Urinary System

Question 1

What does the urinary system consist of? (4)

Major organs etc

Answer 1

• 2 Kidneys: urine formation
• 2 Ureters: conduit to bladder
• Bladder: for storage of urine
• Urethra: elimination of urine from the body

Question 2

What are the 5 major functions of the kidney?

Answer 2

1. Excretion of metabolic wastes(urea, creatine, bilirubin, drugs, etc)
2. Regulation of water, BV, electrolyte balance
3. BP regulation: renin-angiotensin-aldosterone system
4. Regulation of acid-base balance
5. Production of hormones:Erthyropoietin/Vit D (Ca2+ absorption in small intestine

Question 3

Where are the kidneys located? Shape?

Answer 3

1. Paired bean shaped organs located-retro-peritoneally on the posterior abdominal wall
2. Paravertebral gutters-either side of the aorta and inferior vena cava
3. Left kidney T12-L3
4. Right kidney lower d/t liver being large

Question 4

What is the relations of the R Kidney?

Superiorly, Anteriorly, Posteriorly

Answer 4

• *Superior: *suprarenal glands
• Anteriorly: Liver, duodenum, ascending colon, hepatic flexure, jejunum
• Posteriorly: 12th rib, diaphragm, psoas major, quadratus lumborum, transversus abdominus muscle, iliohypogastric and ilioinguinal nerves

L also is located near rib 11

Question 5

What are the relations to the L Kidney anteriorly?

Superior/Posterior same for both kidneys

Answer 5

• Spleen
• Splenic flexure
• Stomach
• Pancreas
• Descending colon
• Jejunum

Question 6

What are the 3 layers and functions of the coverings of the kidneys?

Answer 6

1. Renal Capsule
   * Directly covers the renal cortex
   * Protects kidney from trauma and damage-penetrates kidney parenchyma to form trabeculae that lobulate the kidney
2. Perirenal fat
3. Renal fascia (Gerota’s fascia)
   * Encapsulates kidneys/suprarenal glands
   * Anchors kidney into surrounding structures
   * Divides the fat around kidney into perirenal fat/pararenal fat

Acts like a ligament

Question 7

Parenchyma of the Kidney: 2 layers-distinct features

Answer 7

1. Renal Cortex
   * Lies immediately beneath renal capsule
   * Extends inwards as the renal column between renal pyramids of the medulla and contains nephrons
2. Renal Medulla
   * Darker in colour with a striated appearance
   * Composed of 8-15 renal pyramids
   * Apex of pyramids directed into the sinus of the renal papilla
   * Structure of the papilla is perfored by the ducts of Bellini

Question 8

What is the nephron?

Answer 8

Functional unit of the kidney

Question 9

What are the two main structures in the nephron?

What are their subdivisions

Answer 9

1. Renal Corpuscle: filters blood
   * Glomerulus: capillary network
   * Glomerular capsule-double-walled cup surrounded glomerulus
2. Renal Tubule: filtered fluid passes into
   * Proximal convoluted tubule
   * Loop of Henle:divided into thin/thick for ascending/descending
   * Distal convoluted tubule

Question 10

What are the 3 basic functions of the nephron?

Answer 10

1. Glomerular Filtration: water and solutes in are filtered and moved into the glomerular capsule
2. Tubular Reapsorption:filtered fluid then moves through renal tubules and reabsorbed (99%)
3. Tubular Secretion: secretion of other materials such as wastes, drugs, and excess

Question 11

What are the two layers of the glomerular capsule and what are the cells associated with them?

Answer 11

1. Visceral layer:modified simple squamous epithelial cells (podocytes “toe like projections”)-forms the inner wall of the capsule
2. Parietal layer: simple squamous epithelium-forms the outer wall of the capsule

Question 12

Glomerular Filtration: 3 barriers to cross

Answer 12

1. Glomerular endothelial cells: fenestrations
2. Basal lamina: between endothelium and podocytes (fused together)
3. Pedicels of podocytes create filtration slits
   * Permits filtration of water/small solutes
   * Prevents filtration of most plasma proteins/blood cells/platelets

Question 13

How is the volume of fluid filtered so large? (3)

Answer 13

1. Large surface area
2. Thin and porous membrane
3. High glomerular capillary BP

Question 14

What are the 2 types of nephrons?

