1. Figure 26-1 An Introduction to the Urinary System.
Organs of the
Urinary System
Kidney
Produces urine
Ureter
Transports urine
toward the
urinary bladder
Urinary bladder
Temporarily stores
urine prior
to urination
Urethra
Conducts urine to
exterior; in males,
it also transports
semen
p. 973
Anterior view

2. not in your book © 2012 Pearson Education, Inc.
Copyright © 2009 Pearson Education, Inc., publishing as Pearson Benjamin Cummings
© 2012 Pearson Education, Inc.
© 2015 Pearson Education, Inc.

3. Figure 26-2a The Position of the Kidneys.
Adrenal gland
Diaphragm
11th and
12th ribs
Left kidney
L1 vertebra
Right kidney
Ureter
Renal artery
and vein
Inferior
vena cava
Iliac crest
Aorta
Urinary
bladder
Urethra
p. 974 a
A posterior view of the trunk

4. Figure 26-4a The Structure of the Kidney.
Renal cortex
Renal medulla
Inner layer of
fibrous capsule
Renal pyramid
Renal sinus
Connection to
minor calyx
Adipose tissue
in renal sinus
Minor calyx
Major calyx
Renal pelvis
Hilum
Kidney lobe
Renal papilla
Renal columns
Ureter
Fibrous capsule
p. 976 a
A diagrammatic view of a frontal
section through the left kidney

5. Figure 26-5a The Blood Supply to the Kidneys.
Cortical
radiate
veins
Cortical
radiate
arteries
Interlobar
arteries
Cortex
Segmental
artery
Adrenal
artery
Renal
artery
Renal
vein
Interlobar
veins
Arcuate
veins
Medulla
Arcuate
arteries
p. 977 a
A sectional view, showing major
arteries and veins

6. Figure 26-5b The Blood Supply to the Kidneys.
Glomerulus
Cortical radiate vein
Afferent
arterioles
Cortical radiate artery
Arcuate artery
Arcuate vein
Cortical
nephron
Juxtamedullary
nephron
Renal
pyramid
Interlobar vein
Interlobar artery
Minor calyx
p. 977 b
Circulation in a single kidney lobe

7. Figure 26-5c The Blood Supply to the Kidneys.
Renal vein
Renal artery
Segmental arteries
Interlobar veins
Interlobar arteries
Arcuate veins
Arcuate arteries
Cortical radiate veins
Cortical radiate arteries
Venules
Afferent arterioles
NEPHRONS
Peritubular
capillaries
Glomerulus
Efferent
arteriole
p. 977 c
A flowchart of renal circulation

8. p. 979 The general appearance and location of nephrons in the kidneys
Figure 26-7a The Locations and Structures of Cortical and Juxtamedullary Nephrons.
Cortical
nephron
Juxtamedullary
nephron
Cortex
Medulla
Collecting
duct
Papillary
duct
Renal
papilla
Minor calyx
p. 979 a
The general appearance and location
of nephrons in the kidneys

9. p. 979 © 2012 Pearson Education, Inc. © 2015 Pearson Education, Inc.
Copyright © 2009 Pearson Education, Inc., publishing as Pearson Benjamin Cummings
© 2012 Pearson Education, Inc.
© 2015 Pearson Education, Inc.

10. p. 978 © 2015 Pearson Education, Inc. © 2012 Pearson Education, Inc.
Copyright © 2009 Pearson Education, Inc., publishing as Pearson Benjamin Cummings
© 2012 Pearson Education, Inc.
© 2015 Pearson Education, Inc.

