1. The Urinary System: Part B25
The Urinary System: Part B

2. Most of tubular contents reabsorbed to blood
Tubular Reabsorption
Most of tubular contents reabsorbed to blood
Selective transepithelial process
~ All organic nutrients reabsorbed
Water and ion reabsorption hormonally regulated and adjusted
Includes active and passive tubular reabsorption
Two routes
Transcellular or paracellular
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3. Tubular Reabsorption Transcellular route
Apical membrane of tubule cells 
Cytosol of tubule cells 
Basolateral membranes of tubule cells 
Endothelium of peritubular capillaries
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4. Tubular Reabsorption Paracellular route Between tubule cells
Limited by tight junctions, but leaky in proximal nephron
Water, Ca2+, Mg2+, K+, and some Na+ in the PCT
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5. Tubule cell Peri- tubular capillary
Figure Transcellular and paracellular routes of tubular reabsorption.
Slide 1
Transport across the basolateral membrane. (Often involves the lateral intercellular spaces because membrane transporters transport ions into these spaces.)
The paracellular route
involves:
The transcellular route
involves: 3
• Movement through leaky
tight junctions, particularly in
the PCT.
• Movement through the inter-
stitial fluid and into the
capillary.
Transport across the apical membrane. 1
Diffusion through the cytosol. 2
Movement through the inter-
stitial fluid and into the capillary. 4
Filtrate
in tubule
lumen
Tubule cell
Interstitial fluid
Peri-
tubular
capillary
Tight junction
Lateral
intercellular
space 3 4 1 2 3 4
H2O and
solutes
Transcellular
route
Capillary
endothelial
cell
Apical
membrane
Paracellular route
H2O and
solutes
Basolateral
membranes
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6. Tubule cell Peri- tubular capillary
Figure Transcellular and paracellular routes of tubular reabsorption.
Slide 2
The transcellular route
involves:
Transport across the apical membrane. 1
Filtrate
in tubule
lumen
Tubule cell
Interstitial fluid
Peri-
tubular
capillary
Tight junction
Lateral
intercellular
space 1
H2O and
solutes
Transcellular
route
Capillary
endothelial
cell
Apical
membrane
H2O and
solutes
Basolateral
membranes
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7. Tubule cell Peri- tubular capillary
Figure Transcellular and paracellular routes of tubular reabsorption.
Slide 3
The transcellular route
involves:
Transport across the apical membrane. 1
Diffusion through the cytosol. 2
Filtrate
in tubule
lumen
Tubule cell
Interstitial fluid
Peri-
tubular
capillary
Tight junction
Lateral
intercellular
space 1 2
H2O and
solutes
Transcellular
route
Capillary
endothelial
cell
Apical
membrane
H2O and
solutes
Basolateral
membranes
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8. Tubule cell Peri- tubular capillary
Figure Transcellular and paracellular routes of tubular reabsorption.
Slide 4
The transcellular route
involves:
Transport across the basolateral membrane. (Often involves the lateral intercellular spaces because membrane transporters transport ions into these spaces.) 3
Transport across the apical membrane. 1
Diffusion through the cytosol. 2
Filtrate
in tubule
lumen
Tubule cell
Interstitial fluid
Peri-
tubular
capillary
Tight junction
Lateral
intercellular
space 3 1 2 3
H2O and
solutes
Transcellular
route
Capillary
endothelial
cell
Apical
membrane
H2O and
solutes
Basolateral
membranes
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9. Tubule cell Peri- tubular capillary
Figure Transcellular and paracellular routes of tubular reabsorption.
Slide 5
The transcellular route
involves:
Transport across the basolateral membrane. (Often involves the lateral intercellular spaces because membrane transporters transport ions into these spaces.) 3
Transport across the apical membrane. 1
Diffusion through the cytosol. 2
Movement through the inter-
stitial fluid and into the capillary. 4
Filtrate
in tubule
lumen
Tubule cell
Interstitial fluid
Peri-
tubular
capillary
Tight junction
Lateral
intercellular
space 3 4 1 2 3 4
H2O and
solutes
Transcellular
route
Capillary
endothelial
cell
Apical
membrane
H2O and
solutes
Basolateral
membranes
© 2013 Pearson Education, Inc.

10. Tubule cell Peri- tubular capillary
Figure Transcellular and paracellular routes of tubular reabsorption.
Slide 6
The paracellular route
involves:
The transcellular route
involves:
Transport across the basolateral membrane. (Often involves the lateral intercellular spaces because membrane transporters transport ions into these spaces.) 3
• Movement through leaky
tight junctions, particularly in
the PCT.
• Movement through the inter-
stitial fluid and into the
capillary.