Answer 14

1. Cortical
2. Juxtamedullary
   * flow of fluid is the same except juxtamedullary has thin/thick ascending limb of the loop of henle

Question 15

Minor Calyx features (5)

Answer 15

1. Associated with a single renal pyramid
2. Cup-shaped and surrounds a renal papilla
3. Receives from renal papilla for passage into ureter
4. Delivers urine to the major calyx
5. Each kidney has 8-18 of them

Question 16

Renal Pelvis features (3)

Answer 16

1. Expanded upper end of ureters
2. Lies within the renal sinus
3. Connects 3-4 major calyces together to the ureter

Question 17

Circulation of blood in the Kidney

Answer 17

1. Abdominal Aorta
2. Segmental arteries
3. Interlobar arteries
4. Arcuate arteries
5. Cortical radiate arteries (interlobular)
6. Afferent arterioles
7. Glomerular capillaries
8. Efferent arterioles
9. Peritubular capillaries “vasa recta”
10. Cortical radiate veins
11. Arcuate veins
12. Interlobar veins
13. Renal veins
14. Inferior Vena Cava

Bolded is where exchange happens

Question 18

What renal vein is longer? Why?

Answer 18

Left-IVC is on the right side of the body-has to cross anteriorly to the abdominal aorta
* receives the left suprarenal vein and left gonadal veins

Question 19

What is the difference between Renal Hilum and Renal Sinus?

Answer 19

Renal Hilum: concavity located on medial border-where structures enter and leave. Contains renal vein, artery and pelvis of the ureter
Renal Sinus: cavity within kidney occupied by renal pelvis, calyces, blood vessels and fat

Question 20

Polycycstic Kidney Disease features and 2 types

Answer 20

• Inherited kidney disorder
• Tubules have >100 cysts which results in failure
  1. Autosomal dominant: renal failure late in life
  2. Autosomall recessive: renal failure in early life

TX: kidney transplant

Question 21

Renal Transplant things to know (2)

Answer 21

• Placed in the pelvis of the recipient-renal artery and vein are attached to a nearby artery and vein
• Transplant ureter attached to the bladder
• Diseased kidneys are left in place

Question 22

Ureter features

Answer 22

1. Musucular tube from renal pelvis to posterior surface of bladder
2. Approx 10 inches long
3. Retroperitoneal descends on the anterior surface of the psoas major muscle
4. Passes anterior to the bifurcation of the common iliac artery before descending into pelvis

Question 23

What are the 3 constriction points of the ureters?

Answer 23

1. Ureteropelvic Junction
2. Where is crosses the pelvic brim
3. Pierces bladder wall

Question 24

Histology of the Ureter

3 layers

Answer 24

1. Mucuosa: transitional epithelium-stratified epithelium which can stretch, lamina propria
2. Muscularis 3 layers: Inner longitudinal, middle circular, outer longitudinal
3. Adventitia

First 2/3 of muscularis is: Inner longitudinal, outer circular

Question 25

What ligament attaches to the bladder?

Answer 25

Median Umbilical ligament (Urachus)

Question 26

Histology of the bladder

3 layers

Answer 26

1. Mucuosa: transitional epithelium-stratified epithelium which can stretch
   * dense lamina propria
2. Muscularis 3 layers: Inner longitudinal, middle circular, outer longitudinal
3. Adventitia: adipose tissue

Question 27

Bladder Cancer things to know (4)

Answer 27

1. More prevalent in males
2. Hematuria
3. Cytoscopy used to examine structures-take biopsy
4. Favourable prognosis if identified early

Question 28

External/Internal Urethral Sphincters

Answer 28

1. Internal
Smooth muscle
Parasympathetic/Symphatethic
2. External
Skeletal muscle
Somatic (pedundal)
Membranous urethra

Question 29

Histology of the Urethra

Answer 29

1. Mucosa
   Transitional (early)
   Stratified columnar (middle)
   Stratified squamous (end)
2. Muscularis: thin layer of circular smooth muscle
3. Thin layer of connective tissue

Question 30

Urinary Incontinence definition and 4 types

Answer 30

1. Stress incontinence
   Weakness of deep muscles in pelvic floor-occurs when abdo pressure increases
2. Urge incontinence
   Abrupt and intense urge to urinate-involuntary loss of urine
3. Overflow incontinence
   Bladder becomes overfilled-dribbles out
4. Functional incontinence
   Person is aware they need to void-cant reach a toilet in time (stroke, ALZH)

Definition: lack of voluntary control of micturition

ALZH-alzheimers

Question 31

Micturition Reflex
“How do we pee”

Answer 31

• Combination of voluntary/involuntary muscle contractions
• Stretch receptors in the wall transmit nerve impulses when bladder exceeds 200-400 mL
• Impulses then propagate to the micturition center in the sacral spinal cord S2-S3 and trigger micturition reflex
• Nerve impulses cause contraction of detrusor muscle and relaxation of internal urethral sphincter
• Contraction of urinary bladder wall-relaxation of spincters-urination

Micturition center inhibits skeletal muscle in the external sphincter

Question 32

Glomerular Filtrate Definition

Amount per day

Answer 32

Volume of fluid that enters the Bowman’s capsule from the glomerular capillaries

• *Daily volume is 150-180L

Question 33

Filtration Fraction definition

Answer 33

Fraction of blood plasma in the afferent arterioles of the kidneys that becomes glomerular filtrate

Question 34

How much plasma that flows through the kidneys actually flow through the nephrons?

