1. TOPIC 10� Urinary System Chapter 26
pp. 1004-1036
2. Main Function Regulates the composition and volume of blood by:
Regulating water content
Maintaining ionic concentrations
Maintaining pH balance
Removing metabolic wastes (especially urea)
3. Other Functions: Regulates blood pressure
secretes renin ? renin-angiotensin pathway (results in formation of angiotensin II - a potent vasoconstrictor)
Regulates red blood cell (erythrocyte) formation
erythropoietin (stimulates formation of RBCs in red bone marrow)
Gluconeogenesis during prolonged fasting
4. Overview of Components Kidneys
located posteriorly; superior lumbar region, below diaphragm; retroperitoneal
perform functions of urinary system
Ureters
extend from kidney to urinary bladder
transport urine to urinary bladder
Urinary Bladder
located in pelvic cavity
stores urine before micturition
Urethra
extends from bladder to urethral oriface
transports urine to outside
5. Gross Anatomy: Kidney Coverings renal fascia - dense fibrous CT that anchors kidney to posterior abdominal wall
adipose capsule - fatty tissue surrounding and cushioning kidney outside of renal capsule
renal capsule - connective tissue covering
6. Gross Anatomy: Kidney Regions Regions
cortex - outer region
medulla - middle region
renal sinus - inner open area
7. Gross Anatomy: Ureters Mucosa transitional epithelium (allows stretching)
Muscularis smooth muscle (propels urine by peristalsis)
Adventitia fibrous connective tissue (anchors ureters)
8. Gross Anatomy: Urinary Bladder Mucosa
transitional epithelium
designed to withstand stretching
Muscularis
smooth muscle
contracts to expel urine
9. Gross Anatomy: Urethra Lining varies from transitional to pseudostratified columnar to stratified squamous epithelium
Internal sphincter of smooth muscle (ANS control)
External sphincter of skeletal muscle (voluntary control)
10. Kidney: Internal Anatomy Renal cortex
renal columns extend down into medulla between medullary pyramids
Renal medulla
medullary (renal) pyramids formed from collecting tubules
papilla ends of pyramid
11. Kidney: Internal Anatomy Renal pelvis part of urine collection system; sits in renal sinus
major calyces (singular = calyx) branches of pelvis
minor calyces branches of major calyces that receive urine from renal papillae
12. Nerve Supply Renal plexus - autonomic nervous control
sympathetic nerve fibers
control vasomotor tone of renal arterioles
13. Blood Supply Arterial blood supply: Renal Artery*
Venous drainage: Renal Vein*
*divisions covered in lab
14. Microvasculature: �Afferent Arteriole Leads to (feeds) glomerulus
Arises from interlobular artery
Larger diameter than efferent arteriole (increases pressure in glomerulus)
15. Microvasculature: Glomerulus Fenestrated capillaries - have pores in walls to increase filtration
Surrounded by Bowmans (glomerular) capsule of nephron
filtration membrane = capillary wall plus visceral (inner) layer of Bowmans capsule plus basement membrane (fused basal laminas of capillary and capsule)
16. Microvasculature: �Efferent Arteriole Drain glomerulus
Give rise to peritubular capillaries and vasa recta
17. Microvasculature: �Peritubular Capillaries Arise from efferent arteriole
Follow renal tubules (around proximal and distal convoluted tubules)
Low pressure
Porous better for absorption of water and solutes
18. Microvasculature: Vasa Recta Arise from efferent arteriole
