1. Urinary System

2. Topics & Objectives Kidney Glomerular filtration
Anatomy
Function
Glomerular filtration
Tubular reabsorption & secretion
Urine excretion & plasma clearance

3. Ultimately regulate ECF volume (receive ~ 20% of cardiac output!)
Kidney Functions:
Ultimately regulate ECF volume (receive ~ 20% of cardiac output!)
Maintain H2O balance in the body
Maintain osmolarity
Regulation of ECF ions
Na+, Cl-, K+, H+, etc.
Maintain plasma volume & acid-base balance
Excretion of end products and foreign compounds
Producing EPO & renin

4. Figure 14.1 Page 513 Renal cortex Renal medulla Renal pyramid Renal
pelvis
Renal
artery
Ureter
Renal
vein
Kidney
Aorta
Inferior
vena cava
Ureter
Urinary
bladder
Figure 14.1 Page 513
Urethra

5. Nephrons ~ 1 million within kidney
Functional unit for urine formation
Arrangement comprises renal cortex & renal medulla
Each nephron composed of:
Vascular component
Tubular component
Medulla
Cortex

6. Figure 14.3 Page 514 Distal Proximal tubule tubule Collecting
duct
Juxtaglomerular
apparatus
Efferent
arteriole
Afferent
arteriole
Bowman’s
capsule
Glomerulus
Cortex
Medulla
Peritubular
capillaries
Loop of
Henle
Figure 14.3 Page 514
To renal
pelvis

7. Vascular Component: Glomerulus Arterioles Peritubular capillaries
Location for H2O and solute filtration from blood
Arterioles
Afferent: to glomerular capillaries
Efferent: drains capillaries
No O2 extraction!
Peritubular capillaries
Supply renal tissue
Efferent
arteriole
Afferent
arteriole
Glomerulus
Peritubular
capillaries

8. Tubular Component: Bowman’s capsule Fluid travels to:
Proximal tubule
Distal
tubule
Juxtaglomerular
apparatus
Bowman’s capsule
Collects fluid from glomerulus
Fluid travels to:
Proximal tubule
Loop of Henle
Passes through juxtaglomerular apparatus
Vascular/tubular component
Distal tubule
Bowman’s
capsule
Loop of
Henle

9. Juxtamedullary nephron
Cortical nephron
Juxtamedullary nephron

10. Urine Formation Glomerular filtration (protein-free)
~ 20% of the plasma (1st step of urine formation)
~ 50 gallons each day (PV ~ 65x/day)
Tubular reabsorption
Of the 50 gallons filtered, about 98% reabsorbed
Tubular secretion
~ 80% of the plasma into the peritubular capillaries

11. Figure 14.6 Page 516 80% of the plasma that enters the glomerulus is
Afferent
arteriole GF
Efferent
arteriole
Glomerulus
80% of the plasma
that enters the
glomerulus is
not filtered
and leaves through
the efferent arteriole.
Bowman’s
capsule
20% of the
plasma that
enters the
glomerulus
is filtered. TR
Peritubular
capillary TS
Kidney
tubule
(entire
length,
uncoiled)
To venous system
(conserved
for the body)
Urine excretion
(eliminated
from the body)
Figure 14.6 Page 516

12. Figure 14.7 Page 517 Blood pathway Glomerular capillaries Efferent
arteriole
Peritubular
capillaries
Venous
blood
Glomerular
filtration
Tubular
reabsorption
Tubular
secretion
Filtrate
pathway
Bowman’s
capsule
Tubule (from proximal
tubule to collecting duct)
Urine

13. Glomerular Filtration

15. Figure 14.8 (1) Page 518 Glomerular capillary Basement membrane
Afferent arteriole
Efferent arteriole
Glomerulus
Glomerular capillary
Bowman’s
capsule
Basement
membrane
Figure 14.8 (1) Page 518
Proximal convoluted tubule

16. Glomerular Filtration
Endothelial
cell
Lumen of glomerular
capillary
pores
Basement
membrane
podocytes
Figure 14.8 (3) Page 518
Lumen of
Bowman’s capsule

17. Glomerular Filtration (cont.): Occurs through pressure gradients…
Capillary blood pressure (~55mmHg)
Favors filtration
Plasma osmotic pressure (~30mmHg)
Caused by distribution of plasma proteins across glomerular membrane
Cannot cross into Bowman’s capsule
Bowman’s capsule hydrostatic pressure (~15mmHG)
Pressure by the fluid
All three pressures determine filtration rate!

