Sodium

Question 1

How does water move and its relation to sodium?

Answer 1

• Water will move from an area of low osmolality to an area of high osmolality
• As sodium moves, water will move

Question 2

What is the location of the Kidneys?

Answer 2

• Located between the 11th thoracic and 3rd lumbar vertebrae in the retroperitoneum on either side of vertebral column
• The right kidney is lower than the left kidney

Question 3

What are parts of the kidneys?

Answer 3

• Renal Capsule
• Renal Pelvis
• Ureter
• Renal Vein
• Renal Artery
• Renal Medulla
• Renal Cortex

Question 4

What is the gross anatomy of the kidneys?

Answer 4

• Dimensions: 13 x 6 x 4 cm
• Weight: ~150 g each
• Cardiac output: Receives 20 – 25% of which 90% supplies the renal cortex

Question 5

What are parts of the nephron?

Answer 5

Functional unit of kidney and contains approx 1 million

• Renal Artery and Vein
• Glomerular Capsule/Bowmans Capsule
• Proximal Convoluted Tubule
• Loop of Henle: Thin descending loop, Thin ascending loop, Thick Ascending loop
• Distal Convoluted Tubule
• Collecting Duct

Question 6

How does sodium reabsorption take place?

Answer 6

• <1% filtered Na+ is excreted in the urine
• Therefore, >99% filtered Na+ must be reabsorbed via a process of tubular reabsorptiom which involves PROTEIN CARRIERS and ION-SPECIFIC CHANNELS

Question 7

How does Sodium reabsorption take place in the Proximal Convuluted Tubule?

Answer 7

There is secondary active transport in PCT. Energy from basolateral through Na+-K+-ATPase. This creates favourable inward gradient for Na+

• Na+-H+ ANTIPORTERS: Most Na+ reabsorbed in exchange for H+. It also allows reabsorption of HCO3-
• Na+-SOLUTE CO-TRANSPORTERS: Allows simultaneous reabsorption of various organic & inorganic solutes

Question 8

How does the Loop of Henle absorb Sodium?

Answer 8

​Basolateral membrane

• Secondary active transport due to energy from basolateral Na+-K+-ATPase. This creates favourable inward gradient for Na+
• Cl- leaves cell via channel which creates favourable inward gradient for Cl-.

Apical membrane

• NKCC2 CO-TRANSPORTER: Na+ reabsorbed with K+ & 2x Cl-. Potassium is recycled back via ROMK1
• Mg2+ & Ca2+ REABSORPTION: K+ movement drives reabsorption of Mg2+ & Ca2+

Question 9

How does the Counter-Current System work?

Answer 9

• Descending limb is permeable to H2O and some NaCl
• The Ascending limb is impermeable to H2O and able to transport NaCl into the interstitium via NKCC2
• This helps create a gradient within the medulla that gets more concentrated as the loop enlongates.

Question 10

How does efficiency of the counter current system change?

Answer 10

• Efficiency depedns on the length of the loop of Henle
• JUXTAMEDULLARY NEPHRONS are more important for this process as they are longer
• Cortical nephrons make little contribution due to them being shorter in length

Question 11

How does the DCT reabsorb Sodium?

Answer 11

Basolateral

• Secondary active transport through energy from basolateral Na+-K+-ATPase. This creates favourable inward gradient for Na+
• Cl- leaves cell via channel which creates favourable inward gradient for Cl-

Apical

• Na+ reabsorbed with Cl-

Question 12

How does the Collecting Duct reabsorb Sodium?

Answer 12

• In CD, luminal concentration of Na+ can be lower than intracellular Na+ so can’t set up concentration gradient!!

APICAL SODIUM CHANNEL

• Na+ channel is electrogenic. Electronegativity allows Na+ entry into the cell. K+ is secreted simultaneously to balance charge
• Intracellular electronegativity generated by Na+-K+-ATPase
• Controlled by ALDOSTERONE

Question 13

Which conditions are diuretic prescribed?

Answer 13

• Hypertension
• Heart failure
• Liver cirrhosis
• Nephrotic syndrome

Question 14

What is the effect of Diuretics?

Answer 14

• Cause NEGATIVE FLUID BALANCE
• Decreases renal NaCl reabsorption and increases urinary losses of Na+ and therefore H2O

Question 15

What are the main classes of Diuretics?

Answer 15

• Loop Diuretics
• Thiazide Diuretics
• Potassium-sparing

Question 16

What is the action of Loop Diuretics?

Answer 16

Promote excretion of 20-25% filtered Na+ at max dose

• TARGET: Thick ascending limb of the Loop of Henle
• INHIBIT: NKCC2
• ACTION: Compete with Cl- for binding sites on NKCC2

Question 17

What is the action of Thiazide Diuretics?

Answer 17

Promote excretion of 3-5% filtered Na+ at max dose (Less potent than Loop Diuretics)

• TARGET: Distal convoluted tubule
• INHIBIT: NaCl cotransporter
• ACTION: Compete with Cl- for binding sites on NaCl cotransporter

Question 18

What are Potassium Sparing Diuretics?

Answer 18

Promote excretion of 1-2% filtered Na+ at max dose. Avoid renal K+ wasting

• TARGET: Principle cells of collecting duct
• INHIBIT: ENaC
• ACTION: Decrease the number of open Na+ channels inhibiting the channel directly (amiloride) or competitively inhibiting aldosterone binding to MR (spironolactone, eplenerone)

Question 19

What is the Renin-Angiotensin Alsoterone system?