Answer 34

• 1/5-99% of that is returned to blood plasma via tubular reabsorption

Question 35

Glomerular filtration 3 pressures

Answer 35

1. Glomerular blood hydrostatic pressure (GBHP): blood pressure in glomerular capillaries
2. Capsular hydrostatic pressure pressure exerted against the filtration membrane by fluid already in the capsular space and renal tubule
3. Blood colloid osmotic pressure (BCOP) osmotic pressure due to proteins in the blood plasma

Question 36

Net Filtration equation

Answer 36

NFP=GBHP-CHP-BCOP
55mmHg-30mmHg-15mmHg=10mmHg NET

Pressure is the total pressure that promotes filtration

Question 37

What is the average GFR in males/females

Answer 37

1. MALES: 125mL/min
2. FEMALES: 105mL/min

Any net change in net filtration pressure will affect GFR

Question 38

What are the 3 Mechanisms Regulating GFR

Not indepth

Answer 38

1. Renal Autoregulation: very important for kidneys to do this on their own
2. Neural regulation
3. Hormonal regulation

Question 39

Renal Autoregulation 2 main types

Answer 39

1. Myogenic Mechanism: occurs when stretching triggers contraction of smooth muscle cells in afferent arterioles-reduces GFR. Normalizes GFR in seconds
2. Tubulo-glomerular mechanism: Acts more slowly. Uses JGA apparatus

Question 40

Juxtaglomerular Apparatus (JGA)

3 types of cells w/ functions

Answer 40

1. Macula densa (osmoreceptors): * Found by the vascular poles (afferent/efferent arterioles).
   * Sense changes in Na+ concentration within lumen of distal tubule and send signals to the JG cells.
   * Modified cells of the DCT (narrower and taller)
2. JG cells:
   * Modified smooth muscle fibers found in walls of afferent/efferent arterioles
   * Produces renin-cleaves angiotensinogen to angiotensin 1
3. Extraglomerular mesangial cells:
   * ?contract to open afferent/efferent arterioles

Question 41

Tubuloglomerular Feedback Loop

When GFR is elevated d/t systemic blood pressure

Answer 41

1. Filtered fluid flows more rapidly along the renal tubules
2. Results in less time to reabsorb Na+, Cl-, H20
3. Macula densa cells detect the electroyle levels
4. Inhibit release of NO from JGA
5. Afferent arterioles constrict d/t low levels of NO
6. Results in less blood flow into glomerular capillaries and GFR decreases

Question 42

Neural Regulation of Kidney

(3)

Answer 42

1. Kidney blood vessels supplied by sympathetic autonomic nervous system fibers that release norepinephrine causing vasoconstriction
2. Moderate stimulation: both afferent/efferent arterioles constrict equally=minimal decrease in GFR
3. Greater stimulation: constriction of afferent arteriole is dominate=decrease blood flow into capillaries–>significant GFR decrease

Question 43

Hormonal Regulation (2)

Answer 43

1. Angiotensin II reduces GFR: potent vasoconstrictor of both afferent/efferent
2. ANP increases GFR: stretching of atria d/t increased BV causes release of this hormone. ANP relaxes intraglomerular mesangial cells-increases capillary surface area for filtration

Question 44

Reabsorption Routes (2)

Answer 44

1. Paracellular Reabsorptions: fluid can leak between the cells in a passive process in the PCT
2. Transcellular Reabsorption: substances pass from the tubular lumen through the apical membrane of a tubule across the cytosol and into the interstitial fluid through basolateral membrane

Question 45

Transport Mechanisms (2)

Answer 45

1. Primary Active Transport: energy is derived from hydrolysis of ATP and used to pump substances across the membrane (NA+K+ATPase)
2. Secondary Active Transport: energy is stored in the electrochemical gradient
   * Symporters: same direction movement
   * Antiporters: opposite direction across the membrane

Question 46

Water Reabsoprtion 2 types

Answer 46

1. Obligatory Water Reabsorption: water follows solutes and is “obliged” to follow solutes when they are reabsorbed-occurs in PCT and descending limb of the nephron loop
2. Facultative Water Reabsorption: Reabsorption of the final 10% of the water-regulated by ADH occurs in the collecting ducts

Question 47

Proximal Convoluted Tubule Reabsorption

Simple Cuboidal w/ extensive microvilli

Answer 47

1. Largest amount of solute and water reabsorption from filtered fluid occurs here
   * 65% of filtered water, sodium, potassium
   * 100% of organic solutes (glucose and amino acids)
   * 80-90% of the filtered bicarbonate (important buffer)
   * 50% of filtered urea
   * Variable amount of filtered Ca2+, Mg2+, phosphate
   * Secrete variable amount of H+, ammonium ions, and urea
2. Most solute reabsorption involves Na+ (symporters/antiporters)

At the end of the PCT, tubular fluid is isosmotic-300mOsm/liter

Question 48

How many Sodium molecules are attached to glucose in the PCT symporter process?