Follow loop of Henle toward medulla (loops and vasa recta of juxtamedullary nephrons extend into medulla)
19. Nephrons: Overview Functional unit of the kidney
Consist of:
Glomerular (Bowmans) capsule
Proximal convoluted tubules (PCT)
Loop of Henle
Distal convoluted tubules (DCT)
20. Nephrons: Glomerular Capsule a.k.a. Bowmans capsule
Found in cortex
Cup-shaped blind sac surrounding glomerulus
Renal corpuscle = Bowmans capsule + glomerulus
Parietal layer of Bowmans capsule
outer wall of capsule
simple squamous epithelium
21. Nephrons: Glomerular Capsule Visceral layer (of BC) in contact with glomerulus
modified simple squamous epithelium with branched epithelial cells called podocytes
filtration slits openings between feet of podocytes; permit filtrate to enter capsular space
Capsular space
space between visceral and parietal layers
space into which plasma is filtered
22. Nephrons: Proximal Convoluted Tubule (PCT) Proximal portion of nephron; found in cortex
Designed for absorption and secretion
Simple cuboidal epithelium
microvilli increase area for absorption
23. Nephrons: Loop of Henle Important to concentrated urine
Most are entirely cortical (located in cortex)
Loops of juxtamedullary nephrons extend into medulla very important to concentrated urine
24. Nephrons: Loop of Henle Descending limb carries filtrate toward medulla
thin segment = simple squamous or very low cuboidal ET
Ascending limb carries filtrate back into cortex
thick segment = upper part is low columnar
25. Nephrons: Distal Convoluted Tubule (DCT) Found in cortex
Last part of nephron
Designed for absorption & secretion
simple cuboidal epithelium
microvilli increase area of cells
26. Types of Nephrons Cortical nephrons (~ 85% of all nephrons)
located entirely in cortex (or almost entirely, loops of some dip into upper medulla)
Juxtamedullary nephrons
renal corpuscle located in cortex close to border with medulla
loops of Henle extend far into medulla
important to forming concentrated urine
27. Juxtaglomerular Apparatus Consists of parts of afferent and efferent arterioles (called JG cells) and part of DCT (called macula densa)
Juxtaglomerular (JG) cells
consist of modified smooth muscle in the walls of the afferent and efferent arterioles
respond to decreased blood pressure (BP) by secreting renin
28. Juxtaglomerular Apparatus Macula densa cells of distal convoluted tubule
contains osmoreceptors
respond to changes in solute concentration of filtrate in lumen of tubule
secrete local vasoconstrictor to decrease flow into glomerulus when solute concentration in filtrate is high
29. Mechanisms of Urine Formation Approx. 1-1.2 l of blood passes through kidney per minute
of this, about 120-125 ml is filtered
Approx. 99% of filtrate (liquid in lumen of nephron) is reabsorbed (taken back from filtrate back to blood, via interstitial fluid)
Filtrate is processed in nephron to become urine that leaves through collecting ducts
30. Three Main Processes Overview Glomerular Filtration initial movement of fluid from blood into the capsular space of Bowmans capsule of nephron
Tubular Reabsorption moves desirable substances from tubule to blood
Tubular Secretion moves undesirable substances from blood into tubule for removal from body
31. Glomerular Filtration Occurs at glomerulus
Approx. 120-125 ml filtered into glomerular space per minute (~180 L per day!)
