1. Figure 27-1a The Composition of the Human Body.
SOLID COMPONENTS (31.5 kg; 69.3 lb)
WATER (38.5 kg; 84.7 lb) 15 20
Other 15
Plasma 10
Liters Kg 10
Interstitial
fluid 5 5
Proteins
Lipids
Minerals
Carbohydrates
Miscellaneous
Intracellular fluid
Extracellular fluid a
The body composition (by weight, averaged for both sexes) and major body fluid compartments of a 70-kg (154-lb)
person. For technical reasons, it is extremely difficult to determine the precise size of any of these compartments;
estimates of their relative sizes vary widely.
p. 1018

2. Figure 27-1b The Composition of the Human Body.
ICF
ECF
ICF
ECF
Intracellular
fluid 27%
Interstitial
fluid 18%
Intracellular
fluid 33%
Interstitial
fluid 21.5%
Plasma 4.5%
Other
body
fluids
(≤1%)
Plasma 4.5%
Solids 50%
(organic and inorganic materials)
Solids 40%
(organic and inorganic materials)
Other
body
fluids
(≤1%)
Adult males
Adult females b
A comparison of the body compositions of adult males and females, ages 18–40 years.
p. 1018

3. Figure 27-2 Cations and Anions in Body Fluids (Part 1 of 3).
INTRACELLULAR FLUID
200
KEY
Na+
HCO3–
Cations
CI–
Na+ K+
150
Ca2+
Milliequivalents per liter (mEq/L)
HPO42–
Mg2+ K+
100
Anions
HCO3–
SO42–
CI–
HPO42– 50
SO42–
Proteins
Organic
acid
Mg2+
Proteins
p. 1019
Cations
Anions

4. Figure 27-2 Cations and Anions in Body Fluids (Part 2 of 3).
PLASMA
200
KEY
Cations
Na+ K+
150
HCO3–
Ca2+
Milliequivalents per liter (mEq/L)
Mg2+
100
Anions
HCO3–
Na+
CI–
CI–
HPO42– 50
HPO42–
SO42–
Org. acid
Organic
acid K+
Proteins
Ca2+
Proteins
p. 1019
Cations
Anions

5. Figure 27-2 Cations and Anions in Body Fluids (Part 3 of 3).
INTERSTITIAL FLUID
200
KEY
Cations
Na+ K+
150
Ca2+
Milliequivalents per liter (mEq/L)
HCO3–
Mg2+
100
Anions
HCO3–
Na+
CI–
CI–
HPO42– 50
SO42–
Organic
acid
HPO42–
SO42– K+
Proteins
p. 1019
Cations
Anions

6. p. 1019 © 2015 Pearson Education, Inc. © 2012 Pearson Education, Inc.
Copyright © 2009 Pearson Education, Inc., publishing as Pearson Benjamin Cummings
© 2012 Pearson Education, Inc.

7. Normal Sodium Concentrations
In ECF ~140 mEq/L
In ICF ~ 10 mEq/L or less
Normal Potassium Concentrations
In ICF ~ 160 mEq/L
In ECF ~ 3.5–5.5 mEq/L
© 2015 Pearson Education, Inc.
Copyright © 2009 Pearson Education, Inc., publishing as Pearson Benjamin Cummings
© 2012 Pearson Education, Inc.

8. p. 1025 © 2015 Pearson Education, Inc. © 2012 Pearson Education, Inc.
Copyright © 2009 Pearson Education, Inc., publishing as Pearson Benjamin Cummings

9. HOMEOSTASIS p. 1025 Normal Na+ concentration in ECF
Figure 27-5 The Homeostatic Regulation of Normal Sodium Ion Concentration in Body Fluids (Part 1 of 2).
ADH Secretion Increases
Recall of Fluids
The secretion of ADH restricts
water loss and stimulates thirst,
promoting additional water
consumption
Because the ECF
osmolarity increased,
water shifts out of the
ICF, increasing ECF
volume and decreasing
Na+ concentrations
Osmoreceptors
in hypothalamus
stimulated
HOMEOSTASIS
RESTORED
HOMEOSTASIS
DISTURBED
Decreased Na+
levels in ECF
Increased Na+
levels in ECF
HOMEOSTASIS
Normal Na+
concentration
in ECF
Start
p. 1025