Transport across the apical membrane. 1
Diffusion through the cytosol. 2
Movement through the inter-
stitial fluid and into the capillary. 4
Filtrate
in tubule
lumen
Tubule cell
Interstitial fluid
Peri-
tubular
capillary
Tight junction
Lateral
intercellular
space 3 4 1 2 3 4
H2O and
solutes
Transcellular
route
Capillary
endothelial
cell
Apical
membrane
Paracellular route
H2O and
solutes
Basolateral
membranes
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11. Tubular Reabsorption of Sodium
Na+ - most abundant cation in filtrate
Transport across basolateral membrane
Primary active transport out of tubule cell by Na+-K+ ATPase pump  peritubular capillaries
Transport across apical membrane
Na+ passes through apical membrane by secondary active transport or facilitated diffusion mechanisms
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12. Reabsorption of Nutrients, Water, and Ions
Na+ reabsorption by primary active transport provides energy and means for reabsorbing most other substances
Creates electrical gradient  passive reabsorption of anions
Organic nutrients reabsorbed by secondary active transport; cotransported with Na+
Glucose, amino acids, some ions, vitamins
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13. Passive Tubular Reabsorption of Water
Movement of Na+ and other solutes creates osmotic gradient for water
Water reabsorbed by osmosis, aided by water-filled pores called aquaporins
Aquaporins always present in PCT  obligatory water reabsorption
Aquaporins inserted in collecting ducts only if ADH present  facultative water reabsorption
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14. Passive Tubular Reabsorption of Solutes
Solute concentration in filtrate increases as water reabsorbed  concentration gradients for solutes 
Fat-soluble substances, some ions and urea, follow water into peritubular capillaries down concentration gradients
 Lipid-soluble drugs, environmental pollutants difficult to excrete
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15. Figure 25.14 Reabsorption by PCT cells.
Slide 1
At the basolateral membrane, Na+ is pumped into the interstitial space by the Na+-K+ ATPase. Active Na+ transport
creates concentration gradients that drive: 1 2
“Downhill” Na+ entry at the
apical membrane.
Reabsorption of organic nutrients and certain ions by cotransport at the apical membrane. 3
Filtrate
in tubule
lumen
Nucleus
Interstitial
fluid
Peri-
tubular
capillary
Tubule cell 4
Reabsorption of water by osmosis through
aquaporins. Water reabsorption increases the concentration of the
solutes that are left behind. These solutes can then be reabsorbed as they move down their gradients: 2
Glucose
Amino
acids
Some
ions
Vitamins 1 3 4 5
Lipid-soluble substances diffuse by the transcellular route.
Lipid-
soluble
substances 5
Various
Ions
and urea 6 6
Various ions (e.g., Cl−, Ca2+, K+) and urea diffuse by the paracellular route.
Tight junction
Paracellular
route
Primary active transport
Transport protein
Secondary active transport
Ion channel
Passive transport (diffusion)
Aquaporin
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16. Figure 25.14 Reabsorption by PCT cells.
Slide 2
At the basolateral membrane, Na+ is pumped into the interstitial space by the Na+-K+ ATPase. Active Na+ transport
creates concentration gradients that drive: 1
Filtrate
in tubule
lumen
Nucleus
Interstitial
fluid
Peri-
tubular
capillary
Tubule cell
Glucose
Amino
acids
Some
ions
Vitamins 1
Lipid-
soluble
substances
Various
Ions
and urea
Tight junction
Paracellular
route
Primary active transport
Transport protein
Secondary active transport
Ion channel
Passive transport (diffusion)
Aquaporin
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17. Figure 25.14 Reabsorption by PCT cells.
Slide 3
At the basolateral membrane, Na+ is pumped into the interstitial space by the Na+-K+ ATPase. Active Na+ transport
creates concentration gradients that drive: 1 2
“Downhill” Na+ entry at the
apical membrane.
Filtrate
in tubule
lumen
Nucleus
Interstitial
fluid
Peri-
tubular
capillary
Tubule cell 2
Glucose
Amino
acids
Some
ions
Vitamins 1
Lipid-
soluble
substances
Various
Ions
and urea
Tight junction
Paracellular
route
Primary active transport
Transport protein
Secondary active transport
Ion channel
Passive transport (diffusion)
Aquaporin
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18. Figure 25.14 Reabsorption by PCT cells.
Slide 4
At the basolateral membrane, Na+ is pumped into the interstitial space by the Na+-K+ ATPase. Active Na+ transport
creates concentration gradients that drive: 1 2
“Downhill” Na+ entry at the
apical membrane.