11. Figure 26-6 The Functional Anatomy of a Representative Nephron and the Collecting System (Part 1 of 2).
NEPHRON
Proximal convoluted tubule
Distal convoluted tubule
• Reabsorption of water, ions,
and all organic nutrients
• Secretion of ions, acids, drugs, toxins
• Variable reabsorption of water, sodium ions,
and calcium ions (under hormonal control)
Cuboidal cells
with abundant
microvilli
Cuboidal cells
with few microvilli
Mitochondria
Renal
tubule
Renal corpuscle
• Production of filtrate
Squamous cells
Efferent arteriole
Afferent arteriole
Glomerulus
Glomerular capsule
Descending
limb of
loop begins
Ascending
limb of
loop ends
Capsular space
Nephron loop
Descending limb
Further reabsorption
of water
Thick
ascending
limb
Squamous cells
Ascending limb
Reabsorption of
sodium and
chloride ions
Thin
descending
limb
Low cuboidal cells
KEY
Filtrate
Solute reabsorption
or secretion
p. 978
Water reabsorption
Variable solute
reabsorption or
secretion
Variable water
reabsorption

12. p. 978 COLLECTING SYSTEM Collecting duct
Figure 26-6 The Functional Anatomy of a Representative Nephron and the Collecting System (Part 2 of 2).
COLLECTING SYSTEM
Collecting duct
• Variable reabsorption of water
and reabsorption or secretion of
sodium, potassium, hydrogen,
and bicarbonate ions
Intercalated
cell
Principal cell
KEY
Filtrate
Papillary duct
Water reabsorption
• Delivery of urine to minor calyx
Variable water
reabsorption
Solute reabsorption
or secretion
Minor
calyx
Columnar cells
p. 978
Variable solute
reabsorption or
secretion

13. p. 980 © 2012 Pearson Education, Inc. © 2015 Pearson Education, Inc.
Copyright © 2009 Pearson Education, Inc., publishing as Pearson Benjamin Cummings
© 2012 Pearson Education, Inc.
© 2015 Pearson Education, Inc.

14. Figure 26-8a The Renal Corpuscle.
Glomerular capsule
Capsular
epithelium
Visceral
epithelium
(podocyte)
Glomerular
capillary
Capsular
space
Efferent arteriole
Proximal
convoluted
tubule
Distal convoluted
tubule
Juxtaglomerular
complex
Macula densa
Juxtaglomerular
cells
Afferent arteriole
p. 981 a
Important structural features of a renal corpuscle.

15. Figure 26-8b The Renal Corpuscle.
Podocyte
nucleus
Filtration
membrane
Fenestrated
endothelium
Dense layer
Filtration
slits
Mesangial
cell
Capillary
endothelial
cell
Pores
RBC
Pedicels
Podocyte
Capsular space
Capsular
epithelium b
This cross section through a portion of
the glomerulus shows the components of
the filtration membrane of the nephron.
p. 981

16. Figure 26-6 The Functional Anatomy of a Representative Nephron and the Collecting System (Part 1 of 2).
NEPHRON
Proximal convoluted tubule
Distal convoluted tubule
• Reabsorption of water, ions,
and all organic nutrients
• Secretion of ions, acids, drugs, toxins
• Variable reabsorption of water, sodium ions,
and calcium ions (under hormonal control)
Cuboidal cells
with abundant
microvilli
Cuboidal cells
with few microvilli
Mitochondria
Renal
tubule
Renal corpuscle
• Production of filtrate
Squamous cells
Efferent arteriole
Afferent arteriole
Glomerulus
Glomerular capsule
Descending
limb of
loop begins
Ascending
limb of
loop ends
Capsular space
Nephron loop
Descending limb
Further reabsorption
of water
Thick
ascending
limb
Squamous cells
Ascending limb
Reabsorption of
sodium and
chloride ions
Thin
descending
limb
Low cuboidal cells
KEY
Filtrate
Solute reabsorption
or secretion
p. 978
Water reabsorption
Variable solute
reabsorption or
secretion
Variable water
reabsorption

17. Figure 26-10a Glomerular Filtration.
Glomerulus
Dense
layer
Efferent
arteriole
Capillary
lumen
Afferent
arteriole
Filtration
slit
Podocyte
Pedicels
Pore
Capsular
space
Filtration
membrane
p. 988 a
The glomerular
filtration membrane

