Sodium and Potassium Balance

Question 1

What is osmolarity?

Answer 1

Osmolarity is a measure of the solute (particle) concentration in a solution (osmoles/litre).
1 osmole = 1 mole of dissolved particles per litre (1 mole of NaCl = 2 moles of particles in solution).

Question 2

Which ion is the most prevalent in plasma?

Answer 2

Sodium

Question 3

What is the average osmolarity of sodium in plasma?

Answer 3

140mmol/L

Question 4

What the normal plasma osmolarity?

Answer 4

285-295

Question 5

What is the effect of an increase in dietary sodium?

Answer 5

The increase in the amount of sodium within the extracellular fluid will result in an increase in water retention –> Weight increase

There is a plateau in body weight gain

A reduction in dietary sodium causes a negative balance

Question 6

What is the physiological response to an increase in total body sodium?

Answer 6

Increased water intake and retention in response to an increase in osmolarity (Must be maintained within a homeostatic end point)
This increases the ECF volume and subsequently blood pressure

Question 7

Which nucleus within the brainstem regulates sodium intake?

Answer 7

Lateral parabrachial nucleus

Question 8

What is the definition of euvolemia?

Answer 8

Inhibition of sodium intake (Activity of serotonin and glutamate)

Question 9

Which hormones are involved with the inhibition of sodium intake?

Answer 9

Serotonin and glutamate

Question 10

Which neurotransmitters are responsible for increasing the appetite for sodium?

Answer 10

GABA and opioids

Question 11

Describe how dietary sodium intake is influenced at lower levels?

Answer 11

Enhances the taste of food

Question 12

Describe the peripheral mechanism for regulating dietary intake?

Answer 12

Bimodal

Question 13

At high concentrations of meal sodium, what is the impact?

Answer 13

Aversive

Question 14

In euvolaemia, what is the response to sodium intake?

Answer 14

Inhibition of sodium intake

Question 15

Where is the majority of sodium ions reabsorbed within the nephron?

Answer 15

Proximal convoluted tubule (67%)

Question 16

What proportion of sodium ions are reabsorbed in the proximal convoluted tubule?

Answer 16

67%

Question 17

What proportion of sodium is reabsorbed in the thick ascending limb of the loop of Henle?

Answer 17

25%

Question 18

Which transporter is responsible for sodium reabsorption within the thick ascending limb?

Answer 18

Na-K-Cl triple transporter

Question 19

How is sodium reabsorbed within the distal convoluted tubule (transporter)?

Answer 19

Na-Cl transporter

Question 20

Which transporter is concerned with the reabsorption of sodium within the collecting ducts?

Answer 20

Sodium channel ENAC

Question 21

If the GFR increases, what happens to the proportion of sodium that is filtered?

Answer 21

Remains the same (amount increases)

Question 22

What approximate proportion of renal plasma enters the tubular system?

Answer 22

20%

Question 23

What happens to renal perfusion flow with increasing blood pressure?

Answer 23

• 100mgHG RPF does not increase with increasing blood pressure –> There is a plateau effect to minimise electrolyte and water loss.

Question 24

Where is the macula densa located?

Answer 24

Within the proximal part of the distal convoluted tubule separated from the glomerulus by extraglomerular mesangial cells and JG cells

Question 25

Which two cells are concerned with the macula densa?

Answer 25

Extralglomerular mesangial cells

JG cells

Question 26

Above a sodium tubular threshold, what happens in terms of the macula densa?

Answer 26

The macula densa releases adenosine and ATP,

activating receptors in the extraglomerular mesangial cells

Question 27

Above a tubular sodium threshold what is released by the macula densa?

Answer 27

Adenosine

ATP

Question 28

What are the consequences in response to a high tubular sodium?

Answer 28

In the long term - reduces renin production
Stimulates the contraction of the smooth muscles of the afferent arteriole - to reduce renal plasma flow and a reduction in perfusion pressure- this prevents the loss of sodium and fluid

Question 29

Which cells secrete renin?

Answer 29

Juxtaglomerular cells (JG)

Question 30

What effect does sympathetic stimulation have on tubular sodium regulation?

Answer 30

Increases uptake of sodium by the cells of the proximal convoluted tubule
Promotes the contraction of smooth muscle in the afferent arteriole to reduce GFR
Increased renin secretion

Question 31

How is an increase in renin promoted by the sympathetic system?

Answer 31

Sympathetic stimulation increases the uptake of sodium by the cells in the proximal convoluted tubule.
• Activity of the sodium proton exchanger increases (relies on RAAS).
• Production of renin by the juxtaglomerular cells
• Reduce sodium reaching the distal tube (measured at the JGA). This reduces the production of adenosine from the Macula densa, thus there is reduced inhibition of renin release from the JG cells.