Reabsorption of organic nutrients and certain ions by cotransport at the apical membrane. 3
Filtrate
in tubule
lumen
Nucleus
Interstitial
fluid
Peri-
tubular
capillary
Tubule cell 2
Glucose
Amino
acids
Some
ions
Vitamins 1 3
Lipid-
soluble
substances
Various
Ions
and urea
Tight junction
Paracellular
route
Primary active transport
Transport protein
Secondary active transport
Ion channel
Passive transport (diffusion)
Aquaporin
© 2013 Pearson Education, Inc.

19. Figure 25.14 Reabsorption by PCT cells.
Slide 5
At the basolateral membrane, Na+ is pumped into the interstitial space by the Na+-K+ ATPase. Active Na+ transport
creates concentration gradients that drive: 1
“Downhill” Na+ entry at the
apical membrane. 2
Reabsorption of organic nutrients and certain ions by cotransport at the apical membrane. 3
Filtrate
in tubule
lumen
Nucleus
Interstitial
fluid
Peri-
tubular
capillary
Tubule cell 4
Reabsorption of water by osmosis through
aquaporins. Water reabsorption increases the concentration of the
solutes that are left behind. These solutes can then be reabsorbed as they move down their gradients: 2
Glucose
Amino
acids
Some
ions
Vitamins 1 3 4
Lipid-
soluble
substances
Various
Ions
and urea
Tight junction
Paracellular
route
Primary active transport
Transport protein
Secondary active transport
Ion channel
Passive transport (diffusion)
Aquaporin
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20. Figure 25.14 Reabsorption by PCT cells.
Slide 6
At the basolateral membrane, Na+ is pumped into the interstitial space by the Na+-K+ ATPase. Active Na+ transport
creates concentration gradients that drive: 1
“Downhill” Na+ entry at the
apical membrane. 2
Reabsorption of organic nutrients and certain ions by cotransport at the apical membrane. 3
Filtrate
in tubule
lumen
Nucleus
Interstitial
fluid
Peri-
tubular
capillary
Tubule cell 4
Reabsorption of water by osmosis through
aquaporins. Water reabsorption increases the concentration of the
solutes that are left behind. These solutes can then be reabsorbed as they move down their gradients: 2
Glucose
Amino
acids
Some
ions
Vitamins 1 3 4 5
Lipid-soluble substances diffuse by the transcellular route.
Lipid-
soluble
substances 5
Various
Ions
and urea
Tight junction
Paracellular
route
Primary active transport
Transport protein
Secondary active transport
Ion channel
Passive transport (diffusion)
Aquaporin
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21. Figure 25.14 Reabsorption by PCT cells.
Slide 7
At the basolateral membrane, Na+ is pumped into the interstitial space by the Na+-K+ ATPase. Active Na+ transport
creates concentration gradients that drive: 1
“Downhill” Na+ entry at the
apical membrane. 2
Reabsorption of organic nutrients and certain ions by cotransport at the apical membrane. 3
Filtrate
in tubule
lumen
Nucleus
Interstitial
fluid
Peri-
tubular
capillary
Tubule cell 4
Reabsorption of water by osmosis through
aquaporins. Water reabsorption increases the concentration of the
solutes that are left behind. These solutes can then be reabsorbed as they move down their gradients: 2
Glucose
Amino
acids
Some
ions
Vitamins 1 3 4 5
Lipid-soluble substances diffuse by the transcellular route.
Lipid-
soluble
substances 5
Various
Ions
and urea 6 6
Various ions (e.g., Cl−, Ca2+, K+) and urea diffuse by the paracellular route.
Tight junction
Paracellular
route
Primary active transport
Transport protein
Secondary active transport
Ion channel
Passive transport (diffusion)
Aquaporin
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22. Transcellular transport systems specific and limited
Transport Maximum
Transcellular transport systems specific and limited
Transport maximum (Tm) for ~ every reabsorbed substance; reflects number of carriers in renal tubules available
When carriers saturated, excess excreted in urine
E.g., hyperglycemia  high blood glucose levels exceed Tm  glucose in urine
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23. Reabsorptive Capabilities of Renal Tubules and Collecting Ducts
PCT
Site of most reabsorption
All nutrients, e.g., glucose and amino acids
65% of Na+ and water
Many ions
~ All uric acid; ½ urea (later secreted back into filtrate)
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24. Reabsorptive Capabilities of Renal Tubules and Collecting Ducts
Nephron loop
Descending limb - H2O can leave; solutes cannot
Ascending limb – H2O cannot leave; solutes can
Thin segment – passive Na+ movement
Thick segment – Na+-K+-2Cl- symporter and Na+-H+ antiporter; some passes by paracellular route
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25. Reabsorptive Capabilities of Renal Tubules and Collecting Ducts
DCT and collecting duct
Reabsorption hormonally regulated
