Transcript acid
Chapter 21
Bio 202
Anatomy &
Physiology Part 2
Tim Pimperl
A & P Instructor
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Important Points in Chapter 21:
Outcomes to be Assessed
21.1: Introduction
Explain the balance concept.
Explain the importance of water and electrolyte balance.
21.2: Distribution of Body Fluids
Describe how body fluids are distributed in compartments.
Explain how fluid composition varies among compartments and how
fluids move from one compartment to another.
21.3: Water Balance
List the routes by which water enters and leaves the body.
Explain the regulation of water input and water output.
2
Important Points in Chapter 21:
Outcomes to be Assessed
21.4: Electrolyte Balance
List the routes by which electrolytes enter and leave the body.
Explain the regulation of the input and the output of electrolytes.
21.5: Acid-Base Balance
Explain acid-base balance.
Identify how pH number describes the acidity and alkalinity of a body
fluid.
List the major sources of hydrogen ions in the body.
Distinguish between strong acids and weak acids.
Explain how chemical buffer systems, the respiratory center, and the
kidneys keep the pH of body fluids relatively constant.
3
Important Points in Chapter 21:
Outcomes to be Assessed
21.6: Acid-Base Imbalances
Describe the causes and consequences of increase or decrease in body
fluid pH.
4
21.1: Introduction
• The term balance suggests a state of constancy
• For water and electrolytes that means equal amounts enter and
leave the body
• Mechanisms that replace lost water and electrolytes and
excrete excesses maintain this balance
• This results in stability of the body at all times
• Keep in mind water and electrolyte balance are
interdependent.
5
21.2: Distribution of Body Fluids
• Body fluids are not uniformly distributed
• They occupy compartments of different volumes that
contain varying compositions
• Water and electrolyte movement between these
compartments is regulated to stabilize their distribution and
the composition of body fluids
6
Fluid Compartments
•
An average adult female is about 52% water by
weight, and an average male about 63% water
by weight
There are about 40 liters of water (with its
dissolved electrolytes) in the body, distributed
into two major compartments:
• Intracellular fluid – 63% - fluid inside cells
• Extracellular fluid – 37% - fluid outside
cells
• Interstitial fluid
• Blood plasma
• Lymph
• Transcellular fluid – separated from
other extracellular fluids by epithelial
layers
• Cerebrospinal fluid
• Aqueous and vitreous humors
• Synovial fluid
• Serous fluid
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40
38
36
34
32
30
28
26
24
22
20
18
16
14
12
10
8
6
4
2
0
Extracellular
fluid
(37%)
Liters
•
Intracellular
fluid
(63%)
7
Total Body Water
40 liters (10.6 gallons)
63% Intracellular Fluid
d37% Extracellular Fluid
Interstitial Fluid
Plasma
Lymph
Transcellular Fluid
Female – 52%
Male – 63%
8
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Total body water
Interstitial fluid
Plasma
Membranes of
body cells
Intracellular fluid
(63%)
Lymph
Extracellular fluid
(37%)
Transcellular
fluid
Transcellular:
CSF, aqueous & vitreous
humors, joints, body cavities
exocrine gland secretions etc.