Question 32

What effect does the sympathetic system have on extraglomerular cells?

Answer 32

: Sympathetic activity overrides the effect of extraglomerular cells SMC relaxation of the afferent arteriole – There is an overall contraction of smooth muscle and reduced GFR.

Question 33

What is the effect of renin?

Answer 33

Converted into angiotensin-II by RAAS, angiotensin-II is a potent vasoconstrictor that increases vascular resistance and stimulates sodium uptake in the PCT

Question 34

Where does angiontensin-II act within the nephron?

Answer 34

Promotes sodium reabsorption within the proximal convoluted tubule

Question 35

What hormone is produced by the stimulation of angiontensin-II on the adrenal cortex?

Answer 35

Stimulates the synthesis of aldosterone

Question 36

Where does aldosterone act on the nephron?

Answer 36

Stimulates sodium uptake in the DCT and collecting duct

Question 37

Which peptide opposes increased sodium retention/reabsorption?

Answer 37

Atrial natruiretic peptide

Question 38

What does ANP do to the nephron?

Answer 38

Promotes dilation of the afferent arteriole, inhibits renin release and reduces sodium uptake in the PCT, DCT and CT

Question 39

In response to low plasma sodium, what happens?

Answer 39

• Upregulation in sympathetic activity – contraction of afferent arteriole SMC.
• Reduced GFR  Reduced delivery of sodium and water to the nephron
• Increased renin production  Angiotensin-II and aldosterone synthesis
• Renal NaCl and water reabsorption to reduce volume loss
• Vasoconstriction  Increase blood pressure

Question 40

What type of hormone is aldosterone?

Answer 40

A steroid

Question 41

Where within the adrenal cortex is aldosterone produced?

Answer 41

Zona glomerulosa

Question 42

Which enzyme is activated by angiotensin-II, in order to synthesise aldosterone?

Answer 42

Aldosterone synthase

Question 43

What is the function of aldsoterone?

Answer 43

• Increased sodium reabsorption (Control’s reabsorption of 35g Na/day)
• Increased potassium secretion (A consequence of sodium reabsorption).
The change in voltage promotes an indirect stimulation of proton secretion, there are additional direct effects of aldosterone on the secretion of proton via alterations in the expression of anion exchanges as H+-ATPase.
• Increased hydrogen ion secretion

Question 44

in which cells does aldosterone have an impact on regarding sodium reabsorption?

Answer 44

Principal cells

Question 45

In which cells does aldosterone have an impact on regarding proton secretion?

Answer 45

Intercalated cells

Question 46

An excess of aldosterone can mediate as what?

Answer 46

Hypokalaemia alkalosis

Question 47

Which types of receptors does aldosterone bind onto?

Answer 47

Intracellular mineralocorticoid receptors

Question 48

Which protein dissociates from intracellular mineralocorticoid receptors upon aldosterone binding?

Answer 48

HSP90

Question 49

Upon HSP90 dissociation what happens to the aldosterone-MR complex?

Answer 49

Dimerises

Question 50

What function is performed by aldosterone-MR complexes?

Answer 50

Translocates to the nucleus, binding to promoter regions downstream to target genes, stimulating expression/transcription

Question 51

How does aldosterone increase sodium reabsorption within the cortical collecting duct?

Answer 51

Increases the transcription and ultimate synthesis of ENaC (epithelial sodium channel)

• Coordinates increase in the number of sodium transporters, and their activity thereby increasing sodium reabsorption.

Question 52

What pathologies or iatrogenic causes are linked with hypoaldosteronism?

Answer 52

NSAIDs, lead poisoning, diabetes and kidney disease

Question 53

What are the impacts of hypoaldosteronism?

Answer 53

Reabsorption of sodium in the distal nephron is reduced manifesting as hyponatremia

Increased urinary loss of sodium

ECF volume falls - incresed renin, angiotensin-II and ADH

Hyperkalaemia and alkalosis

Question 54

What are the symptoms associated with hypoaldosteronism?

Answer 54

Dizziness
Low blood pressure
Salt carving
Palpitations

Question 55

What is hyperaldosteronism?

Answer 55

A disorder manifested by the hypersecretion of aldosterone from the adrenal gland

• adrenal tumours

Question 56

What occurs due to hyperaldosteornism?

Answer 56

Hyperaldosteronism increases the reabsorption of sodium in the distal nephron. 
•	Reduced urinary loss of sodium. 
•	ECF volume increases (Hypertension)
•	Reduced renin, Angiotensin-II, ADH
•	Increased ANP and BNP

Question 57

What the symptoms associated with hyperaldosteronism?