Antidiuretic hormone (ADH) – Water
Aldosterone – Na+ (therefore water)
Atrial natriuretic peptide (ANP) – Na+
PTH – Ca2+
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26. Reabsorptive Capabilities of Renal Tubules and Collecting Ducts
Antidiuretic hormone (ADH)
Released by posterior pituitary gland
Causes principal cells of collecting ducts to insert aquaporins in apical membranes  water reabsorption
As ADH levels increase  increased water reabsorption
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27. Reabsorptive Capabilities of Renal Tubules and Collecting Ducts
Aldosterone
Targets collecting ducts (principal cells) and distal DCT
Promotes synthesis of luminal Na+ and K+ channels, and basolateral Na+-K+ ATPases for Na+ reabsorption; water follows
 little Na+ leaves body; aldosterone absence  loss of 2% filtered Na+ daily - incompatible with life
Functions – increase blood pressure; decrease K+ levels
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28. Reabsorptive Capabilities of Renal Tubules and Collecting Ducts
Atrial natriuretic peptide
Reduces blood Na+  decreased blood volume and blood pressure
Released by cardiac atrial cells if blood volume or pressure elevated
Parathyroid hormone acts on DCT to increase Ca2+ reabsorption
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29. Reabsorption in reverse; almost all in PCT
Tubular Secretion
Reabsorption in reverse; almost all in PCT
Selected substances
K+, H+, NH4+, creatinine, organic acids and bases move from peritubular capillaries through tubule cells into filtrate
Substances synthesized in tubule cells also secreted – e.g., HCO3-
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30. Disposes of substances (e.g., drugs) bound to plasma proteins
Tubular Secretion
Disposes of substances (e.g., drugs) bound to plasma proteins
Eliminates undesirable substances passively reabsorbed (e.g., urea and uric acid)
Rids body of excess K+ (aldosterone effect)
Controls blood pH by altering amounts of H+ or HCO3– in urine
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31. Figure 25.15 Summary of tubular reabsorption and secretion.
Cortex
65% of filtrate volume
reabsorbed
• H2O
• Na+, HCO3−, and
many other ions
• Glucose, amino acids,
and other nutrients
Regulated reabsorption
• Na+ (by aldosterone;
Cl− follows)
• Ca2+ (by parathyroid
hormone)
• H+ and NH4+
• Some drugs
Regulated
secretion
• K+ (by
aldosterone)
Outer
medulla
Regulated
reabsorption
• H2O (by ADH)
• Na+ (by
aldosterone; Cl−
follows)
• Urea (increased
by ADH)
• Urea
Regulated
secretion
• K+ (by
aldosterone)
Inner
medulla
• Reabsorption or secretion
to maintain blood pH
described in Chapter 26;
involves H+, HCO3−,
and NH4+
Reabsorption
Secretion
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32. Regulation of Urine Concentration and Volume
Osmolality
Number of solute particles in 1 kg of H2O
Reflects ability to cause osmosis
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33. Regulation of Urine Concentration and Volume
Osmolality of body fluids
Expressed in milliosmols (mOsm)
Kidneys maintain osmolality of plasma at ~300 mOsm by regulating urine concentration and volume
Kidneys regulate with countercurrent mechanism
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34. Countercurrent Mechanism
Occurs when fluid flows in opposite directions in two adjacent segments of same tube with hair pin turn
Countercurrent multiplier – interaction of filtrate flow in ascending/descending limbs of nephron loops of juxtamedullary nephrons
Countercurrent exchanger - Blood flow in ascending/descending limbs of vasa recta
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35. Countercurrent Mechanism
Role of countercurrent mechanisms
Establish and maintain osmotic gradient (300 mOsm to 1200 mOsm) from renal cortex through medulla
Allow kidneys to vary urine concentration
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36. The three key players and their orientation in the osmotic gradient:
Figure 25.16a Juxtamedullary nephrons create an osmotic gradient within the renal medulla that allows the kidney to produce urine of varying concentration. (1 of 4)
The three key players and their
orientation in the osmotic gradient:
(c) The collecting ducts of
all nephrons use the gradient
to adjust urine osmolality.
300
300
400
(a) The long nephron loops of
juxtamedullary nephrons create
the gradient. They act as
countercurrent multipliers.
600
The osmolality of the medullary
interstitial fluid progressively
increases from the 300 mOsm of
normal body fluid to 1200 mOsm
at the deepest part of the medulla.
900
(b) The vasa recta preserve the
gradient. They act as
countercurrent exchangers.