Filtrate resembles blood, but
normally lacks proteins and formed elements,
ions and other solutes are in proportion to concentration in blood
32. Net Filtration Pressure (NFP) Provides force for movement of fluid into capsular space
NFP = difference between pressures forcing fluid into glomerular space and pressures resisting filtration
Uses forces similar to those involved in movement of fluid between blood and interstitial fluid at other capillaries
33. Net Filtration Pressure (NFP) NFP = forces into nephron forces out of nephron
NFP = HPg + OPc (OPg + HPc)
HPg = glomerular (capillary) hydrostatic pressure within glomerulus
OPg = osmotic pressure of the filtrate within capsular space (normally near 0)
OPg = glomerular osmotic pressure of the blood within the glomerulus (due to solutes inc., protein)
HPc = hydrostatic pressure of fluid within capsular space
34. NFP: Forces Supporting Filtration factors supporting filtration move fluid out of blood into filtrate (within nephron)
Glomerular hydrostatic pressure (HPg)
main force supporting filtration
blood pressure within glomerulus
normally approx. 55 mm Hg
higher than in most capillaries because efferent arteriole is narrower (smaller diameter) than afferent arteriole
35. NFP: Opposing Forces factors opposing filtrate push/pull fluid out of filtrate, back into blood
(Glomerular) blood colloid osmotic pressure (OPg)
osmotic pressure created primarily by proteins (albumins) in blood
draws fluid back into blood
normally 28-30 mm Hg
Capsular hydrostatic pressure (HPc)
physical pressure of fluids in glomerular space
pushes fluid back into blood
normally approx. 15 mm Hg
36. Net Filtration Pressure (NFP) NFP = forces into nephron forces out of nephron
NFP = HPg (OPg + HPc)
= 55 mm Hg (28 mm Hg + 15 mm Hg)
= 12 mm Hg
range is normally 10-12 mm Hg
37. Glomerular Filtration Rate (GFR) Total amount of filtrate formed per minute (120-125 ml/min)
Based on:
total surface area available for filtration (number of functioning glomeruli) *
permeability of filtration membrane *
net filtration pressure
varies with systemic blood pressure
main part that is controlled
Normally, total surface area available and permeability of filtration membrane do not change; can be changed by disease
38. Intrinsic Control (Autoregulation) of GFR Kidney adjusts resistance to blood flow to maintain normal, adequate filtration rate by regulating diameter of afferent (and efferent) arterioles
myogenic mechanism (stretch response) = involves changes in vasomotor tone in response to changes in blood pressure
tubuloglomerular feedback mechanism involves macula densa cells of DCT in response to filtrate osmolarity
39. Myogenic mechanism Increase in systemic BP would be expected to increase filtration, kidney counteracts by myogenic mechanism (to a degree) to maintain normal (or near normal) GFR
Increased systemic BP, smooth muscles are stretched resulting in reflexive constriction of afferent arterioles
decreases filtration pressure (compared to what it would be without change)
minimizes increase in pressure due to increased systemic BP to prevent damage to glomerulus
With a large increase in systemic BP, filtration increases ? increases fluid loss ? decreases blood volume ? decreases BP
40. Myogenic mechanism Decrease in systemic BP stretches afferent arteriole less
resulting in dilation of afferent arterioles, which allows more blood to pass through glomerulus thus increasing filtration pressure (compared to doing nothing)
maintains filtration even when BP decreases in order to maintain removal of wastes
41. Tubuloglomerular Feedback Mechanism Macula densa cells of distal convoluted tubules DCT secrete a potent locally-acting vasoconstrictor when:
lots of filtrate is present and flow is high
osmolarity (solute concentration, especially Na+ and Cl- content) of filtrate is high because not as many ions are being reabsorbed in PCT
Vasoconstrictor constricts afferent arterioles which decreases flow ? decreases filtration
slows movement of filtrate through nephron thus allowing increased time for reabsorption
42. Tubuloglomerular Feedback Mechanism (cont) When flow or osmolarity is low, vasoconstrictor is not secreted
afferent arteriole remains at normal size (i.e., not constricted) ? more blood enters glomerulus ? greater pressure
allows maintenance of filtration rate
43. Extrinsic Controls: ANS Sympathetic Division rapid control of filtration
