Renal phys.

Question 1

What 3 layers make up the glomerular filtration barrier?

Answer 1

1. Fenestrated endothelium of glomerular capillaries
2. Inner epithelial layer of Bowmans capsule
3. Intervening basal lamina

Question 2

What molecules are/aren’t able to pass through the glomerular filtration barrier?

Answer 2

• Water and small molecules can pass through
• Plasma proteins and blood cells cannot

Question 3

What are the 5 components of the filtration pathway?

Answer 3

1. Capillary endothelium
2. Fenestrae of glomerular capillaries
3. Basal lamina
4. Slits between podocytes
5. PCT lumen

Question 4

Which one plasma protein is normally filtered by the glomerulus?

Answer 4

Albumin

Question 5

What are 4 factors affecting glomerular filtration?

Answer 5

1. Back pressure - hydrostatic prssure in Bowman’s space forcing material back towards the capillary; not significant though
2. Capillary oncotic pressure - exceeds back pressure, material moves into Bownman’s space
3. Bowman’s space oncotic pressure - negligible
4. Capillary pressure - high

Question 6

What is the net filtrate pressure?

Answer 6

cap. pressure - back pressure - oncotic pressure

= 50 - 10 - 30

= 10mmHg

Question 7

Define the glomerular filtration rate

Answer 7

Volume of fluid filtered per minute from glomerular capillaries into Bowman’s space.

It is the product of the net filtration pressure across the glomerular filter ad filtration coefficient (Kp).

Question 8

What are 3 factors regulating GFR?

Answer 8

1. Autoregulation
2. Angiotensin II
3. Sympathetic input to kidneys

Question 9

Explain the effect of autoregulation on GFR

Answer 9

• Resistance in afferent arterioles can be altered in response to changes in blood pressure
• Smooth muscle in arteriole walls automatically constrict when arterial BP is high & dilate when it is low - stabilises perfusion & filtration
• Increased arterial BP temporarily increases blood flow and GFR - fluid flow in nephron monitored by chemicals in macula densa which signal to SM in arterioles to constrict (decreased blood pressure has opposite effect)
• Prevents potentially large changes in GFR and urine output

Question 10

Explain the effect of angiotensin II

Answer 10

• Acts on efferent arteriole

1. Decreased arterial BP, juxtaglomerular cells release renin
2. Renin converts angiotensinogen to angiotensin I
3. Angiotensin I converted to angiotensin II in lungs
4. Angiotensin II constricts all arterioles in body, acts on adrenal gland to increase aldosterone secretion
5. Efferent arteriole in kidney constricts, increasing glomerular HP, allowing filtration to continue

* aff. & eff. constriction, decrease HP peritubular capillaries, promote tubular reabsorption, normalise ECV & arterial BP in hypotension

Question 11

Explain the sympathetic effects on GFR

Answer 11

Similar to action of angiotensin II

Question 12

What characterises PCT activity?

Answer 12

• Iso-osmotic reabsorption
• Delivery of iso-osmotic product to loop of Henle
• 66% reabsorption

Question 13

Describe the reabsorption of Na in PCT

Answer 13

1. Na simply diffuses into tubular epithelium from tubular lumen
2. Na exchanged for K in an E independant process on the basolateral membrane. Na enters interstitial fluid
3. Water follows Na reabsorption, an inreased oncotic pressure in peritubular capillaries enables water to be easily reabsorbed

Question 14

Describe the reabsorption of glucose from the PCT

Answer 14

1. Glucose cotransported with Na from lumen into epithelial cells using E released when Na is transported across apical membrane
2. Glucose transported by facilitated diffusion across basolateral membrane into interstitial fluid
3. From here diffuses into capillary lumen

• 100% glucose normally reabsorbed

Question 15

What is ‘Tm’?

Answer 15

Tubular maximum - max. amount of glucose that can be reabsorbed

Question 16

What happens to protein and phosphate in the PCT?

Answer 16

• Protein reabsorbed by endocytosis
• PTH inhibits reabsorption of phosphate so is excreted in urine

Question 17

What characterises the activity of the loop of Henle?

Answer 17

• Recieves iso-osmotic filtrate from PCT
• Only the thick limb is metabolically active

Question 18

Describe the processes that occur in the loop of Henle

Answer 18

1. Ascending thick limb impermeable to water, pumps out 25% Na, Cl, K, Mg
2. Causes water to be drawn out of thin descending limb - 25% - & CD
3. Descending limb becomes hyperosmolar

Question 19

What characterises DCT activity?

Answer 19

• Receives 9% of total glomerular filtrate
• All activities are hormonally regulated

Question 20

Describe the processes that occur in the DCT

Answer 20

1. Receives hypo-osmotic filtrate from loop of Henle
2. Aldosterone causes selective Na reabsorption
3. Na exchanged for K, urine Na content reduced to < 1%
4. Water reabsorbed
5. PTH stimulates final Ca reabsorption
6. CT inhibits Ca reabsorption

Question 21

Describe the processes that occur in the CD

Answer 21

Initial section:

1. Sensitive to aldosterone, maintains Na reabsorption via Na/K exchange
2. Allows for variable amounts of K to be excreted in urine

Deep medullary section:

• Water reabsorption - satisfy Na:water in ECF
• Hypothalamus controls this by:

1. thirst - (dehydration) - Na conc. increases in ECF as water is lost, water moves out of osmoreceptor cells, shrink, hypothalamus stimulates thirst & ADH secretion
2. ADH - increases CD water permeability, water drawn into medulla, returns to ECF, Na conc. decreases, osmoreceptor cells return to original turgor

• Reabsorption of water causes reabsorption of urea; contributes to osmotic gradient drawing more water out

Question 22

What happens during hypovolaemia?

Answer 22

1. Low arterial BP acts on arterial baroreceptors to activate sympathetic NS
2. Juxtaglomerular apparatus stimulated to secrete renin
3. Directly overrides autoregulation to cut GFR to preserve plasma volume
4. Renin activates angiotensin pathway
5. Thirst and ADH stimulated
6. Water and Na conserved to increase ECV and increase BP

Question 23

What happens during hypervolaemia?

Answer 23

1. Sympathetic NS low tone, JG low activity, low renin activity
2. High blood volume detected by baroreceptors in R atrium, trigger atrial natriuretic hormone, inhibits aldosterone
3. Low PCT reabsorption
4. ADH inhibited
5. Urine has low specific gravity