1200
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37. Countercurrent Multiplier: Loop of Henle
Descending limb
Freely permeable to H2O
H2O passes out of filtrate into hyperosmotic medullary interstitial fluid
Filtrate osmolality increases to ~1200 mOsm
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38. Countercurrent Multiplier: Loop of Henle
Ascending limb
Impermeable to H2O
Selectively permeable to solutes
Na+ and Cl– actively reabsorbed in thick segment; some passively reabsorbed in thin segment
Filtrate osmolality decreases to 100 mOsm
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39. The Countercurrent Multiplier
Constant 200 mOsm difference between two limbs of nephron loop and between ascending limb and interstitial fluid
Difference "multiplied" along length of loop to ~ 900 mOsm
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40. The Countercurrent Exchanger
Vasa recta
Preserve medullary gradient
Prevent rapid removal of salt from interstitial space
Remove reabsorbed water
Water entering ascending vasa recta either from descending vasa recta or reabsorbed from nephron loop and collecting duct 
Volume of blood at end of vasa recta greater than at beginning
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41. Long nephron loops of juxtamedullary nephrons create the gradient.
Figure 25.16a Juxtamedullary nephrons create an osmotic gradient within the renal medulla that allows the kidney to produce urine of varying concentration. (2 of 4)
Long nephron loops of juxtamedullary nephrons create the gradient.
The countercurrent multiplier depends on three properties
of the nephron loop to establish the osmotic gradient.
Fluid flows in the
opposite direction
(countercurrent)
through two
adjacent parallel
sections of a
nephron loop.
The descending
limb is permeable
to water, but not
to salt.
The ascending limb
is impermeable to
water, and pumps
out salt.
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42. Long nephron loops of juxtamedullary nephrons create the gradient.
Figure 25.16a Juxtamedullary nephrons create an osmotic gradient within the renal medulla that allows the kidney to produce urine of varying concentration. (3 of 4)
Long nephron loops of juxtamedullary nephrons create the gradient.
These properties establish a positive feedback cycle that
uses the flow of fluid to multiply the power of the salt pumps.
Interstitial fluid
osmolality
Start
here
Water leaves the
descending limb
Salt is pumped out
of the ascending limb
Osmolality of filtrate
in descending limb
Osmolality of filtrate
entering the ascending
limb
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43. Osmolality of interstitial fluid (mOsm)
Figure 25.16a Juxtamedullary nephrons create an osmotic gradient within the renal medulla that allows the kidney to produce urine of varying concentration. (4 of 4)
(continued) As water and solutes are reabsorbed, the loop first concentrates the filtrate, then dilutes it.
Active transport
Passive transport
Water impermeable
300
300
100
Cortex
100
300
300
Filtrate entering the nephron loop is isosmotic to both blood plasma and cortical interstitial fluid. 1 5
Filtrate is at its most dilute as it leaves the nephron loop. At
100 mOsm, it is hypo-osmotic to the interstitial fluid.
400
400
200
Na+ and Cl- are pumped out of the filtrate. This increases the interstitial fluid osmolality. 4
Outer
medulla
Osmolality of interstitial fluid (mOsm)
600
600
400
Water moves out of the filtrate in the descending limb down its osmotic gradient. This concentrates the filtrate. 2
900
900
700
Filtrate reaches its highest concentration at the bend of the loop. 3
Inner
medulla
Nephron loop
1200
1200
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44. Vasa recta preserve the gradient.
Figure 25.16b Juxtamedullary nephrons create an osmotic gradient within the renal medulla that allows the kidney to produce urine of varying concentration.
Vasa recta preserve the gradient.
The entire length of the vasa recta is highly permeable to water
and solutes. Due to countercurrent exchanges between each
section of the vasa recta and its surrounding interstitial fluid, the
blood within the vasa recta remains nearly isosmotic to the
surrounding fluid. As a result, the vasa recta do not undo the
osmotic gradient as they remove reabsorbed water and solutes.
Blood from
efferent
arteriole
To vein
300
325
300
400
The countercurrent
flow of fluid moves
through two adjacent
parallel sections of
the vasa recta.
400
600
600
900
900
1200
Vasa recta
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45. Osmolality of interstitial fluid (mOsm)
Figure 25.16c Juxtamedullary nephrons create an osmotic gradient within the renal medulla that allows the kidney to produce urine of varying concentration.
Collecting ducts use the gradient.
Under the control of antidiuretic hormone, the collecting
ducts determine the final concentration and volume of
urine. This process is fully described in Figure
Collecting duct
300
400
Osmolality of interstitial fluid (mOsm)
600
900
1200
Urine
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46. Formation of Dilute or Concentrated Urine
Osmotic gradient used to raise urine concentration > 300 mOsm to conserve water
Overhydration  large volume dilute urine
ADH production ; urine ~ 100 mOsm
If aldosterone present, additional ions removed  ~ 50 mOsm
Dehydration  small volume concentrated urine
ADH released; urine ~ 1200 mOsm
Severe dehydration – 99% water reabsorbed
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47. Figure 25.17 Mechanism for forming dilute or concentrated urine.
If we were so overhydrated we had no ADH...
If we were so dehydrated we had maximal ADH...