10. p. 1025 HOMEOSTASIS Normal Na+ concentration in ECF HOMEOSTASIS
Figure 27-5 The Homeostatic Regulation of Normal Sodium Ion Concentration in Body Fluids (Part 2 of 2).
HOMEOSTASIS
Normal Na+
concentration
in ECF
Start
HOMEOSTASIS
DISTURBED
HOMEOSTASIS
RESTORED
Decreased Na+
levels in ECF
Increased Na+
levels in ECF
Osmoreceptors
in hypothalamus
inhibited
Water loss decreases
ECF volume,
concentrates ions
ADH Secretion
Decreases
As soon as the osmotic
concentration of the
ECF decreases by
2 percent or more, ADH
secretion decreases, so
thirst is suppressed
and water losses by
the kidneys increase
p. 1025

11. p. 1026 © 2015 Pearson Education, Inc. © 2012 Pearson Education, Inc.
Copyright © 2009 Pearson Education, Inc., publishing as Pearson Benjamin Cummings
© 2015 Pearson Education, Inc.
© 2012 Pearson Education, Inc.
p. 1026

12. Increasing ECF volume by fluid gain or fluid and Na+ gain
Figure 27-6 The Integration of Fluid Volume Regulation and Sodium Ion Concentration in Body Fluids (Part 1 of 2).
Responses to Natriuretic Peptides
Combined
Effects
Increased Na+ loss in urine
Decreased
blood
volume
Increasing blood
pressure and
volume
Increased water loss in urine
Natriuretic peptides
released by cardiac
muscle cells
Decreased thirst
Decreased
blood
pressure
Inhibition of ADH, aldosterone, epinephrine,
and norepinephrine release
Increased blood
volume and
atrial distension
HOMEOSTASIS
DISTURBED
HOMEOSTASIS
RESTORED
Increasing ECF volume by fluid
gain or fluid and Na+ gain
Decreasing ECF
volume
HOMEOSTASIS
Start
Normal ECF
volume
p. 1026

13. loss or fluid and Na+ loss
Figure 27-6 The Integration of Fluid Volume Regulation and Sodium Ion Concentration in Body Fluids (Part 2 of 2).
HOMEOSTASIS
Start
Normal ECF
volume
HOMEOSTASIS
DISTURBED
HOMEOSTASIS
RESTORED
Decreasing ECF volume by fluid
loss or fluid and Na+ loss
Increasing ECF
volume
Decreased blood
volume and
blood pressure
Endocrine Responses
Combined Effects
Increased renin secretion
and angiotensin II activation
Increased urinary Na+ retention
Decreased urinary water loss
Increased aldosterone
release
Decreasing blood
pressure and
volume
Increased thirst
Increased ADH release
Increased water intake
p. 1026

14. p. 1031 PCO2 40–45 mm Hg HOMEOSTASIS If PCO2 increases
Figure 27-9 The Basic Relationship between PCO2 and Plasma pH (Part 1 of 2).
PCO2
40–45
mm Hg
HOMEOSTASIS
If PCO2 increases
When carbon dioxide levels increase, more carbonic acid
forms, additional hydrogen ions and bicarbonate ions are
released, and the pH decreases.
PCO2 pH
p. 1031

15. p. 1031 pH 7.35–7.45 HOMEOSTASIS If PCO2 decreases
Figure 27-9 The Basic Relationship between PCO2 and Plasma pH (Part 2 of 2). pH
7.35–7.45
HOMEOSTASIS
If PCO2 decreases
When the PCO2 decreases, the reaction runs in reverse, and
carbonic acid dissociates into carbon dioxide and water.
This removes H+ from solution and increases the pH. pH
PCO2
p. 1031

16. Figure 27-10 Buffer Systems in Body Fluids.
occur in
Intracellular fluid (ICF)
Extracellular fluid (ECF)
Phosphate Buffer
System
Protein Buffer Systems
Carbonic Acid–
Bicarbonate Buffer System
Protein buffer systems contribute to the regulation of pH in the
ECF and ICF. These buffer systems interact extensively with the
other two buffer systems.
The phosphate
buffer system has
an important role in
buffering the pH of
the ICF and of urine.
The carbonic acid–
bicarbonate buffer
system is most
important in the ECF.
Hemoglobin buffer
system (RBCs only)
Amino acid buffers
(All proteins)
Plasma protein
buffers
p. 1032

