 24 hours
Glomerular filtration rate
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When the filtrate passes through the
tubules, a large amount of solutes and
water are absorbed
The re-absorption can be divided into:
Obligatory re-absorption
Facultative re-absorption
Tubular re-absorption
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A large amount of solutes is absorbed
when the filtrate passes through proximal
convoluted tubules and loop of Henle
A corresponding amount of water is re-absorbed due to osmotic effect of solutes
This is known as obligatory re-absorption
Obligatory re-absorption
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Obligatory re-absorption equals:
About 85% of the glomerular filtrate
Or about 153 litres per day
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Cells of distal convoluted tubules andcollecting ducts are not permeable to waterin the absence of ADH
Binding of ADH to its receptors (V2
receptors) on the surface of these cellsactivates adenylate cyclase
Facultative re-absorption
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Active adenylate cyclase increases theintracellular concentration of cAMP
cAMP activates protein kinase A
Active protein kinase A phosphorylatessome cytosolic proteins
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The phosphorylated proteins translocateaquaporins from cytosol into cell membrane
Aquaporins are water channels
Water moves into the cell through thesewater channels
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Movement of water into distal convoluted
tubules and collecting ducts is proportional
to plasma ADH concentration
The ADH-regulated re-absorption is knownas facultative re-absorption of water
Normally, this is about 25.5 litres/day
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About 1.5 litres of water is not absorbed bytubules
This is excreted in the form of urine everyday
Facultative re-absorption can be adjustedto maintain the water balance of the body
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Electrolyte balance
Sodium, potassium and chloride are the major electrolytes
Their plasma levels are:
Sodium: 135 -145 mEq/L
Potassium: 3.5 - 5.0 mEq/L
Chloride: 96 -106 mEq/L
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Sodium
The most important cation in regulation of fluid and electrolyte balance
The most abundant cation in the ECF
Contibutes significant osmotic pressure
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Potassium
Critical to maintenance of membrane potential
Compensates for shifts of hydrogen ions in or out of cells
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Chloride
The most abundant anion in the ECF
Contributes significant osmotic pressure
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Regulation of sodium
Aldosterone promotes tubular re-absorption of sodium
Oesrogens have a similar but weakereffect
Atrial natriuretic peptide inhibits release ofaldosterone
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Plasma K+ level regulates potassium balance
High plasma K+ level promotes tubular
secretion of potassium
Low plasma K+ level inhibits tubular secretion
of potassium
Aldosterone increases potassium secretion
Regulation of potassium
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Regulation of chloride
Chloride is the major anion associated with sodium
It moves with sodium
Aldosterone increases the tubular reabsorption of chloride
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Dehydration can result from diminished intake of water or excessive loss of
water
Excessive water loss is a far more common cause of dehydration
Dehydration
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Excessive water loss can be due to:
• Excessive sweating
• Vomiting
• Diarrhoea
• Haemorrhage
• Burns
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Excessive water loss can also occur inuncontrolled diabetes mellitus
To dissolve the glucose being excretedin urine, urinary water output increases
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Excess water loss in urine may also occurin renal diseases
This happens when the kidneys fail toreabsorb water e.g. in chronic glomerulo-nephritis
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Extremely severe water loss can occur in diabetes insipidus
Diabetes insipidus can be:
Central diabetes insipidus
Nephrogenic diabetes insipidus
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Central diabetes insipidus is due todecreased secretion of ADH
Nephrogenic diabetes insipidus is dueto decreased responsiveness of targetcells to ADH
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Dehydration is corrected by administra-tion of fluids
The fluids may be given orally or intra-venously
The composition of the fluid givenshould be similar to that of the fluid lost
Correction of dehydration
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Excessive retention of water can occurin acute renal failure
Kidneys fail to excrete water in acuterenal failure
Sometimes, it can result from over-administration of intravenous fluids
Water intoxication
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Hypersecretion of ADH is a rare causeof water retention
Apart from treatment of the primarycause, diuretics may be used toincrease the output of urine
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Most diuretics act by inhibiting thetubular reabsorption of some solutes
Water is lost in urine to dissolve theextra solutes
Diuretics
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Some commonly used diuretics are:
• Acetazolamide
• Spironolactone
• Thiazides
• Furosemide
• Ethacrynic acid
• Mannitol
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Acetazolamide is a competitive inhibitorof carbonic anhydrase
It decreases the formation of carbonicacid in proximal convoluted tubules
Normally, carbonic acid dissociates intoH+ and HCO3
–
Acetazolamide
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H+ is secreted into tubular fluid inexchange for Na+
By disrupting this exchange, acetazola-mide increases urinary Na+ excretion
Extra water is excreted to dissolve Na+
Excessive use of acetazolamide cancause acidosis due to H+ retention
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Spironolactone is a structural analogueof aldosterone
Due to structural resemblance, it bindsto aldosterone receptors
This prevents the action of aldosteroneon distal convoluted tubules
Spironolactone
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When the action of spironolactone isblocked, excretion of sodium andchloride increases
Water excretion is increased due to theosmotic effect of sodium and chloride