Osmolality of extracellular fluids
Osmolality of extracellular fluids
ADH release from posterior pituitary
ADH release from posterior pituitary
Number of aquaporins (H2O channels) in collecting duct
Number of aquaporins (H2O channels) in collecting duct
H2O reabsorption from collecting duct
H2O reabsorption from collecting duct
Large volume of dilute urine
Small volume of concentrated urine
Collecting
duct
Collecting duct
Descending limb
of nephron loop
300
Descending limb
of nephron loop
300
100
100
150
DCT
100
DCT
300
Cortex
Cortex
300
100
300
300
100
300
300
400
600
400
Osmolality of interstitial fluid (mOsm)
600
600
400
Osmolality of interstitial fluid (mOsm)
600
600
100
Outer
medulla
Outer
medulla
Urea
900
700
900
900
700
900
900
Urea
Urea
Inner
medulla
Inner
medulla
1200
100
1200
1200
1200
1200
Large volume
of dilute urine
Small volume of
concentrated urine
Urea contributes to
the osmotic gradient. ADH increases its recycling.
Active transport
Passive transport
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48. Urea Recycling and the Medullary Osmotic Gradient
Urea helps form medullary gradient
Enters filtrate in ascending thin limb of nephron loop by facilitated diffusion
Cortical collecting duct reabsorbs water; leaves urea
In deep medullary region now highly concentrated urea  interstitial fluid of medulla  back to ascending thin limb  high osmolality in medulla
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49. Chemicals that enhance urinary output
Diuretics
Chemicals that enhance urinary output
ADH inhibitors, e.g., alcohol
Na+ reabsorption inhibitors (and resultant H2O reabsorption), e.g., caffeine, drugs for hypertension or edema
Loop diuretics inhibit medullary gradient formation
Osmotic diuretics - substance not reabsorbed so water remains in urine, e.g., high glucose of diabetic patient
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50. Clinical Evaluation of Kidney Function
Urine examined for signs of disease
Assessing renal function requires both blood and urine examination
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51. Volume of plasma kidneys clear of particular substance in given time
Renal Clearance
Volume of plasma kidneys clear of particular substance in given time
Renal clearance tests used to determine GFR
To detect glomerular damage
To follow progress of renal disease
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52. Renal Clearance C = UV/P C = renal clearance rate (ml/min)
U = concentration (mg/ml) of substance in urine
V = flow rate of urine formation (ml/min)
P = concentration of same substance in plasma
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53. Renal Clearance Inulin (plant polysaccharide) is standard used
Freely filtered; neither reabsorbed nor secreted by kidneys; its renal clearance = GFR = 125 ml/min
If C < 125 ml/min, substance reabsorbed
If C = 0, substance completely reabsorbed, or not filtered
If C = 125 ml/min, no net reabsorption or secretion
If C > 125 ml/min, substance secreted (most drug metabolites)
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54. Homeostatic Imbalance
Chronic renal disease - GFR < 60 ml/min for 3 months
E.g., in diabetes mellitus; hypertension
Renal failure – GFR < 15 ml/min
Causes uremia syndrome – ionic and hormonal imbalances; metabolic abnormalities; toxic molecule accumulation
Treated with hemodialysis or transplant
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55. Physical Characteristics of Urine
Color and transparency
Clear
Cloudy may indicate urinary tract infection
Pale to deep yellow from urochrome
Pigment from hemoglobin breakdown; more concentrated urine  deeper color
Abnormal color (pink, brown, smoky)
Food ingestion, bile pigments, blood, drugs
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56. Physical Characteristics of Urine
Odor
Slightly aromatic when fresh
Develops ammonia odor upon standing
As bacteria metabolize solutes
May be altered by some drugs and vegetables
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57. Physical Characteristics of Urine
Slightly acidic (~pH 6, with range of 4.5 to 8.0)
Acidic diet (protein, whole wheat)   pH
Alkaline diet (vegetarian), prolonged vomiting, or urinary tract infections  pH
Specific gravity
1.001 to 1.035; dependent on solute concentration
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58. Chemical Composition of Urine
95% water and 5% solutes
Nitrogenous wastes
Urea (from amino acid breakdown) – largest solute component
Uric acid (from nucleic acid metabolism)
Creatinine (metabolite of creatine phosphate)
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59. Chemical Composition of Urine
Other normal solutes
Na+, K+, PO43–, and SO42–, Ca2+, Mg2+ and HCO3–
Abnormally high concentrations of any constituent, or abnormal components, e.g., blood proteins, WBCs, bile pigments, may indicate pathology
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60. Urine transport, Storage, and Elimination: Ureters
Convey urine from kidneys to bladder
Begin at L2 as continuation of renal pelvis
Retroperitoneal
Enter base of bladder through posterior wall
As bladder pressure increases, distal ends of ureters close, preventing backflow of urine
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61. Three layers of ureter wall from inside out
Ureters
Three layers of ureter wall from inside out
Mucosa - transitional epithelium
Muscularis – smooth muscle sheets
Contracts in response to stretch
Propels urine into bladder
Adventitia – outer fibrous connective tissue
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62. Figure 25.19 Cross-sectional view of the ureter wall (10x).
