Fluid Balance and Homeostasis PDF

Summary

This document provides an overview of fluid balance in the human body. It describes water balance, electrolyte balance, and acid-base balance. The document goes into detail on the actions of the various systems involved and the effects of imbalances.

Full Transcript

Balance
cellular function requires a fluid medium with a
carefully controlled composition
three types of homeostatic balance:
1. water balance
2. electrolyte balance
3. acid-base balance
balances maintained by the collective action of the
urinary, respiratory, digestive, integumentary,
endocrine, nervous, cardiovascular, and lymphatic
systems

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 Body Water
newborn baby’s body weight is about 75%
water
young men average 55% - 60%
women average slightly less
obese & elderly people as little as 45%
total body water (TBW) of a 70kg (150
lb) young man is about 40 liters
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 Fluid Compartments
major fluid compartments of the body
– 65% intracellular fluid (ICF)
– 35% extracellular fluid (ECF)
25% tissue (interstitial) fluid
8% blood plasma and lymphatic fluid
2% transcellular fluid ‘catch-all’ category

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Water Movement Between Fluid
Compartments
fluid continually exchanged btwn compartments
– water moves by osmosis

osmosis from one fluid compartment to another is
determined by the relative concentrations of solutes in
each compartment
– electrolytes – the most abundant solute particles
sodium salts in ECF
potassium salts in ICF

electrolytes are key to body’s water distribution

24-4
Water Movement Between Fluid
Compartments
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or
display.

Intracellular
fluid

Digestive tract

Bloodstream Tissue fluid Lymph Bloodstream

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 Water Gain
fluid balance: when daily gains & losses are equal

gains come from two sources:
1. preformed water (2,300 mL/day)
ingested in food and drink

2. metabolic water (200 mL/day)
by-product of aerobic metabolism and
dehydration synthesis
– C6H12O6 + 6O2 6CO2 + 6H2O

24-6
 Fluid Balance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or
display.

Intake Output
2,500 mL/day 2,500 mL/day
Individual
values are
FYI
Metabolic water Feces
200 mL 200 mL
Expired air
300 mL
Food
700 mL Cutaneous
transpiration
400 mL
Sweat 100 mL

Drink Urine
1,600 mL 1,500 mL

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Regulation of Fluid Intake
thirst mainly governs fluid intake
dehydration
– reduces blood volume and blood pressure
– increases blood osmolarity

osmoreceptors in hypothalamus:
– respond to angiotensin II
produced when BP or blood volume drops
– communicate w/ hypothalamus & cerebral cortex
– hypothalamus makes antidiuretic hormone (ADH)
– cerebral cortex produces sense of thirst

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 Dehydration

Increased Reduced
blood osmolarity blood pressure

Dehydration, Dehydration
Renin

Thirst, and
Angiotensin II

Stimulates Stimulates

Rehydration hypothalamic
osmoreceptors
Reduced
hypothalamic
osmoreceptors

salivation

Dry mouth

Thirst
Sense of
thirst

Ingestion
of water

Cools and Distends Short-term
moistens mouth stomach inhibition
and intestines of thirst
Long-term
Rehydrates inhibition
Rehydration blood of thirst
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Regulation of Water Output
only way to control water output: variation in urine
volume
– kidneys can’t replace water or electrolytes
– can only slow rate of water & electrolyte loss until
water & electrolytes can be ingested

Two mechanisms:
a) changes in urine volume linked to adjustments
in Na+ reabsorption
as Na+ is reabsorbed or excreted, water follows

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Regulation of Water Output
b) concentrate the urine through action of ADH
ADH secretion stimulated by hypothalamic
osmoreceptors in response to dehydration
aquaporins synthesized in response to ADH
– membrane proteins in renal collecting ducts
whose job is to channel water back into renal
medulla; Na+ is still excreted
– concentrates urine

– ADH release inhibited when blood volume and
pressure is too high or blood osmolarity too low
helps to compensate for hypertension

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Secretion Dehydration

and H 2O H2O Na+ Na+

Elevates blood osmolarity

Effects of Negative
feedback
Stimulates hypothalamic

ADH
loop
osmoreceptors
Negative
feedback
Water Stimulates posterior pituitary loop
ingestion to release antidiuretic hormone (ADH)

Stimulates distal convoluted
Thirst tubule and collecting duct

Increases water reabsorption

Reduces urine Increases ratio
volume of Na+: H2O
in urine

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Disorders of Water Balance
– volume depletion (hypovolemia)
– water and Na both lost equally - osmolarity stays
normal
– hemorrhage, severe burns, chronic vomiting, or
diarrhea

– dehydration (negative water balance)
– more water lost than sodium - osmolarity rises
– lack of drinking water, diabetes, profuse sweating,
overuse of diuretics