Answer 19

• Renin released which cleaves angiotensinogen to angiotensin 1
• Angiotensin is converted to angiotensin 2 by the Angiotensin converting enzyme (ACE)
• Angiotensin 2 leads to proudction of Aldosterone which leads to sodium and water rentention.
• This leads to systemic volume expansion

Question 20

Where is Renin secreted from?

Answer 20

• Synthesized and secreted by juxtaglomerular cells which are part of juxtaglomerular apparatus (JGA
• They are specialised smooth muscle cells that are sensitive to arteriolar stretch ie. sense changes in ECF volume
• Sodium is the main determinant of Renin Secretion

Question 21

Where is ACE mainly found and which proteins does it act on?

Answer 21

Dipeptidyl carboxypeptidase highly concentrated in the lungs. It acts to cleave dipeptides from a range of substrates:

• Angiotensin I
• Bradykinin
• Substance P
• Enkephalins

Question 22

Describe the Angiotensinogen metabolism

Answer 22

Angiotensinogen

• 60 kDa, α2-globulin
• Produced by the liver
• Normally present in the plasma at a concentration of 1 mmol/L

Angiotensin 1

• Formed from the cleavage of a decapeptide from angiotensinogen which is catalysed by RENIN
• INACTIVE

Angiotensin 2

• Formed from the cleavage of a dipeptide from angiotensin I
• Catalysed by ACE
• ACTIVE

Question 23

What are the main effects of Angiotensin 2?

Answer 23

SYSTEMIC VASOCONSTRICTION

• Increases blood pressure

Na+ AND H2O RETENTION

Question 24

How does Angiotensin 2 increase Na+ and H2O retention?

Answer 24

• Stimulates ALDOSTERONE release
• Stimulates ADH release (­H2O retention)
• Increases tubular reabsorption of Na+ & H2O

Question 25

What is Aldosterone?

Answer 25

• Steroid hormone produced by the zona glomerulosa cells in the Adrenal Glands that acts as a mineralcorticoid
• Aldosterone freely diffuses into CD cells and binds to mineralocorticoid receptor (MR)

Question 26

What is the effect of Aldosterone?

Answer 26

• Increase in number of open Na+ channels so increased Na+ reabsorption & hence H2O reabsorption
• Increased Na+ transport out of cell via Na+-K+-ATPase so Intracellular K+ increases
• Increased K+ secretion as a result

Question 27

How can the RAAS mechanism be altered for therapy?

Answer 27

ACE Inhibitors (e.g. captopril, lisinopril, ramipril)

• Produce vasodilation by inhibiting production angiotensin II
• Block breakdown of bradykinin therefore increased levels contribute to vasodilator action of ACE-I

Angiotensin II receptor blockers (e.g. candesartan, losartan)

• Receptor antagonists, dilate arteries and veins reducing arterial pressure and load on heart
• Promote renal excretion Na and H2O

Aldosterone receptor blockers (e.g. spironolactone, eplerenone)

• Antagonise actions of aldosterone in DCT resulting in excretion of Na and H2O

Question 28

What is structure of ADH?

Answer 28

• Nonapeptide
• MW = 1084 Da
• Rapidly metabolized by Liver and Kidney
• t1/2 = 15 – 20 mins

Question 29

What is the role of ADH?

Answer 29

Decrease the amount of urine produced by increased reabsoprtion of H2O

Question 30

How is ADH synthesised and secreted?

Answer 30

Synthesized by HYPOTHALAMUS

• Supraoptic nuclei (SON)
• Paraventricular nuclei (PVN)

Secreted by:

• POSTERIOR pituitary

Question 31

What is action of ADH?

Answer 31

• Binds to ADH receptor (V2) in the kidneys
• This increases the aquaporin channels inserted into the apical membrane of the collecting duct
• This increases the amount of water reabsorption

Question 32

Where are ADH receptors located?

Answer 32

• V1(v1a): Located in smooth muscle of mesenteric artery. It causes vasoconstriction
• V2: Located in Kidney. It leads to anti-diuresis
• V3(v1b): Located in Pituitary Gland. It leads to release of ACTH

Question 33

What are ‘other’ causes of ADH secretion?

Answer 33

• Nausea
• Pain
• Surgery
• Pregnancy
• Angiotensin II
• Low Cortisol

Question 34

How is ADH secretion controlled?

Answer 34

• Increased Extracellular fluid osmolality: increase in plasma osmolality stimulates ADH release & thirst
• Decreased Extracellular fluid volume: decrease in plasma volume (without a change in osmolality) stimulates ADH release
• Others

Question 35

How does increased ECF osmolality cause ADH release?

Answer 35

• Increase ECF osmolality
• ALL cells in the body become dehydrated and ALL cells in the body shrink including hypothalamic osmoreceptors
• Loss of H2O from hypothalamic osmoreceptors leads to activation of “stretch-inactivated cation channels”
• There is depolarization of the cell
• This leads to stimulation of ADH secretion and synthesis

Question 36

How does decrease in ECF volume cause ADH release?

Answer 36

• Detect decrease ECF volume
• Massive increase in ADH secretion
• Maximum urine concentration achieved