18. 1) Changes in BP
2) Osmotic pressure
Look at Table 14.1!
3) Hydrostatic pressure

19. GFR Regulation Autoregulation Extrinsic sympathetic control
Prevents spontaneous changes in GFR
Vasoconstriction & vasodilation
Myogenic mechanism – response to stretch
Tubuloglomerular feedback mechanism
Extrinsic sympathetic control
Long-term regulation of arterial BP
Sympathetic nervous system (no parasympathetic activity)
Baroreceptor reflex

20. GFR autoregulation
Alterations in arteriolar afferent & efferent blood pressures
Afferent arteriole
Glomerulus
Efferent arteriole
Glomerular
capillary
blood pressure
Arterial blood
pressure
(increases blood
flow into the
glomerulus)
Net filtration
pressure
Figure Page 520
GFR

21. GFR autoregulation (cont.)
Glomerulus
Glomerular
capillary
blood pressure
Afferent arteriole
Efferent arteriole
Net filtration
pressure
Vasoconstriction
(decreases blood flow
into the glomerulus)
GFR

22. GFR autoregulation Glomerulus Afferent arteriole Glomerular capillary
blood pressure
Efferent arteriole
Net filtration
pressure
Vasodilation
(increases blood flow
into the glomerulus)
GFR

23. GFR Autoregulation – Tubuloglomerular feedback
Smooth muscle cells within afferent arteriole
Granular cells – secretory capabilities
Tubular cells (macula densa)
Detect changes in the rate of fluid passing through tubule
Bring about vasoconstriction or vasodilation
Efferent
arteriole
Distal
tubule
Bowman’s
capsule
Afferent

24. Efferent
arteriole
Smooth
muscle
cell
Macula
densa
Distal
tubule
Afferent
Granular cells
Podocyte
Glomerular
capillaries
Lumen of
Bowman’s
capsule
Endothelial

25. Arterial blood pressure
Driving pressure into glomerulus
Glomerular capillary pressure
GFR
Rate of fluid flow
through tubules
Stimulation of macula densa cells
to release vasoactive chemicals
Chemicals released that induce
afferent arteriolar vasoconstriction
Blood flow into glomerulus
Glomerular capillary pressure
to normal
GFR to normal

26. Extrinsic Control – Baroreceptors
Response to decreased BP
Sympathetically induced vasoconstriction
Afferent arterioles (sympathetically innervated)
Response to increased BP
Sympathetic stimulation decreases

27. arteriolar vasoconstriction
Short-term
adjustment
for
Long-term
adjustment for
Arterial blood
pressure
Arterial
blood
pressure
Detection by aortic
arch and carotid sinus
baroreceptors
Cardiac
output
Sympathetic activity
Total
peripheral
resistance
Generalized
arteriolar vasoconstriction
Afferent arteriolar
vasoconstriction
Glomerular capillary
blood pressure
GFR
Urine volume
Conservation of fluid and salt
Arterial blood pressure

28. Tubular Reabsorption

29. Figure 14.6 Page 516 Afferent Efferent arteriole arteriole GlomerulusGF
Efferent
arteriole
Glomerulus
Bowman’s
capsule TR
Peritubular
capillary
Figure 14.6 Page 516

30. Tubular reabsorption:
Ultimately attempting to maintain body’s internal environment
Proper composition & volume
Table 14.2
Filtered substance reabsorbed
Filtered substance excreted
Water 99 1
Sodium
99.5
0.5
Glucose
100
Urea (waste product) 50
Phenol (waste product)

31. Transepithelial transport
Material must pass through the cells (5 steps)
Tubular
lumen
epithelial cell
Peritubular
capillary
Plasma
Tight
junction
4) Interstitial
fluid
1) Luminal
membrane
2) Cytosol
3) Basolateral
membrane
5) Capillary
wall
Figure Page 526
Transepithelial transport

32. Passive & Active Reabsorption
Passive: all steps follow electrochemical or osmotic gradients
Active: any one of the steps requiring energy
Sodium (80% of kidney’s total energy requirement)
~ 67% in proximal tubule
~ 25% in loop of Henle
~ 8% in distal and collecting tubules
Glucose
Phosphate
Constant percentage of Na+ reabsorption

33. Na+ pumped out against concentration gradient
Creates higher concentration in interstitial fluid & allows for passive diffusion back into lumen
Lumen
Tubular cell
Interstitial fluid
Peritubular
capillary
Diffusion
Na+
channel
Active transport
Basolateral
Na+– K+ ATPase
carrier
Diffusion
Figure Page 527

34. Distal tubule (~ 8% of total reabsorption) is hormonally regulated
Related to total Na+ load in body
Changes in ECF affect osmotic pressures
ex: Increased Na+ in ECF causes increased H2O in ECF
Ultimately regulates blood pressure
Renin-angiotensin-aldosterone system ↑
Atrial natriuretic peptide ↓

35. Within juxtaglomerular apparatus…
Granular cells release renin
In response to fall of NaCl/ ECF volume/ BP
Recognized by intrarenal baroreceptors
Sympathetic response to secrete more renin
Ultimately trying to increase plasma volume

36. Figure 14.19 Page 529 H2O conserved Adrenal cortex Liver Kidney Lungs
NaCl / ECF volume /
Arterial blood pressure
H2O
conserved
Adrenal
cortex
Liver
Kidney
Lungs
Kidney
Na+ (and CI–)
osmotically hold
more H2O in ECF
Na+ (and CI–)
conserved
Angiotensin-
converting
enzyme
Renin
Na+ reabsorption
by kidney tubules
( CI–
reabsorption
follows passively)
Angiotensinogen
Angiotensin I
Angiotensin II
Aldosterone
Vasopressin
Thirst
Arteriolar
vasoconstriction
H2O reabsorption
by kidney tubules
Fluid intake
Figure Page 529