9
Body Fluid Composition
• Blood plasma has more proteins
than interstitial fluid or lymph
• Intracellular fluids have high
concentrations of potassium,
magnesium, phosphate, and sulfate
ions
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Relative concentrations and ratios of ions in extracellular and intracellular fluids
150
140
Extracellular fluid
130
Intracellular fluid
120
110
Ion concentration (m Eq/L)
• Extracellular fluids are generally
similar in composition including
high concentrations of sodium,
calcium, chloride and bicarbonate
ions
100
90
80
70
60
50
40
30
20
10
0
Na+
Ratio 14:1
K+
Ca+2
Mg+2
Cl-
1:28
5:1
1:19
26:1
(Extracellular: intracellular)
HCO3- PO4-3 SO4-2
3:1
1:19
1:2
10
Movement of Fluid
Between Compartments
• Two major factors regulate the movement of water and
electrolytes from one fluid compartment to another
• Hydrostatic pressure
• Osmotic pressure
Fluid leaves plasma
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Capillary wall
Plasma
Interstitial fluid
Transcellular
fluid
Serous
membrane
at arteriolar end of
capillaries because
outward force of
hydrostatic pressure
predominates
Fluid returns to
plasma at venular
ends of capillaries
because inward force
Lymph of colloid osmotic
vessel pressure predominates
Hydrostatic pressure
Lymph within interstitial
spaces forces fluid
into lymph capillaries
Intracellular
fluid
Cell
membrane
Interstitial fluid is
in equilibrium with
transcellular and
intracellular fluids
11
21.3: Water Balance
• Water balance exists when water intake equals water output
• Homeostasis requires control of both water intake and
water output
12
Water Intake
• The volume of water gained each day varies among
individuals averaging about 2,500 milliliters daily for an
adult:
• 60% from drinking
Average daily intake of water
Average daily output of water
• 30% from moist foods
Water lost in sweat
(150 mL or 6%)
Water of
Water lost in feces
• 10% as a bi-product of
metobolism
(150 mL or 6%)
(250 mL or 10%)
Water
in
Water lost through
oxidative metabolism of
moist food
skin and lungs
(750 mL or 30%)
(700 mL or 28%)
nutrients called water of
Total intake
Total output
(2,500 mL)
(2,500 mL)
metabolism
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Water in
beverages
(1,500 mL or 60%)
(a)
Water lost in urine
(1,500 mL or 60%)
(b)
13
Regulation of Water Intake
The primary regulator of water intake is thirst.
14
Water Output
• Water normally enters the body only through the mouth, but
it can be lost by a variety of routes including:
• Urine (60% loss)
• Feces (6% loss)
• Sweat (sensible perspiration) (6% loss)
• Evaporation from the skin (insensible perspiration)
• The lungs during breathing
(Evaporation from the skin and the lungs is a 28% loss)
15
Regulation of Water Output
The osmoreceptor-ADH mechanism in the hypothalamus
regulates the concentration of urine produced in the kidney.
16
21.1 Clinical Application
Water Balance Disorders
(Read all of this Clin. App. Carefully pg. 816 12e & 808-809 13e)
Water intox./hyponatremia
headache
weakness
dizziness
nausea
muscle cramps
slurred speech
confusion
loss of consciousness
seizures in severe cases
Dehydration
dry mouth & mucous membranes
confusion
profuse sweating progressing
to no sweating
increased temperature
17
21.4: Electrolyte Balance
• An electrolyte balance exists when the quantities of
electrolytes the body gains equals those lost
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Foods
Fluids
Metabolic
reactions
Electrolyte intake
Electrolyte output
Perspiration
Feces
Urine
18
Electrolyte Intake
• The electrolytes of greatest importance to cellular functions
release sodium, potassium, calcium, magnesium, chloride,
sulfate, phosphate, bicarbonate, and hydrogen ions
• These ions are primarily obtained from foods, but some are
from water and other beverages, and some are by-products of
metabolism
19
Regulation of Electrolyte Intake
• Ordinarily, a person obtains sufficient electrolytes by
responding to hunger and thirst
• A severe electrolyte deficiency may cause salt craving
20
Electrolyte Output
• The body loses some electrolytes by perspiring (more on
warmer days and during strenuous exercise)
• Some are lost in the feces
• The greatest output is as a result of kidney function and urine
output
21
Regulation of Electrolyte Output
• The concentrations of positively charged ions, such as sodium (Na+),
potassium (K+) and calcium (Ca+2) are of particular importance
• These ions are vital for nerve impulse conduction, muscle fiber
contraction, and maintenance of cell membrane permeability
• Sodium ions account for nearly 90% of the positively charged ions in
extracellular fluids
22
Regulation of Electrolyte Output
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Potassium ion
concentration increases
Calcium ion
Concentration decreases
Parathyroid glands
are stimulated
Adrenal cortex is signaled
Parathyroid hormone
is secreted
Aldosterone is secreted
Renal tubules conserve
calcium and increase
secretion of phosphate
Intestinal absorption
of calcium increases
Activity of bone-resorbing
osteoclasts increases
Renal tubules
increase reabsorption of
sodium ions and increase
secretion of potassium ions
Increased phosphate
excretion in urine
Addition of phosphate
to bloodstream
Sodium ions are
conserved and potassium
ions are excreted
Calcium ion concentration
returns toward normal
Normal phosphate
concentration is maintained
23
21.2 Clinical Application
Sodium and Potassium Imbalances
Read through these imbalances carefully
Pg. 820 12 e & pg. 811 13e
Hyponatremia - PubMed Health
24
21.5: Acid-Base Balance
• Acids are electrolytes that ionize in water and release
hydrogen ions
• Bases are substances that combine with hydrogen ions
• Acid-base balance entails regulation of the hydrogen ion
concentrations of body fluids
• This is important because slight changes in hydrogen ion
concentrations can alter the rates of enzyme-controlled
metabolic reactions, shift the distribution of other ions, or
modify hormone actions
• pH number indicates the degree to which a solution is acidic
or basic (alkaline).