Lumen
Mucosa
• Transitional
epithelium
• Lamina
propria
Muscularis
• Longitudinal
Layer
• Circular
layer
Adventitia
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63. Homeostatic Imbalance
Renal calculi - kidney stones in renal pelvis
Crystallized calcium, magnesium, or uric acid salts
Large stones block ureter  pressure & pain
May be due to chronic bacterial infection, urine retention, Ca2+ in blood, pH of urine
Treatment - shock wave lithotripsy – noninvasive; shock waves shatter calculi
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64. Muscular sac for temporary storage of urine
Urinary Bladder
Muscular sac for temporary storage of urine
Retroperitoneal, on pelvic floor posterior to pubic symphysis
Males—prostate gland inferior to bladder neck
Females—anterior to vagina and uterus
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65. Openings for ureters and urethra Trigone
Urinary Bladder
Openings for ureters and urethra
Trigone
Smooth triangular area outlined by openings for ureters and urethra
Infections tend to persist in this region
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66. Urinary Bladder Layers of bladder wall
Mucosa - transitional epithelial mucosa
Thick detrusor muscle - three layers of smooth muscle
Fibrous adventitia (peritoneum on superior surface only)
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67. Collapses when empty; rugae appear
Urinary Bladder
Collapses when empty; rugae appear
Expands and rises superiorly during filling without significant rise in internal pressure
~ Full bladder 12 cm long; holds ~ 500 ml
Can hold ~ twice that if necessary
Can burst if overdistended
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68. Kidney Renal pelvis Ureter Urinary bladder
Figure Pyelogram.
Kidney
Renal
pelvis
Ureter
Urinary
bladder
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69. Figure 25.20a Structure of the urinary bladder and urethra.
Peritoneum
Ureter
Rugae
Detrusor
Adventitia
Ureteric orifices
Trigone of bladder
Bladder neck
Internal urethral sphincter
Prostate
Prostatic urethra
Intermediate part of the urethra
External urethral sphincter
Urogenital diaphragm
Spongy urethra
Erectile tissue of penis
External urethral orifice
Male. The long male urethra has three regions:
prostatic, intermediate, and spongy.
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70. Figure 25.20b Structure of the urinary bladder and urethra.
Peritoneum
Ureter
Rugae
Detrusor
Ureteric orifices
Bladder neck
Internal urethral
sphincter
Trigone
External urethral
sphincter
Urogenital diaphragm
Urethra
External urethral
orifice
Female.
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71. Muscular tube draining urinary bladder
Urethra
Muscular tube draining urinary bladder
Lining epithelium
Mostly pseudostratified columnar epithelium, except
Transitional epithelium near bladder
Stratified squamous epithelium near external urethral orifice
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72. Urethra Sphincters Internal urethral sphincter
Involuntary (smooth muscle) at bladder-urethra junction
Contracts to open
External urethral sphincter
Voluntary (skeletal) muscle surrounding urethra as it passes through pelvic floor
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73. Urethra Female urethra (3–4 cm) Tightly bound to anterior vaginal wall
External urethral orifice
Anterior to vaginal opening; posterior to clitoris
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74. Figure 25.20b Structure of the urinary bladder and urethra.
Peritoneum
Ureter
Rugae
Detrusor
Ureteric orifices
Bladder neck
Internal urethral
sphincter
Trigone
External urethral
sphincter
Urogenital diaphragm
Urethra
External urethral
orifice
Female.
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75. Male urethra carries semen and urine
Three named regions
Prostatic urethra (2.5 cm)—within prostate gland
Intermediate part of the urethra (membranous urethra) (2 cm)—passes through urogenital diaphragm from prostate to beginning of penis
Spongy urethra (15 cm)—passes through penis; opens via external urethral orifice
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76. Figure 25.20a Structure of the urinary bladder and urethra.
Peritoneum
Ureter
Rugae
Detrusor
Adventitia
Ureteric orifices
Trigone of bladder
Bladder neck
Internal urethral sphincter
Prostate
Prostatic urethra
Intermediate part of the urethra
External urethral sphincter
Urogenital diaphragm
Spongy urethra
Erectile tissue of penis
External urethral orifice
Male. The long male urethra has three regions:
prostatic, intermediate, and spongy.