sympathetic stimulation results in vasoconstriction of afferent arterioles (and to a lesser extent, efferent arterioles)
? less blood enters glomerulus
? lower HPg (lowers NFP)
? decreases filtration
? less filtrate produced
? decreases volume loss to maintain blood pressure
44. Extrinsic Controls: �Renin-Angiotensin Pathway Slower method of control
Renin (enzyme) secreted by juxtaglomerular cells (of afferent and efferent arterioles) when:
BP in arterioles drops and they are no longer stretched as much
reduced filtrate flow stimulates macula densa cells (of DCT) next to JG cells
sympathetic nervous system stimulates JG cells directly
45. Renin-Angiotensin Pathway (cont) Renin hydrolyses angiotensinogen to angiotensin I which is then converted to angiotensin II, which:
is a potent vasoconstrictor that directly raises BP by increasing peripheral resistance (? increased glomerular hydrostatic pressure)
causes greater constriction of efferent than afferent arterioles (restores filtration to normal level when systemic BP decreases)
46. Renin-Angiotensin Pathway (cont) Renin also stimulates release of aldosterone from adrenal cortex
aldosterone acts on DCT to increase Na+ reabsorption leading to increased obligatory water reabsorption
47. Tubular Processing Tubular reabsorption brings water and solutes back from filtrate into blood
Tubular secretion adds solutes to filtrate
Reabsorption and secretion occur simultaneously
48. Tubular Reabsorption (TR) Absorption of solutes from filtrate and subsequent return to blood
Takes place in PCT, loop of Henle and DCT, but substances moved varies through nephron
49. Reabsorbed Substances Most organic nutrients (e.g., glucose, amino acids, vitamins)
Most ions
Na+ and K+ highly regulated (by aldosterone)
H+ regulated to maintain pH balance
minerals (e.g., Ca2+) regulated by hormones (PTH)
Water reabsorption is highly regulated
Aldosterone (indirectly) & antidiuretic hormone (directly)
50. Nonreabsorbed Substances Substances that are not reabsorbed or reabsorbed only in small amounts
lack carriers, limited lipid solubility, large
some substances are partially reabsorbed then later secreted into the DCT
Nitrogenous wastes
urea: 50% to 60% of urea is reabsorbed because it is small
creatinine (from creatine phosphate in skeletal muscle) large, not lipid soluble
uric acid is reabsorbed by PCT, but most is secreted again later
51. Reabsorption Pathways Transcellular
materials move through tubule cells
materials must cross apical (near lumen) and basolateral membranes
transport of some substances requires presence of membrane channels or carriers
Paracellular
materials go between cells held together by tight junctions
limited to very small substances
52. Reabsorption: Passive Transport Uses energy of concentration gradient set up by active reabsorption of Na+
Simple diffusion thru lipid bilayer of membrane
fat-soluble substances, urea
Facilitated diffusion
requires membrane proteins
some ions (e.g., Cl-, HCO3-) and polar molecules
53. Reabsorption: Passive Transport Osmosis
obligatory water reabsorption (follows osmotic gradient)
facultative water reabsorption (controlled by ADH)
Solvent drag pulls substances (especially fat-soluble substances and urea) as water moves
54. Reabsorption: �Primary Active Transport Requires direct use of ATP
Sodium-potassium pump at basal end of cell (basolateral membrane)
moves Na+ into interstitial fluid
creates Na+ and K+ gradients
55. Reabsorption: �Primary Active Transport Na+ gradient forms as Na+ moves from filtrate into cells because of gradient created by active transport of Na+ into interstitial fluid
K+ returns to interstitial fluid through K+ channels in basolateral membrane due to gradient created by pumping it into filtrate
56. Reabsorption: Secondary Active Transport (Cotransportation) Cotransport of substance is by same protein that carries Na+ from lumen of tubule into cells of tubule wall
Substances cotransported:
simple sugars (glucose, galactose, fructose),
amino acids
some ions
vitamins
57. Reabsorption: Secondary Active Transport (Cotransportation) Transport maximum (Tm) maximum amount of substance that can be reabsorbed per minute
depends on number of carrier proteins in membrane
solute is lost if availability exceeds Tm or if filtrate moves too fast
58. Sites of Reabsorption Proximal convoluted tubule (PCT)
65% to 99% of desirable solutes reabsorbed
about 65% of the filtrate fluid reabsorbed
Loop of Henle reabsorption of water and NaCl
Distal convoluted tubule (DCT)