• The more acid the solution, the lower its pH
25
• The more alkaline the solution, the higher its pH
Sources of Hydrogen Ions
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Aerobic
respiration
of glucose
Anaerobic
respiration
of glucose
Incomplete
oxidation of
fatty acids
Oxidation of
sulfur-containing
amino acids
Hydrolysis of
phosphoproteins
and nucleic acids
Carbonic
acid
Lactic
acid
Acidic ketone
bodies
Sulfuric
acid
Phosphoric
acid
H+
Internal environment
26
Strengths of Acids and Bases
• Acids:
• Strong acids ionize more completely and release more H+
• Ex: HCl
• Weak acids ionize less completely and release fewer H+
• Ex: H2CO3
• Bases:
• Strong bases ionize more completely and release more OHor other negative ions
• Weak bases ionize less completely and release fewer OHor other negative ions
27
Regulation of Hydrogen Ion
Concentration
• Either an acid shift or an alkaline (basic) shift in the body
fluids could threaten the internal environment
• Normal metabolic reactions generally produce more acid
than base
• The reactions include cellular metabolism of glucose, fatty
acids, and amino acids
• Maintenance of acid-base balance usually eliminates acids
in one of three ways:
• Acid-base buffer systems
• Respiratory excretion of carbon dioxide
• Renal excretion of hydrogen ions
28
Chemical Buffer Systems
Chemical buffer systems are in all body fluids and are based on chemicals that
combine with excess acids or bases.
•Bicarbonate buffer system
• The bicarbonate ion converts a strong acid to a weak acid
• Carbonic acid converts a strong base to a weak base
H+ + HCO3- H2CO3 H+ + HCO3• Phosphate buffer system
• The monohydrogen phosphate ion converts a strong acid to a weak acid
• The dihydrogen phosphate ion converts a strong base to a weak base
H+ + HPO4-2 H2PO4- H+ + HPO4-2
• Protein buffer system
• NH3+ group releases a hydrogen ion in the presence of excess base
• COO- group accepts a hydrogen ion in the presence of excess acid
29
30
Respiratory Excretion of Carbon Dioxide
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• The respiratory center in the
brainstem helps regulate
hydrogen ion concentrations in
the body fluids by controlling
the rate and depth of breathing
• If body cells increase their
production of CO2…
Cells increase production of CO2
CO2 reacts with H2O to produce H2CO3
H2CO3 releases H+
Respiratory center is stimulated
Rate and depth of breathing increase
More CO2 is eliminated through lungs
31
Respiratory System
32
Renal Excretion of Hydrogen Ions
• Nephrons help regulate the hydrogen ion concentration of
body fluids by excreting hydrogen ions in the urine
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High intake of proteins
Increased metabolism
of amino acids
Increased concentration
of H+ in urine
Concentration of H+
in body fluids returns
toward normal
Increased secretion
of H+ into fluid of
renal tubules
Increased formation
of sulfuric acid and
phosphoric acid
Increased concentration
of H+ in body fluids
33
Urinary System
34
Time Course of pH Regulation
• Various regulators of
hydrogen ion
concentration operate at
different rates
First line of defense
• Acid-base (chemical) against pH shift
buffers function rapidly
• Respiratory and renal
(physiological buffers)
mechanisms function
Second line of
more slowly
defense against
pH shift
(Resp.-takes several
minutes.
Renal- up to 1 to 3
days.)
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Bicarbonate
buffer system
Chemical
buffer system
Phosphate
buffer system
Protein
buffer system
Respiratory
mechanism
(CO2 excretion)
Physiological
buffers
Renal
mechanism
(H+ excretion)
35
Time Course of pH Regulation
• Various regulators of
hydrogen ion
concentration operate at
different rates
First line of defense
• Acid-base (chemical) against pH shift
buffers function rapidly
• Respiratory and renal
(physiological buffers)
mechanisms function
Second line of
more slowly
defense against
pH shift
(Resp.-takes several
minutes.