37. Inhibits aldosterone & renin secretion
Helps correct
NaCl / ECF volume /
Arterial blood pressure
Helps correct
Cardiac
atria
Atrial natriuretic
peptide
Na+ reabsorption
by kidney tubules
Salt-conserving
renin-angiotensin-
aldosterone system
Smooth muscle
of afferent arterioles
Sympathetic
nervous system
Inhibits aldosterone & renin secretion
Afferent
arteriolar
vasodilation
Cardiac
output
Total
peripheral
resistance
GFR
Na+ excretion
in urine
Arterial blood
pressure
Figure Page 530
Na+ and H2O
filtered
H2O excretion
in urine

38. Glucose and amino acid reabsorption
Na+ dependent secondary active transport
Co-transporters that do not require energy
Maximal reabsorption rate depends on substance

39. No energy
required
Cotransport carrier
Glucose
carrier
Basolateral
border
Energy
Na+–K+ pump
Blood vessel
Luminal border

40. Phosphate & Calcium reabsorption
Dependent upon total body content
Regulated by kidneys
Hormonally (parathyroid hormone)
Na+ reabsorption responsible for passive reabsorption of Cl-, H2O, and urea

41. H2O (passive) reabsorption
80% in proximal tubules & loops of Henle
Lumen
Proximal tubular cell
Peritubular
capillary
Interstitial fluid
Osmosis
Water
channel
Figure Page 533
Hydrostatic
pressure
Osmosis

42. Urea (passive) reabsorption
Glomerulus
Bowman’s
capsule
Beginning of
proximal
tubule
End of
= Urea molecules
Peritubular
capillary
Urea (passive) reabsorption
Waste product of protein
Becomes increasingly concentrated
125 ml of
filtrate
Na+ (active)
H2O (osmosis)
Na+ (active)
H2O (osmosis)
44 ml of
filtrate
Figure Page 534
Passive diffusion
of urea down its
concentration gradient

43. Tubular Secretion

44. Figure 14.6 Page 516 Afferent Efferent arteriole arteriole GlomerulusGF
Bowman’s
capsule
Peritubular
capillary TS
Kidney
tubule
(entire
length,
uncoiled)
Figure 14.6 Page 516

45. Organic anions & cations
Tubular secretion:
Hydrogen ions (H+)
Acid-base regulation throughout the body
Potassium (K+)
Early reabsorption into tubules not regulated
Secretion in distal tubules regulated
Na+-K+ pump
Aldosterone
Organic anions & cations
Foreign compounds, chemical messengers

46. Aldosterone - dual regulation 1) Na+ & K+
Na+/ ECF volume/
arterial pressure
Aldosterone - dual regulation
1) Na+ & K+
Renin
Angiotensin I
Plasma K+
Angiotensin II
Figure Page 536
Aldosterone
Tubular K+ secretion
Tubular Na+ reabsorption
Urinary K+ excretion
Urinary Na+ excretion

47. Plasma Clearance

48. Substance: Filtered NOT reabsorbed NOT secreted All filtered plasma is
Peritubular
capillary
Glomerulus
All filtered plasma is
cleared of substance
Tubule In
urine
Fig a Page 539

49. Substance:
Filtered
NOT secreted
Completely reabsorbed
None of filtered plasma is
cleared of substance

50. Substance:
Filtered
NOT secreted
Partially reabsorbed
Portion of filtered plasma is
cleared of substance

51. Substance:
Filtered
Secreted
NOT reabsorbed
ALL of filtered plasma is
cleared of substance

52. Regulation of plasma H2O
Fluids & solutes
Normal balance in body fluids called isotonic
300 mosm/liter
Hypotonic
Too much H2O compared to solute (osmolality < 300)
Hypertonic
Too little H2O compared to solute (osmolality > 300)
Osmotic gradient maintained in interstitial fluid of medulla
Dependent upon hydration levels

53. Fig. 14.28a (2) Page 542 From proximal tubule To distal tubule
Medullary
interstitial fluid
Medullary
interstitial fluid
Descending limb
of loop of Henle
of juxtamedullary
nephron
Ascending limb
of loop of Henle
of juxtamedullary
nephron
Fig a (2) Page 542
Initial scene

54. Step 1

55. From
proximal
tubule To
distal
tubule
Step 2

56. Step 3

57. From
proximal
tubule To
distal
tubule
Step 4

58. Step 5

59. From
proximal
tubule To
distal
tubule
Step 6 and on

60. Further regulation Vasopressin Anti-diuretic hormone from hypothalamus
Tubular
lumen
filtrate
Distal tubular cell
Peritubular
capillary
plasma
Water
channel
Increases permeability of
luminal membrane to H2O
by inserting new
water channels
Figure Page 544