reabsorption of water, NaCl (controlled by aldosterone)
Collecting ducts (CD) NaCl, water, urea
water reabsorption is influenced by ADH (antidiuretic hormone) which increases permeability of duct walls to water
59. Control of Tubular Reabsorption: Aldosterone made mainly by zona glomerulosa of adrenal cortex
secreted when:
K+ levels rise (hyperkapnia)
Na+ levels drop (hyponatremia)
blood pressure or blood volume drop (renin-angiotensin pathway)
ACTH is secreted by adenohypophysis
targets cells of collecting ducts to increase Na+ reabsorption and K+ secretion
water follows Na+ by osmosis (obligatory reabsorption) ? increases blood volume ? increases blood pressure
60. Control of Tubular Reabsorption: Antidiuretic Hormone (ADH) produced in hypothalamus
secreted from posterior pituitary gland when hypothalamic cells detect increase in blood osmotic pressure (solute concentration)
acts on DCT and collecting ducts to increase water permeability, thus allowing increased reabsorption of water = facultative water reabsorption
61. Control of Tubular Reabsorption: ANP and PTH Atrial natriuretic peptide (ANP)
inhibits reabsorption of Na+ (thus decreasing water reabsorption)
decreased water reabsorption ? decreased blood volume ? decreased blood pressure
secreted by atria when BP rises
Parathyroid Hormone (PTH)
secreted by parathyroid glands when blood Ca2+ drops
increases Ca2+ reabsorption in DCT
62. Control of Tubular Reabsorption: Diuretics any solute that exceeds its transport maximum acts as an osmotic diuretic
e.g., glucose in diabetes mellitus
e.g., glucose in steroid diabetes
chemicals that inhibit ADH release
e.g., alcohol
chemicals that inhibit Na+ reabsorption
e.g., caffeine
63. Tubular Secretion Movement of solutes from blood (via interstitial fluid) INTO filtrate
Solutes secreted include:
H+
K+
NH4+ (ammonium ions)
organic acids and bases
urea and uric acid
certain drugs (transported by same carriers as organic acids and bases)
64. Tubular Secretion Important to:
disposal of solutes not normally filtered (e.g., penicillin, phenobarbitol)
eliminating undesirable substances (urea, uric acid)
ridding body of excess K+
maintaining blood pH (by secreting H+)
65. Conserving Water While Removing Wastes Living in dry environment means we constantly lose water --> must conserve water
Kidneys conserve water while concentrating undesirable solutes by removal of water (and NaCl) from filtrate
66. Concentration Amount of solute per volume of solution (or solvent)
Changed by:
changing amount of solute
adding solute (tubular secretion) increases concentration
removing solute (tubular reabsorption) decreases concentration
changing amount of solvent (water)
adding solvent decreases concentration
removing solvent increases concentration
Concentration is measured as osmolality or osmolarity
67. Osmolarity vs Osmolality Osmolality = number of solute particles per kilogram of solvent (water; 1 L water weighs 1 kg at 20o C)
filtrate (urine) concentration measured in osmolality
unit = milliosmols (mosm)
Osmolarity = number of solute particles in 1 liter of solution (e.g., plasma)
unit = mg/L
68. Mechanism of Water Conservation Countercurrent multiplier in loop of Henle and vasa recta
Key factors:
direction of flow in ascending limb of loop is opposite that of flow in descending limb
filtrate entering and exiting loop of Henle is approximately isotonic with plasma
BUT, urea is concentrated relative to blood because water, NaCl and nutrients have been removed
69. Counter-current Multiplier (cont) Osmotic gradient exists between cortex and medulla
Osmolality in cortex ~ 300 milliosmols (mosm)
Osmolality in inner (deep) medulla ~ 1200 mosm
Descending limb of loop is relatively impermeable to solutes, but freely permeable to water --> water leaves as filtrate descends into medulla
70. Counter-current Multiplier (cont) Ascending limb of loop is impermeable to water but NaCl is actively reabsorbed from filtrate into interstitial fluid --> creates and maintains osmotic gradient in medulla
Vasa recta removes excess water and solute
Lower portion of the collecting ducts is permeable to urea, which adds to the high medullary osmolality
71. Mechanism of Concentration �(How it works) NaCl is actively reabsorbed from filtrate in ASCENDING LIMB of loop ? NaCl enters interstitial fluid (IF)
Entrance of NaCl into IF increases osmolality of IF
this exerts an osmotic pressure that draws water out of loop
BUT, ascending limb is impermeable to water cannot leave!!