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Thiazides inhibit sodium re-absorptionin the distal convoluted tubules
They also increase potassium loss
Thiazides
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Furosemide decreases reabsorption of sodium and chloride in the loop of Henle
Hence, it is known as a loop diuretic
It is a potassium-sparing diuretic as itdoes not cause potassium loss
Furosemide
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Action of ethacrynic acid is very similarto that of furosemide
This is also a potassium-sparing loopdiuretic
Ethacrynic acid
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Mannitol is an osmotic diuretic
It is filtered by the glomeruli but isnot re-absorbed by the tubules
Extra water is lost in urine due tothe osmotic effect of mannitol
Mannitol
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Dehydration described earlier is neverdue to a pure water loss
The fluids lost from the body containelectrolytes also
The loss usually occurs from the extra-cellular compartment as the intracellularfluid is tightly protected
ECF contraction and expansion
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Dehydration results in a decrease in ECF volume (ECF contraction)
Depending upon the osmolality of the fluid lost, ECF contraction can be:
Isotonic Hypotonic Hypertonic
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Retention of water causes an increase in the volume of ECF (ECF expansion)
ECF expansion can be:
Isotonic Hypotonic Hypertonic
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Isotonic contraction or expansion of ECFdoes not affect the ICF
If ECF becomes hypotonic or hypertonic,secondary changes occur in the ICF
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Isotonic fluid is lost from the body
Can occur in diarrhoea due to loss of isotonic secretions
Can occur in intestinal obstruction due to collection of secretions in the gut
Isotonic ECF contraction
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Hypertonic fluid is lost from the body
Can occur in Addison’s disease due to excessive loss of sodium and chloride in urine
Hypotonic ECF contraction
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Hypotonic fluid is lost from the body
Can occur in fevers and heat exposure due to excessive sweating or insensible perspiration
Hypertonic ECF contraction
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Isotonic fluid accumulates in interstitial tissue
Can occur due to oedema caused by hypertension, congestive heart failure, nephrotic syndrome, cirrhosis of liver etc
Isotonic ECF expansion
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More water is retained than solutes
Can occur in acute glomerulonephritis due to decreased glomerular filtration
Hypotonic ECF expansion
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Retention of solutes is more than that of water
Can occur in primary aldosteronism and Cushing’s disease due to retention of sodium and chloride
Hypertonic ECF expansion
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ECF contraction clinically manifests as adecrease in blood volume (hypovolaemia)
Sudden and excessive loss of fluids fromthe body can cause life-threatening hypo-volaemia
Hypovolaemia
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But hypovolaemia is not always due toloss of fluids
It can occur when the total body water isnormal, or even increased
It may be due to shifting of water fromthe vascular compartment into interstitialtissue
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A decrease in blood volume decreases the blood pressure
Restoration of blood volume and blood pressure requires the actions of:
Renin-angiotensin system
Aldosterone
ADH
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Compensatory mechanisms may be unable to correct hypovolaemia:
If it is too severe
If the pathological condition causing hypovolaemia persists
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Pathological conditions causing hypovolaemia may do so by causing:
Fluid loss
Redistribution of water
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Renal Na and H2O loss can
occur in:
• Chronic renal diseases
• Diabetes mellitus
• Addison’s disease
• Diabetes insipidus etc
Extra-renal Na and H2O loss can occur in:
• Fevers
• Vomiting
• Diarrhoea
• Intestinal obstruction
• Haemorrhage
• Burns etc
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A shift of water from the vascular compartment into interstitial tissue (oedema) can cause hypovolaemia
Redistribution of water
Oedema can occur due to a decrease
in oncotic pressure of plasma or due
to an increase in capillary permeability
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Common causes of
oedema are:
Congestive heart failure
Nephroticsyndrome
Cirrhosis of liver
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Hypovolaemia
can be:
Isotonic
Hypotonic
Hypertonic
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Isotonic hypovolaemiacan occur due to:
Diarrhoea
Intestinal obstruction
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Hypotonic hypovolaemiacan occur due to:
Chronic renal disease
Excessive use of diuretics
Addison’s disease
Congestive heart failure
Nephrotic syndrome
Cirrhosis of liver
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Hypertonic hypovolaemiacan occur due to:
Fevers
Heat exposure
Severe burns
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Treatment of hypovolaemia should comprise:
Treatment of the primary cause
Correction of fluid balance
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In hypovolaemia due to shifting of waterfrom vascular compartment, correctionrequires salt restriction and diuretics
In hypovolaemia due to sodium andwater loss, correction requires oral orintravenous administration of fluids
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Oral rehydration is preferable if hypo-volaemia is mild
Severe cases require intravenous fluids
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In isotonic hypovolaemia, isotonic (0.9%)saline should be given
In hypotonic hypovolaemia, hypertonic(3%) saline is preferable
In hypertonic hypovolaemia, hypotonic(0.45%) saline or 5% GDW (glucose indistilled water) is preferable
Intravenous fluids
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While giving intravenous fluids, a watchshould be kept on serum potassium
Care should be taken not to over-hydrate the patient
Fluid imbalance may be accompaniedby disturbances in acid-base balance
Acid-base imbalance should also becorrected along with the fluid imbalance
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