17. Figure 27-11 The Role of Amino Acids in Protein Buffer Systems.
Neutral pH
If pH
increases
If pH
decreases
In an alkaline
medium, the amino
acid acts as an acid
and releases H+
Amino acid
(zwitterion)
In an acidic medium,
the amino acid
acts as a base
and absorbs H+
p. 1033

18. Cells in peripheral tissues
Figure A Summary of the Primary Gas Transport Mechanisms (Part 4 of 4).
HCO3−
Chloride shift
Cl−
H+ + HCO3− Hb
H2CO3 Hb H+
CO2
H2O
CO2 Hb Hb
CO2
Cells in peripheral tissues
Systemic capillary
CO2 pickup

19. Cl− Alveolar air space HCO3− Hb H+ + HCO3− Hb H+ H2CO3 CO2 CO2 H2O CO2
Figure A Summary of the Primary Gas Transport Mechanisms (Part 3 of 4).
Cl−
Alveolar air space
HCO3− Hb
H+ + HCO3− Hb H+
H2CO3
CO2
CO2
H2O
CO2 Hb Hb
CO2
Pulmonary capillary
CO2 delivery

20. Figure 27-12a The Carbonic Acid–Bicarbonate Buffer System.
BICARBONATE RESERVE
H2CO3
(carbonic acid)
NaHCO3
(sodium
bicarbonate) +
HCO3–
(bicarbonate ion)
CO2
CO2 + H2O
Na+
HCO3– H+
Lungs
Basic components of the carbonic acid–bicarbonate buffer system, and
their relationships to carbon dioxide and the bicarbonate reserve a
p. 1034

21. Figure 27-12b The Carbonic Acid–Bicarbonate Buffer System.
Fixed acids or
organic acids:
add H+
Increased
H2CO3
Na+
HCO3–
CO2
CO2 + H2O H+ +
HCO3–
NaHCO3
Lungs
The response of the carbonic acid–bicarbonate buffer system to
hydrogen ions generated by fixed or organic acids in body fluids b
p. 1034

22. Figure 27-13a Kidney Tubules and pH Regulation.
The three major buffering systems in tubular fluid, which are
essential to the secretion of hydrogen ions 1 2 3
Cells of
PCT,
DCT, and
collecting
system 1
Carbonic acid–bicarbonate
buffer system 2
Phosphate buffer system
Peritubular
fluid 3
Ammonia buffer system
Peritubular
capillary
KEY
= Countertransport
= Reabsorption
= Active transport
= Secretion
= Exchange pump
= Cotransport
= Diffusion
p. 1037

23. Figure 27-13b Kidney Tubules and pH Regulation.
Production of ammonium
ions and ammonia by the
breakdown of glutamine
Tubular fluid
in lumen
Glutamine
Glutaminase
Carbon
chain
KEY
= Countertransport
= Reabsorption
= Active transport
= Secretion
= Exchange pump
p. 1037
= Cotransport
= Diffusion

24. Figure 27-13c Kidney Tubules and pH Regulation.
The response of the
kidney tubule to
alkalosis
Tubular fluid
in lumen
Carbonic
anhydrase
KEY
= Countertransport
= Reabsorption
= Active transport
= Secretion
= Exchange pump
p. 1037
= Cotransport
= Diffusion

25. CARBONIC ACID–BICARBONATE BUFFER SYSTEM Renal Response to Acidosis
Figure 27-14a Interactions among the Carbonic Acid–Bicarbonate Buffer System and Compensatory Mechanisms in the Regulation of Plasma pH.
The response to acidosis caused by the addition of H+ a
Addition
of H+
Start
CARBONIC ACID–BICARBONATE BUFFER SYSTEM
BICARBONATE RESERVE
CO2
CO2 + H2O
H2CO3 H+ +
HCO3–
HCO3– + Na+
NaHCO3
(sodium bicarbonate)
(carbonic acid)
(bicarbonate ion)
Lungs
Generation
of HCO3–
Respiratory Response
to Acidosis
Other
buffer
systems
absorb H+
Kidneys
Renal Response to Acidosis
Increased respiratory
rate decreases PCO2,
effectively converting
carbonic acid
molecules to water.
Kidney tubules respond by (1) secreting H+,
(2) removing CO2, and (3) reabsorbing HCO3– to
help replenish the bicarbonate reserve.
Secretion
of H+
p. 1039