18. Figure 26-10b Glomerular Filtration.
Factors Controlling Glomerular Filtration
The glomerular hydrostatic pressure (GHP) is the blood pressure in the glomerular capillaries.
This pressure tends to push water and solute molecules out of the plasma and into the filtrate. The
GHP, which averages 50 mm Hg, is significantly higher than capillary pressures elsewhere in the
systemic circuit, because the efferent arteriole is smaller in diameter than the afferent arteriole.
The blood colloid osmotic pressure
(BCOP) tends to draw water out of the
filtrate and into the plasma; it thus
opposes filtration. Over the entire length
of the glomerular capillary bed, the BCOP averages about 25 mm Hg.
Filtrate in
capsular
space
Plasma
proteins
The net filtration pressure (NFP) is the
net pressure acting across the glomerular
capillaries. It represents the sum of the
hydrostatic pressures and the colloid
osmotic pressures. Under normal
circumstances, the net filtration pressure
is approximately 10 mm Hg. This is the
average pressure forcing water and
dissolved substances out of the glomerular
capillaries and into the capsular space. 50 10 mm Hg 25 15
Solutes
Capsular hydrostatic pressure (CsHP)
opposes GHP. CsHP, which tends to push
water and solutes out of the filtrate and into
the plasma, results from the resistance of
filtrate already present in the nephron that
must be pushed toward the renal pelvis. The
difference between GHP and CsHP is the net
hydrostatic pressure (NHP).
The capsular colloid osmotic pressure
is usually zero because few, if any, plasma
proteins enter the capsular space.
p. 988 b
Net filtration pressure

19. Figure 26-10b Glomerular Filtration
Factors Controlling Glomerular Filtration
Glomerular hydrostatic pressure (GHP)
Blood colloid osmotic pressure (BCOP)
Filtrate in capsular space
Plasma proteins 50
10 mm Hg
Net filtration pressure (NFP) 25 15
Solutes
Capsular hydrostatic pressure (CsHP)
Capsular colloid osmotic pressure
p. 988
Net filtration pressure
© 2015 Pearson Education, Inc. 19

20. Figure 26-12 Transport Activities at the PCT (Part 1 of 2).
Lumen containing
tubular fluid
Cuboidal
epithelial cells
Proximal
convoluted
tubule
Distal
convoluted
tubule
Glomerulus
Glomerular
capsule
Collecting
duct
KEY
Nephron loop
Water reabsorption
Solute reabsorption
p. 993
Variable solute reabsorption
or secretion
Urine storage
and elimination

21. Figure 26-12 Transport Activities at the PCT (Part 2 of 2).
Tubular fluid
Cells of
proximal
convoluted
tubule
Glucose
and other
organic
solutes
Osmotic
water
flow
p. 988
Peritubular
fluid
KEY
Peritubular
capillary
Leak channel
Diffusion
Countertransport
Reabsorption
Exchange pump
Cotransport
Secretion

22. Figure 26-13a Countercurrent Multiplication and Urine Concentration (Part 2 of 2).
Tubular fluid
Urea
Cells of
thick
ascending
limb
This plasma
membrane is
impermeable
to water
p. 995
Loop of Henle
KEY
Cotransport
Exchange pump
Reabsorption
Peritubular
fluid
Secretion
Diffusion a
The mechanism of sodium and chloride ion transport involves the
Na+–K+/2 Cl– carrier at the apical surface and two carriers at the
basal surface of the tubular cell: a potassium–chloride cotransport
pump and a sodium–potassium exchange pump. The net result is
the transport of sodium and chloride ions into the peritubular fluid.

23. Figure 26-13b Countercurrent Multiplication and Urine Concentration.
Thin
descending
limb
(permeable
to water;
impermeable
to solutes)
Thick
ascending limb
(impermeable
to water;
active solute
transport)
KEY
Impermeable to water
Impermeable to solutes
Impermeable to urea;
variable permeability to water
Permeable to urea
Renal medulla
p. 995 b
Transport of NaCl along the ascending thick limb results
in the movement of water from the descending limb.

