3 Corticopapillary Gradient and Countercurrent Exchange

Question 1

Outline the effect of water balance of plasma osmolarity

Answer 1

• Water intake < water excretion = plasma osmolarity ↑
• Water intake > than water excretion = plasma osmolarity ↓

Question 2

What is the value for normal plasma osmolarity?

Answer 2

280-310 mOsm/Kg (280-310 mmol/L)

Question 3

Outline the 2 different mechanisms of regulating plasma osmolarity in the body

Answer 3

Question 4

Which sensors in the body detect changes in plasma osmolarity?

Answer 4

Osmoreceptors – located in the Hypothalamus (OVLT)

Question 5

How do hypothalamic osmoreceptors act?

Answer 5

Signal secondary responses leading to two different complimentary outcomes:

• Concentration of urine
• Thirst

Question 6

Where is ADH produced?

Answer 6

Produced by neurosecretory cells in the hypothalamus

Question 7

What does ADH do?

Answer 7

ADH acts on the kidney to increase the permeability of the collecting duct to water and urea

Question 8

Describe the actions of ADH in terms of diuresis

Answer 8

• Low plasma ADH = diuresis
• High plasma ADH = anti-diuresis

Question 9

Describe the events occurring in the efferent pathway: ADH

Answer 9

• Released from posterior pituitary
• Released in conditions of predominant H₂O loss
• Renal H₂O excretion decreases
• Inhibited by decreased plasma osmolarity

Question 10

Identify and describe 2 clinical conditions which result from problems with ADH secretion

Answer 10

• Central diabetes insipidus: low plasma ADH levels
• Nephrogenic diabetes insipidus: acquired insensitivity of the kidney to ADH

Question 11

Identify 2 forms of clinical management for low plasma ADH

Answer 11

• ADH injections
• ADH nasal spray treatments

Question 12

Identify 5 different causes of low plasma ADH

Answer 12

• Damage to hypothalamus / pituitary gland
• A tumour
• An aneurysm
• Sarcoidosis
• Tuberculosis

Question 13

What is Syndrome of Inappropriate ADH secretion?

Answer 13

• SIADH is the excessive release of ADH from the posterior pituitary gland or another source e.g. small cell lung tumour
• Dilutional hyponatremia results

Question 14

Identify the different aquaporin channels and their location in the nephron

Answer 14

Question 15

In terms of aquaporins, explain how a lack of ADH secretion leads to diuresis

Answer 15

• No Aquaporin 2 in apical membrane
• No AQP 3 and 4 on basolateral membrane
• Limited water reuptake in DCT2 and collecting duct
• Hyposmotic urine produced

Question 16

Describe the relationship between haemodynamic and osmotic changes

Answer 16

Question 17

Large deficits in water are only partially compensated for in the kidney.

Describe the events occuring in the efferent pathway: thirst

Answer 17

• Induced by increases in plasma osmolarity or by decreases in ECF volume
• Thirst increases intake of free water
• Stops when sufficient fluid has been consumed

Question 18

How does the osmolarity of the nephron increase down the LoH?

Answer 18

• Descending limb of LoH is highly permeable to H₂O (AQP 1)
• Descending limb is not permeable to Na⁺
• Na⁺ remains in the lumen and filtrate concentration (osmolarity) increases

Question 19

Where is the maximum osmolality reached in the nephron?

Answer 19

Maximum osmolality is at apex of LoH = 1200 mOsm/Kg

Question 20

Explain how the thick ascending limb of the Loop of Henle generates the medullary gradient

Answer 20

• Ascending limb actively transports NaCl out of tubular lumen into interstitial fluid
• Ascending limb is impermeable to H₂O
• Filtrate is diluted and osmolarity of interstitium increases

Question 21

What is the osmolality of the filtrate at DCT1?

Answer 21

Fluid entering the DCT has low osmolality = 100 mOsm/Kg

Question 22

What is the juxtamedullary nephron what does it do?

Answer 22

• Juxtamedullary nephron is a long-looped nephron of 20% abundance
• It has importance in establishing the medullary vertical osmotic gradient

Question 23

What is the vertical osmotic gradient?

Answer 23

The vertical osmotic gradient is a gradient of increasing osmolarity established in the interstitial fluid of the medulla

Question 24

Describe 2 features of the vertical osmotic gradient

Answer 24

• Isotonic (300mOsm/Kg) at corticomedullary border
• Hyperosmotic in medullary interstitium up to 1200 mOsm/Kg at papilla

Question 25

Why is the vertical osmotic gradient an essential mechanism?

Answer 25

• Active NaCl transport in thick ascending limb
• Recycling of urea (effective osmole)

Question 26

What is an ineffective osmole?

Answer 26

If the membrane allows a solute to freely cross it, then the solute is totally ‘ineffective’ at exerting an osmotic force across this membrane

Question 27

Why is urea an effective osmole in the kidney?

Answer 27

Urea is hydrophilic and does not readily permeate artificial lipid bilayers

Question 28

In which circumstance would urea be an ineffective osmole?

Answer 28

In the presence of urea transporters which facilitate urea diffusion across most cell membranes

Question 29

Describe the recycling of urea in the kidney under the influence of ADH

Answer 29

• Urea is reabsorbed from the medullary CD
• Cortical CD cells are impermeable to urea
• Urea moves into interstitium and diffuses back in LoH to increase concentration gradient for H₂O reabsorption

Question 30

What is the Counter Current Multiplication?

Answer 30

Counter Current Multiplication is the increased osmolarity of the interstitial fluid surrounding the LoH due active transport of Na⁺

Question 31

What does the vasa recta do?

Answer 31

The vasa recta maintains the concentration gradient by acting as a counter-current exchanger

Question 32

How does the vasa recta act as a counter current exchanger?

Answer 32

Flow in vasa recta is in opposite direction to fluid flow in the tubule so the osmotic gradient is maintained

Question 33

Compare and contrast blood flow in the renal cortex and medulla

Answer 33

• Renal cortex: blood flow is one of the highest per gram of any tissue in the body
• Renal medulla: low blood flow (5-10% of total RPF)

Question 34

Explain why the renal medulla and cortex have contrasting blood flow

Answer 34

• Need to deliver nutrients to renal cortex (high blood flow)
• Need to maintain medullary hyper-tonicity (low blood flow)

Question 35

What happens in the descending limb of the vasa recta?

Answer 35

• Isosmotic blood in vasa recta enters hyperosmotic milieu of the medulla
• Na⁺, Cl^- and urea diffuse into the lumen of vasa recta
• Osmolarity in vasa recta increases as it reaches tip of hairpin loop

Question 36

What happens in the ascending limb of the vasa recta?

Answer 36

• Blood ascending towards cortex has a higher solute content than surrounding interstitium
• Water moves into vasa recta from the descending limb of the LoH