26. CARBONIC ACID–BICARBONATE BUFFER SYSTEM
Figure 27-14b Interactions among the Carbonic Acid–Bicarbonate Buffer System and Compensatory Mechanisms in the Regulation of Plasma pH.
The response to alkalosis caused by the removal of H+ b
Removal
of H+
Start
CARBONIC ACID–BICARBONATE BUFFER SYSTEM
BICARBONATE RESERVE
Lungs
CO2 + H2O
H2CO3 H+ +
HCO3–
HCO3– + Na+
NaHCO3
(sodium bicarbonate)
(carbonic acid)
(bicarbonate ion)
Respiratory Response
to Alkalosis
Other
buffer
systems
release H+
Generation
of H+
Kidneys
Decreased respiratory
rate increases PCO2,
effectively converting
CO2 molecules to
carbonic acid.
Renal Response to Alkalosis
Kidney tubules respond by
conserving H+ and secreting
HCO3–.
Secretion
of HCO3–
p. 1039

27. Figure 27-15a Respiratory Acid–Base Regulation
Responses to Acidosis
Respiratory compensation:
Stimulation of arterial and CSF chemo-
receptors results in increased
respiratory rate.
Increased
PCO2
Renal compensation:
Combined Effects
H ions are secreted and HCO3
ions are generated.
Respiratory Acidosis
Decreased PCO2
Elevated PCO2 results
in a fall in plasma pH
Buffer systems other than the carbonic
acid–bicarbonate system accept H ions.
Decreased H and
increased HCO3
HOMEOSTASIS
DISTURBED
HOMEOSTASIS
RESTORED
HOMEOSTASIS
Hypoventilation
causing increased PCO2
Plasma pH
returns to normal
Normal
acid–base
balance
Respiratory acidosis
p. 1039
© 2015 Pearson Education, Inc. 27

28. Figure 27-15b Respiratory Acid–Base Regulation
HOMEOSTASIS
HOMEOSTASIS
DISTURBED
HOMEOSTASIS
RESTORED
Normal
acid–base
balance
Hyperventilation
causing decreased PCO2
Plasma pH
returns to normal
Respiratory Alkalosis
Combined Effects
Responses to Alkalosis
Lower PCO2 results
in a rise in plasma pH
Increased PCO2
Respiratory compensation:
Inhibition of arterial and CSF
chemoreceptors results in a decreased
respiratory rate.
Increased H and
decreased HCO3
Renal compensation:
Decreased
PCO2
H ions are generated and HCO3 ions
are secreted.
Buffer systems other than the carbonic
acid–bicarbonate system release H
ions.
Respiratory alkalosis
p. 1039
© 2015 Pearson Education, Inc. 28

29. Figure 27-16a Responses to Metabolic Acidosis
Respiratory compensation:
Stimulation of arterial and CSF chemo-
receptors results in increased
respiratory rate.
Increased
H ions
Renal compensation:
H ions are secreted and HCO3 ions
are generated.
Metabolic Acidosis
Combined Effects
Elevated H results
in a fall in plasma pH
Buffer systems accept H ions.
Decreased H and
increased HCO3
Decreased PCO2
HOMEOSTASIS
DISTURBED
HOMEOSTASIS
HOMEOSTASIS
RESTORED
Normal
acid–base
balance
Increased H production
or decreased H excretion
Plasma pH
returns to normal
Metabolic acidosis can result from increased
acid production or decreased acid excretion,
leading to a buildup of H in body fluids.
p. 1042
© 2015 Pearson Education, Inc. 29