24. Figure 26-13c Countercurrent Multiplication and Urine Concentration.
Renal
cortex
DCT and
collecting
ducts
(impermeable
to urea;
variable
permeability
to water)
Thin descending
limb (permeable
to water;
Impermeable
to urea)
KEY
Impermeable to water
Papillary duct
(permeable to
urea)
Impermeable to solutes
Impermeable to urea;
variable permeability to water
Permeable to urea
Na+
Cl–
Renal medulla
Urea c
The permeability characteristics of both the loop and the collecting
duct tend to concentrate urea in the tubular fluid and in the medulla.
The nephron loop, DCT, and collecting duct are impermeable to
urea. As water reabsorption occurs, the urea concentration
increases. Papillary duct permeability to urea makes up nearly
one-third of the solutes in the deepest portions of the medulla.
p. 995

25. Figure 26-8a The Renal Corpuscle.
Glomerular capsule
Capsular
epithelium
Visceral
epithelium
(podocyte)
Glomerular
capillary
Capsular
space
Efferent arteriole
Proximal
convoluted
tubule
Distal convoluted
tubule
Juxtaglomerular
complex
Macula densa
Juxtaglomerular
cells
Afferent arteriole
p. 988 a
Important structural features of a renal corpuscle.

26. Figure 26-14ab Tubular Secretion and Solute Reabsorption by the DCT.
Sodium and chloride
reabsorption along entire
length of DCT
Sodium–potassium exchange in
aldosterone-sensitive portion of DCT
and collecting duct
Distal
convoluted
tubule
Tubular fluid
Tubular fluid
Glomerulus
Glomerular
capsule
Cells of
distal
convoluted
tubule
Collecting
duct
Proximal
convoluted
tubule
Sodium ions are
reabsorbed in
exchange for
potassium ions when
these ion pumps are
stimulated by
aldosterone (A).
Nephron
loop
Urine storage
and elimination
Peritubular
fluid
Peritubular
capillary
KEY
Leak channel
Cotransport
Countertransport
Diffusion
Exchange pump
Reabsorption
Aldosterone-
regulated pump
Secretion
p. 998 DCT a
The basic pattern of the
reabsorption of sodium and
chloride ions and the secretion
of potassium ions. b
Aldosterone-regulated reabsorption
of sodium ions, linked to the passive
loss of potassium ions.

27. p. 998 DCT © 2012 Pearson Education, Inc.
Copyright © 2009 Pearson Education, Inc., publishing as Pearson Benjamin Cummings
© 2012 Pearson Education, Inc.
© 2015 Pearson Education, Inc.

28. p. 998 DCT © 2012 Pearson Education, Inc.
Copyright © 2009 Pearson Education, Inc., publishing as Pearson Benjamin Cummings
© 2012 Pearson Education, Inc.
© 2015 Pearson Education, Inc.

29. Figure 26-14c Tubular Secretion and Solute Reabsorption by the DCT.
H+ secretion and HCO3– reabsorption along entire DCT and
collecting duct
Distal
convoluted
tubule
Tubular fluid
Hydrochloric
acid
Ammonium
chloride
Glomerulus
Glomerular
capsule
Collecting
duct
Proximal
convoluted
tubule
Amino acid
deamination
Nephron
loop
Urine storage
and elimination
KEY
Leak channel
Cotransport
Countertransport
Diffusion
Sodium bicarbonate
Exchange pump
Reabsorption
Aldosterone-
regulated pump
Secretion
p. 999 DCT & CD c
Hydrogen ion secretion and the acidification of urine occur by two
routes. The central theme is the exchange of hydrogen ions in the
cytosol for sodium ions in the tubular fluid, and the reabsorption of
the bicarbonate ions generated in the process.