Also process

Answer 48

2-carries them from tubular fluid into the tubule cell.
* Glucose then exit via facilitated diffusion-diffuse into the peritubular capillaries
* This is a similar process for phosphate, sulphate ions, ALL amino acids and lactic acid

Question 49

How does the PCT cells produce H+ to keep the antiport system running?

Formula

Answer 49

C02 +H20–carbonic anhydrase–>H2CO3–>H+ + HCO3-

Question 50

Reabsorption of the solutes in the PCT create what?

Answer 50

An osmotic gradient that *promotes reabsorption of water via osmosis

• With water leaving the concentration of the remaing filtered solutes increase

Question 51

What happens in the second half of the PCT electrochemical gradients?

Answer 51

Cl-, K+, Ca2+, Mg 2+ and urea passively diffuse into the peritubular capillaries via both paracellular and transcellular routes

Question 52

Is any water reabsorbed in the ascending loop of henle?

Answer 52

NO-impermeable to H20
This causes the osmolarity to progressively decrease as the fluid moves towards the end of the ascending limb

Question 53

What is reabsorbed in the Loop of Henle?

Answer 53

*Note: Chemical composition of fluid entering is different from the filtrate but the osmolarity is very close to blood

Reabsorbs: 15% of filtered H20
* 20-30% of filtered Na+/K+
* 35% of Cl-
* 10-20% of HCO3-

Question 54

What is the major site that the parathyroid hormone works on?

Answer 54

Early Distal Convoluted Tubule

Question 55

Late distal convoluted tubule & collecting duct

Simple cuboidal epithelium w/ principal cells and intercalated cells

Answer 55

*Amount of water reabsorption/secretion depends on body’s needs

1. Principal cells reabsorb Na+ and secrete K+
2. Na+ leakage channels in apical membranes of principal cells
3. Intercalated cells reabsorb K+ and HCO3 and secrete H+

Question 56

Hormonal Regulation of Tubules: Angiotensin II

Answer 56

• Increases reabsorption of Na+, Cl- and H20 in the PCT by stimulating Na+/H+ antiporters
• Constricts afferent arterioles, decreases GFR
• Stimulates aldosterone release from adrenal cortex (glomerulosa)

Question 57

Hormonal Regulation of Tubules: ADH

Answer 57

Increases H20 reabsorption by increasing the water permeability of principal cells allowing water to move more rapidly from tubular fluid in the cells

Aquaporin II

Question 58

Hormonal Regulation of Tubules: PTH

Answer 58

• Increases Ca+reabsorption in the DCT
• Decreases phosphate reabsorption

Question 59

Hormonal Regulation of the Tubules: ANP

Answer 59

• Increase in BV causes stretch in atria and release of ANP
• Decreases Na+ and water reabsorption in PCT and collecting duct (increases GFR)
• Suppresses the secrtion of Aldosterone/ADH
  RESULTS: Decreases BV and BP

Question 60

Hormonal Regulation of the Tubules: Aldosterone

Answer 60

• Na+ reabsorption and K+ secretion in late DCT and collecting duct

Question 61

Evaluation of Kidney Function: Urinalysis

Answer 61

• Total urine volume, water, electrolytes, drugs toxins etc
• If disease alters metabolism or kidney functions, abnormal amounts may appear

Question 62

Evaluation of Kidney Function: Blood tests

Answer 62

1. BUN
2. Cr

Question 63

Evaluation of Kidney Function: Renal plasma clearance

Answer 63

Most useful in diagnosis of kidney problems
A substance that is filtered but neither reabsorbed or secreted has a clearance that equals GFR

Question 64

Histology of Renal Tubule and Collecting Duct

Answer 64

PCT: Simple cuboidal epithelial cells w/ prominent microvilli
Nephron loop (descending limb and thin ascending: simple squamous epithelial
Nephron loop (thick ascending limb: simple cuboidal to low columnar epithelial cells
DCT Simple cuboidal epithelial cells
DCT last part/collecting duct: simple cuboidal epithelium w/ principal cells and intercalated cells

Question 65

Renin-Angiotensin-Aldosterone

Answer 65