Renal- up to 1 to 3
days.)
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Bicarbonate
buffer system
Chemical
buffer system
Phosphate
buffer system
Protein
buffer system
Respiratory
mechanism
(CO2 excretion)
Physiological
buffers
Renal
mechanism
(H+ excretion)
36
21.6: Acid-Base Imbalances
• Chemical and physiological buffer systems ordinarily
maintain the hydrogen ion concentration of body fluids within
very narrow pH ranges
• Abnormal conditions may disturb the acid-base balance
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Alkalosis
Acidosis
pH scale
6.8
7.0
7.35 7.45
7.8
8.0
Normal pH range
Survival range
37
Acidosis
• Acidosis results from the
accumulation of acids or loss of
bases, both of which cause
abnormal increases in the
hydrogen ion concentrations of
body fluids
• Alkalosis results from a loss of
pH scale
acids or an accumulation of
bases accompanied by a decrease
in hydrogen ion concentrations
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Accumulation
of acids
Loss of
bases
Increased concentration of H+
Acidosis
pH drops
7.4
pH rises
Alkalosis
Decreased concentration of H+
Loss of
acids
Accumulation
of bases
38
Acidosis
• Two major types of acidosis are respiratory acidosis and
metabolic acidosis
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Kidney failure
to excrete acids
Excessive production of acidic
ketones as in diabetes mellitus
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Decreased rate
and depth of
breathing
Obstruction of
air passages
Decreased
gas exchange
Accumulation of nonrespiratory acids
Metabolic acidosis
Accumulation of CO2
Excessive loss of bases
Respiratory
acidosis
Prolonged diarrhea
with loss of alkaline
intestinal secretions
Prolonged vomiting
with loss of intestinal
secretions
39
Alkalosis
• Respiratory alkalosis develops as a result of hyperventilation
• Metabolic alkalosis results from a great loss of hydrogen ions
or from a gain in bases, both accompanied by a rise in the pH
of blood
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• Anxiety
• Fever
• Poisoning
• High altitude
Gastric
drainage
Vomiting with loss
of gastric secretions
Hyperventilation
Loss of acids
Excessive loss of CO2
Decrease in concentration of H2CO3
Net increase in alkaline substances
Decrease in concentration of H+
Respiratory alkalosis
Metabolic alkalosis
40
• Normal Arterial Blood Gas Values
•
•
•
•
•
•
pH
PaCO2
O2
HCO3
Saturation
BE
7.35-7.45
35-45 mm HgPa
80-95 mm Hg
22-26 mEq/LO2
95-99%
+/- 1
Four-Step Guide to ABG Analysis
• Is the pH normal, acidotic or alkalotic?
• Are the pCO2 or HCO3 abnormal? Which
one appears to influence the pH?
• If both the pCO2 and HCO3 are abnormal,
the one which deviates most from the norm
is most likely causing an abnormal pH.
• Check the pO2. Is the patient hypoxic? \
• manuelsweb.com
pH control and ABG’s (Arterial
Blood Gases)
• http://orlandohealth.com/pdf%20folder/Inte
r%20of%20Arterial%20Blood%20Gas.pdf
• ABG interpreter – calculator
• http://manuelsweb.com/abg.htm
pH control and ABG’s (Arterial
Blood Gases)
• Interp. of Arterial Blood Gases.pdf
• ABG interpreter - calculator.mht
pH control and ABG’s Practice
•
•
•
•
Analyze the following:
pH
7.35
pCO2 33
HCO3 15
• ABG interpreter - calculator.mht
• (Must allow blocked content for interpreter to work.)
pH control and ABG’s Practice
•
•
•
•
Analyze the following:
pH
7.35
pCO2 49
HCO3 28
• ABG interpreter - calculator.mht
pH control and ABG’s Practice
•
•
•
•
Analyze the following:
pH
7.48
pCO2 40
HCO3 30
• ABG interpreter - calculator.mht
pH control and ABG’s Practice
•
•
•
•
Analyze the following:
pH
7.30
pCO2 49
HCO3 28
• ABG interpreter - calculator.mht