30. p. 1000 Tubule permeabilities and the osmotic concentration of urine
Figure 26-15a The Effects of ADH on the DCT and Collecting Duct (Part 2 of 2).
Renal cortex
PCT
DCT
Glomerulus
KEY
= Na+/Cl–
transport
= Antidiuretic
hormone
= Water
reabsorption
= Variable water
reabsorption
Solutes
= Impermeable
to solutes
= Impermeable
to water
Renal medulla
Collecting
duct
= Variable permeability
to water a
Tubule permeabilities and the
osmotic concentration of urine
without ADH
Large volume
of dilute urine
p. 1000

31. p. 1000 Tubule permeabilities and the osmotic
Figure 26-15b The Effects of ADH on the DCT and Collecting Duct (Part 2 of 2).
Renal cortex
KEY
= Na+/Cl–
transport
= Antidiuretic
hormone
= Water
reabsorption
= Variable water
reabsorption
= Impermeable
to solutes
= Impermeable
to water
Renal medulla
= Variable permeability
to water b
Tubule permeabilities and the osmotic
concentration of urine with ADH
Small volume of
concentrated urine
p. 1000

32. Figure 26-13c Countercurrent Multiplication and Urine Concentration.
Renal
cortex
DCT and
collecting
ducts
(impermeable
to urea;
variable
permeability
to water)
Thin descending
limb (permeable
to water;
Impermeable
to urea)
KEY
Impermeable to water
Papillary duct
(permeable to
urea)
Impermeable to solutes
Impermeable to urea;
variable permeability to water
Permeable to urea
Na+
Cl–
Renal medulla
Urea c
The permeability characteristics of both the loop and the collecting
duct tend to concentrate urea in the tubular fluid and in the medulla.
The nephron loop, DCT, and collecting duct are impermeable to
urea. As water reabsorption occurs, the urea concentration
increases. Papillary duct permeability to urea makes up nearly
one-third of the solutes in the deepest portions of the medulla.
p. 995 CD

33. Figure 26-11 The Response to a Reduction in the GFR (Part 2 of 2).
Autoregulation
Immediate local
response in the
kidney
HOMEOSTASIS
RESTORED
Increased
glomerular
blood pressure
if sufficient
Normal
GFR
Dilation of
afferent arterioles
HOMEOSTASIS
DISTURBED
HOMEOSTASIS
Normal
glomerular
filtration rate
Contraction of
mesangial cells
Decreased GFR
resulting in
decreased filtrate
and urine
production
Start
Constriction of
efferent arterioles
p. 991

34. Figure 26-11 The Response to a Reduction in the GFR (Part 1 of 2).
Renin–Angiotensin-Aldosterone System
Integrated endocrine and
neural mechanisms activated
Renin in the bloodstream
triggers formation of
angiotensin I, which is then
activated to angiotensin II
by angiotensin converting
enzyme (ACE) in the
capillaries of the lungs
Endocrine
response
Juxtaglomerular
complex increases
production of renin
Angiotensin II triggers
increased aldosterone
secretion by the
adrenal glands
Angiotensin II
triggers
neural
responses
Angiotensin II constricts
peripheral arterioles and
further constricts the
efferent arterioles
Aldosterone
increases
Na+ retention
HOMEOSTASIS
RESTORED
Increased
stimulation of
thirst centers
Increased
systemic
blood
pressure
Increased fluid
consumption
Increased
glomerular
pressure
Increased
blood
volume
Increased fluid
retention
Increased ADH
production
Constriction of
venous reservoirs
Increased
cardiac output
Increased
sympathetic
motor tone
Together, angiotensin II
and sympathetic activation
stimulate peripheral
vasoconstriction
HOMEOSTASIS
Normal
glomerular
filtration rate
p. 991

35. Figure 26-16 Summary of Renal Function (Part 1 of 6).

36. Figure 26-16 Summary of Renal Function (Part 2 of 6).