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77. Three simultaneous events must occur
Micturition
Urination or voiding
Three simultaneous events must occur
Contraction of detrusor muscle by ANS
Opening of internal urethral sphincter by ANS
Opening of external urethral sphincter by somatic nervous system
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78. Reflexive urination (urination in infants)
Micturition
Reflexive urination (urination in infants)
Distension of bladder activates stretch receptors
Excitation of parasympathetic neurons in reflex center in sacral region of spinal cord
Contraction of detrusor muscle
Contraction (opening) of internal sphincter
Inhibition of somatic pathways to external sphincter, allowing its relaxation (opening)
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79. Pontine control centers mature between ages 2 and 3
Micturition
Pontine control centers mature between ages 2 and 3
Pontine storage center inhibits micturition
Inhibits parasympathetic pathways
Excites sympathetic and somatic efferent pathways
Pontine micturition center promotes micturition
Excites parasympathetic pathways
Inhibits sympathetic and somatic efferent pathways
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80. Figure 25.21 Control of micturition.
Brain
Higher brain
centers
Urinary bladder
fills, stretching
bladder wall
Allow or inhibit micturition
as appropriate
Afferent impulses
from stretch
receptors
Pontine micturition
center
Pontine storage
center
Simple
spinal
reflex
Promotes micturition
by acting on all three
spinal efferents
Inhibits micturition by
acting on all three
Spinal efferents
Spinal
cord
Spinal
cord
Parasympathetic
activity
Sympathetic
activity
Somatic motor
nerve activity
Parasympathetic activity
Sympathetic activity
Somatic motor nerve activity
Detrusor contracts;
internal urethral
sphincter opens
External urethral
sphincter opens
Inhibits
Micturition
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81. Homeostatic Imbalance
Incontinence usually from weakened pelvic muscles
Stress incontinence
Increased intra-abdominal pressure forces urine through external sphincter
Overflow incontinence
Urine dribbles when bladder overfills
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82. Homeostatic Imbalance
Urinary retention
Bladder unable to expel urine
Common after general anesthesia
Hypertrophy of prostate
Treatment - catheterization
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83. Developmental Aspects
Three sets of embryonic kidneys form in succession
Pronephros degenerates but pronephric duct persists
Mesonephros claims this duct; becomes mesonephric duct
Metanephros develop by fifth week, develops into adult kidneys and ascends
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84. Figure 25.22a Development of the urinary system in the embryo.
Degenerating
pronephros
Developing
digestive tract
Urogenital
ridge
Duct to
yolk sac
Mesonephros
Allantois
Cloaca
Mesonephric duct
(initially, pronephric duct)
Ureteric bud
Hindgut
Week 5
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85. Figure 25.22b Development of the urinary system in the embryo.
Degenerating
pronephros
Duct to yolk sac
Allantois
Body stalk
Urogenital sinus
Rectum
Mesonephros
Ureteric bud
Mesonephric
duct
Metanephros
Week 6
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86. Developmental Aspects
Metanephros develops as ureteric buds that induce mesoderm of urogenital ridge to form nephrons
Distal ends of ureteric buds form renal pelves, calyces, and collecting ducts
Proximal ends become ureters
Kidneys excrete urine into amniotic fluid by third month
Cloaca subdivides into rectum, anal canal, and urogenital sinus
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87. Figure 25.22c Development of the urinary system in the embryo.
Urogenital
sinus
(developing
urinary
bladder)
Gonad
Rectum
Metanephros
(kidney)
Week 7
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88. Figure 25.22d Development of the urinary system in the embryo.
Urinary bladder
Gonad
Urethra
Kidney
Anus
Ureter
Rectum
Week 8
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89. Homeostatic Imbalance
Three common congenital abnormalities
Horseshoe kidney
Two kidneys fuse across midline  single U-shaped kidney; usually asymptomatic
Hypospadias
Urethral orifice on ventral surface of penis
Corrected surgically at ~ 12 months
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90. Homeostatic Imbalance
Polycystic kidney disease
Many fluid-filled cysts interfere with function
Autosomal dominant form – less severe but more common
Autosomal recessive – more severe
Cause unknown but involves defect in signaling proteins
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91. Developmental Aspects
Frequent micturition in infants due to small bladders and less-concentrated urine
Incontinence normal in infants: control of voluntary urethral sphincter develops with nervous system
E. coli bacteria account for 80% of all urinary tract infections
Untreated childhood streptococcal infections may cause long-term renal damage
Sexually transmitted diseases can also inflame urinary tract
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92. Developmental Aspects
Most elderly people have abnormal kidneys histologically
Kidneys shrink; nephrons decrease in size and number; tubule cells less efficient
GFR ½ that of young adult by age 80
Possible from atherosclerosis of renal arteries
Bladder shrinks; loss of bladder tone  nocturia and incontinence
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