– most serious effects:
circulatory shock due to loss of blood volume,
neurological dysfunction due to dehydration of brain
cells, infant mortality from diarrhea 24-13
 Fluid Excess
fluid excess – not common; kidneys compensate for
excessive intake by excreting more urine
– renal failure can lead to fluid retention

two types of fluid excesses:
1. volume excess
both Na+ & water retained - ECF stays isotonic
caused by aldosterone hypersecretion or renal failure
(or salty diet)
2. hypotonic hydration (water intoxication)
more water than Na+ retained or ingested
ECF becomes hypotonic
– cellular swelling, pulmonary & cerebral edema

24-14
Blood Volume & Fluid Intake Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or
display.

5

4 Hypovolemia
Blood volume (L)

Death
3

2

1
Danger Normal Water diuresis
0
0 1 2 3 4 5 6 7 8
Fluid intake (L/day)

kidneys compensate well for excessive fluid
intake, but not for inadequate fluid intake
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 Fluid Sequestration
fluid sequestration – excess fluid accumulates in a
particular location

total body water may be normal, but volume of blood
may drop, causing circulatory shock

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 Fluid Sequestration
There should be an equilibrium of fluid moving into
and back out of the tissues (Starling’s Law of the
Capillaries)
– If equilibrium is lost: edema - build-up of fluid in the
interstitial spaces, causes swelling of tissues

hemorrhage - another cause of fluid sequestration
blood that pools in the tissues is not circulating
pleural effusion – several liters of fluid can accumulate in
the pleural cavity
caused by some lung infections

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?

24-18
 Electrolyte Balance
functions of electrolytes:
– chemically reactive & participate in metabolism
– determine electrical potential across cell membranes
– strongly affect osmolarity of body fluids, thus affect
body’s water content and distribution

major cations: Na+, K+, Ca2+, and H+

major anions: Cl-, HCO3- (bicarbonate), and PO43-

different concentrations in blood plasma and
intracellular fluid (ICF)
– but same osmolarity

24-19
 145

300
103

Electrolyte
Concentrations
(know relative 4 5 4

proportions, not (a) Blood plasma
150
numbers)
300

75

12
4 145 mEq/L (FYI)
Causes: loss of water faster than sodium (diarrhea),
not drinking
Results: water retention, hypertension & edema

hyponatremia
– plasma sodium concentration 7.45, Why is it bad?
– H+ diffuses out of cells and K+ diffuses in,
membranes depolarized, nerves and muscles
overstimulated
– a person cannot live for more than a few hours if
the blood pH is below 7.0 or above 7.7

K+ H+ Protein

leading to
(b) Alkalosis Hypokalemia 24-52
Disorders of Acid-Base Balance
two categories: respiratory and metabolic

respiratory acidosis
– when ventilation rate too slow for rate of CO2
production
– CO2 accumulates in the ECF & lowers its pH
– emphysema is a common cause
– Arterial Blood Gas (ABG) measurement will show
high PCO2
respiratory alkalosis
– results from hyperventilation
– CO2 eliminated faster than it is produced
24-53
Disorders of Acid-Base Balance
metabolic acidosis
– increased production of acids like lactic acid
(anaerobic fermentation), or ketone bodies
(alcoholism, diabetes mellitus)
– ingestion of acidic drugs (aspirin)
– loss of base due to chronic diarrhea, laxative
overuse
metabolic alkalosis
– rare, but can result from:
– overuse of antacids
– loss of stomach acid (chronic vomiting)

24-54
Compensation for Acid-Base
Imbalances
compensated acidosis or alkalosis:
– either the kidneys compensate for pH
imbalances of respiratory origin, or
– the respiratory system compensates
for pH imbalances of metabolic origin

uncompensated acidosis or alkalosis
– a pH imbalance that the body cannot
correct without clinical intervention

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Compensation for Acid-Base
Imbalances
respiratory compensation – changes in
pulmonary ventilation to correct changes in
pH of body fluids
– an acidic pH (like with ketoacidosis)
stimulates pulmonary ventilation,
eliminating CO2 and allowing pH to rise
– an alkaline pH reduces ventilation and
allows CO2 to build up, lowering pH

24-56
Compensation for Acid-Base
Imbalances
renal compensation – adjustment of pH by changing
rate of H+ secretion by the renal tubules
– slow, but better at restoring a fully normal pH
– in acidosis, urine pH may fall as low as 4.5
renal tubules secrete more H+, elevating pH
– in alkalosis, as high as 8.2 b/c of excess HCO3-
renal tubules secrete less H+, lowering pH

– kidneys cannot act quickly enough to compensate for
short-term pH imbalances
– better for imbalances that last > a few days

24-57