Permeable descending limb is close by and also subject to increased osmolality of IF
Water flows out of descending limb of loop of Henle into IF (i.e., water leaves filtrate)
72. Mechanism of Concentration Loss of water from filtrate increases concentration of solutes remaining in filtrate in descending limb
Water and excess NaCl are removed from IF around descending limb by vasa recta? solute concentration in IF stays high
Active transport of NaCl out of ascending limb lowers osmolality of filtrate remaining in nephron
Urea is more concentrated (as are other remaining solutes) because the amount of urea has not changed while the amount of water (and NaCl) has decreased
73. Mechanism of Concentration Portion of collecting duct deep in inner medulla is permeable to urea, which diffuses out and adds to high osmolality in medulla --> pulls more water out of descending limb into interstitial fluid
74. Role of the Vasa Recta Vasa recta acts does countercurrent exchange
Vasa recta (VR) parallel loop of Henle of juxtamedullary nephrons and descends into inner medulla
Freely permeable to both water and NaCl --> preserves osmotic gradient of IF
Water leaves vasa recta as it descends into medulla, and reenters as vasa recta ascends into cortex
Salt enters as VR descends into medulla, leaves as vasa recta ascends into cortex
75. Formation of Dilute Urine Response to excess fluid intake or decreased secretion of ADH or aldosterone
Normally, collecting ducts (CDs) are not very permeable to water, therefore, lots of water leaves with filtrate, resulting in a dilute urine
Reabsorption of solutes from DCT and CDs further dilutes urine
76. Formation of Concentrated Urine Response to dehydration or increased ADH or aldosterone secretion
Urine is concentrated by reabsorption of water
Water reabsorption increases when water permeability of CDs increases
Water permeability of CDs increases when ADH is present
ADH secreted by posterior pituitary in response to signal from hypothalamus
Hypothalamus stimulated by:
increase in plasma solute concentration (especially Na+)
aldosterone
77. Characteristics & Composition�of Urine Normal constituents include:
substances that are only partially reabsorbed (e.g., NaCl, water)
substances that are secreted (e.g., organic acids, organic bases, K+, H+)
Abnormal constituents include:
blood cells (white or red)
organic nutrients (e.g., simple sugars, amino acids -- normally completely reabsorbed)
hemoglobin
bile pigments
proteins
78. Micturition (Urination) Distension of bladder activates stretch receptors when ~ 200 ml of urine has accumulated ? visceral reflex arc
Sensory impulses to sacral spinal cord segments
Result in parasympathetic impulses to smooth muscle of bladder and internal urethral sphincter
results in contraction of bladder and relaxation of internal urethral sphincter
79. Micturition (Urination) Sensory input to brain allows conscious recognition of need to urinate and conscious control of external urethral sphincter
Reflexive contractions of bladder cease after ~ 1 minute if urine is not voided
Cycle begins again after an additional ~ 200-300 ml of urine have accumulated
80. Disorders Incontinence inability to control micturition voluntarily
Bladder infection invasion of bladder by bacteria
Cystitis inflammation of the bladder
Renal calculi (kidney stones) crystallization of calcium, magnesium or uric acid salts in renal pelvis
Nephritis inflammation of the nephrons
Pyelonephritis inflammation of the kidney caused by bacterial infection
Anuria abnormally low urinary output caused by low glomerular blood pressure or renal failure
81. Disorders: Diabetes Excessive production of urine; differ in cause
Insipidus due to failure of ADH secretion
Mellitus due to lack of insulin (results in excess glucose in urine, which pulls water out)
Steroid diabetes excess of glucocorticoids cause persistent hyperglycermia that results in excess glucose in urine