30. Figure 27-16b Responses to Metabolic Acidosis
HOMEOSTASIS
HOMEOSTASIS
DISTURBED
HOMEOSTASIS
RESTORED
Normal
acid–base
balance
Bicarbonate loss;
depletion of bicarbonate
reserve
Plasma pH
returns to normal
Combined Effects
Metabolic Acidosis
Responses to Metabolic Acidosis
Decreased PCO2
Plasma pH falls because
bicarbonate ions are
unavailable to accept H
Respiratory compensation:
Stimulation of arterial and CSF chemo-
receptors results in increased
respiratory rate.
Decreased H and
increased HCO3
Renal compensation:
H ions are secreted and HCO3 ions
are generated.
Decreased
HCO3 ions
Buffer systems other than the carbonic
acid–bicarbonate system accept H
ions.
Metabolic acidosis can result
from a loss of bicarbonate
ions that makes the carbonic
acid–bicarbonate buffer
system incapable of
preventing a fall in pH.
p. 1042
© 2015 Pearson Education, Inc. 30

31. Figure 27-17 Metabolic Alkalosis
HOMEOSTASIS
DISTURBED
HOMEOSTASIS
RESTORED
HOMEOSTASIS
Loss of H;
gain of HCO3
Normal
acid–base
balance
Plasma pH
returns to normal
Metabolic Acidosis
Combined Effects
Elevated HCO3 results
in a rise In plasma pH
Increased H and
decreased HCO3
Responses to Metabolic Alkalosis
Respiratory compensation:
Increased PCO2
Stimulation of arterial and CSF
chemoreceptors results in decreased
respiratory rate.
Decreased
H ions, gain
of HCO3 ions
Renal compensation:
H ions are generated and HCO3
Ions are secreted.
Buffer systems other than the
carbonic acid–bicarbonate system
donate H ions.
p. 1043
© 2015 Pearson Education, Inc. 31

32. © 2012 Pearson Education, Inc.
Copyright © 2009 Pearson Education, Inc., publishing as Pearson Benjamin Cummings
© 2015 Pearson Education, Inc.

33. © 2012 Pearson Education, Inc.
Copyright © 2009 Pearson Education, Inc., publishing as Pearson Benjamin Cummings
© 2015 Pearson Education, Inc.

34. Figure 27-18 The Diagnosis of Acid–Base Disorders (Part 1 of 2).
Suspected Acid–Base Disorder
Check pH
Acidosis
pH <7.35 (acidemia)
Check PCO2
Metabolic Acidosis
Respiratory Acidosis
PCO2 normal or decreased
PCO2 increased (>50 mm Hg)
Primary cause is hypoventilation
Check HCO3–
Acute
Metabolic
Acidosis
Chronic
(compensated)
Metabolic Acidosis
Chronic
(compensated)
Respiratory Acidosis
Acute
Respiratory
Acidosis
PCO2 decreased
(<35 mm Hg)
PCO2 normal
HCO3– increased
(>28 mEq/L)
HCO3– normal
Reduction due to
respiratory
compensation
Examples
• respiratory failure
• CNS damage
• pneumothorax
Examples
• emphysema
• asthma
Check anion gap*
*The anion gap is defined as:
Na+ concentration – (HCO3– concentration + Cl– concentration)
Normal
Increased
Due to loss of HCO3–
or to generation or
ingestion of HCl
Due to generation or retention
of organic or fixed acids
Examples
• lactic acidosis
• ketoacidosis
• chronic renal failure p
Example
• diarrhea

35. Figure 27-18 The Diagnosis of Acid–Base Disorders (Part 2 of 2).
Suspected Acid–Base Disorder
Check pH
Alkalosis
pH >7.45 (alkalemia)
Check PCO2
Metabolic
Alkalosis
Respiratory
Alkalosis
PCO2 increased
(>45 mm Hg)
PCO2 decreased
(<35 mm Hg)
(HCO3– will
be elevated)
Examples
• vomiting
• loss of gastric
acid
Primary
cause is
hyperventilation
Check HCO3–
Acute
Respiratory
Alkalosis
Chronic
(compensated)
Respiratory
Alkalosis
Normal or slight
decrease
in HCO3–
Decreased HCO3–
(<24 mEq/L) p
Examples
• fever
• panic attacks
Examples
• anemia
• CNS damage

36. p. 1025 p. 1044 © 2015 Pearson Education, Inc.
Copyright © 2009 Pearson Education, Inc., publishing as Pearson Benjamin Cummings p