Answer 57

• High blood pressure
• Muscle weakness
• Polyuria –> Consequence of thirst and increased drinking.
• Thirst

Question 58

What is Liddle’s syndrome?

Answer 58

An inherited disorder characterised by chronic hypertension and exhibits the same phenotype of hyperaldosteronism (despite normal to low levels of aldosterone).
• Mutation in the aldosterone activated sodium channel (Alters re-internalisation and degradation of the channel, or opening time of the channel  Increasing likelihood of it being open).
• ENaC activity has overall increased (always ‘on’).
• Results in sodium retention  Leading to hypertension

Question 59

Which receptors detect pressure?

Answer 59

Baroreceptors

Question 60

Which protein channel is always on in Liddle’s syndrome?

Answer 60

ENaC

Question 61

What is the aldosterone level in Liddle’s syndrome?

Answer 61

Normal to low

Question 62

Which brainstem centre regulates blood pressure?

Answer 62

Cardio-regulatory centre

Question 63

What is the tonic frequency of baroreceptor firing rate?

Answer 63

baroreceptor firing of receptors which tonically suppress sympathetic activity

Question 64

What happens due to reduced baroreceptor firing?

Answer 64

There is an upregulation in sympathetic activity and ADH release

Question 65

What happens to the heart rate and stroke volume in response to reduced baroreceptor firing?

Answer 65

Increases (SAN and ventricular cardiomyocytes have sympathetic post-ganglionic neurones)

Question 66

Which peptides are released in response to high pressure?

Answer 66

ANP and BNP, synthesised in response to atrial stretch

Question 67

What is ANP?

Answer 67

A small peptide synthesised within the atria (In addition to BNP)

Question 68

When his ANP released?

Answer 68

In response to atrial stretch due to high blood pressure, and circulates in blood where it binds to complementary receptors

Question 69

Which enzyme is activated in response to ANP?

Answer 69

Protein kinase G

Question 70

What effect occurs by ANP stimulation?

Answer 70

Vasodilation to reduce blood pressure (renal and systemic vessels)

Inhibition sodium reabsorption in the distal nephron

Inhibits renin and aldosterone release

Question 71

What is the overall effect from ANP stimulation?

Answer 71

Reduces blood pressure

Question 72

What is volume expansion?

Answer 72

An increase in plasma sodium, increasing blood pressure and ECF volume

Question 73

What effect does reduced sympathetic activity have on GFR?

Answer 73

Afferent arteriole dilation increasing GFR (to increase sodium and water delivery)

• Reduces sodium uptake in the PCT and reduce renin-angiotensin and aldosterone levels to reducing sodium reuptake in the distal nephron.
• Reduced sodium reabsorption –> Reduced water reabsorption (excretion of both).

Question 74

What effect does ANP have on ADH?

Answer 74

Suppresses the release of ADH

Question 75

Which ion determines ECF volume?

Answer 75

Sodium

Question 76

What is the mechanism of action of ACE-inhibitors?

Answer 76

Reduce the conversion of angiotensin-I to angiotensin-II

Question 77

What are the vascular effects of ACEi?

Answer 77

Vasodilation - increasing the vascular volume to accommodate and reduce blood pressure

Question 78

What are the diuretic effects of ACEi?

Answer 78

Reduces sodium uptake in the PCT

Question 79

What effect does ACEi have on aldosterone?

Answer 79

Reduced aldosterone - reduced sodium reabsorption

Question 80

How does mannitol work?

Answer 80

• Add substrate that cannot be reabsorbed + increase tubular osmolarity to promote water retention in the filtrate.

Question 81

What is a carbonic anhydrase inhibitor?

Answer 81

Carbonic anhydrase activity leads to sodium uptake and proton export in the PCT (urinary acidity)
• Inhibitors –> Inhibits sodium uptake into PCT cells, leading to a greater concentration of sodium in the distal nephron.
• Reduced difference between the tubular and interstitial osmolarity  Reduces water reabsorption.

Question 82

What is the mechanism of action of loop diuretics?

Answer 82

Loop diuretics target the triple transporter in the ascending limb of the loop of Henle.
• Inhibit sodium uptake – leading to higher levels of sodium in the distal nephron
• Reduction in the osmolarity of the interstitial fluid.
• Reduce the difference between the tubular and interstitial osmolarity – reduce water reabsorption.

Question 83

What type of diuretic is furosemide?

Answer 83

Loop diuretic

Question 84

What is the target and location of thiazides?

Answer 84

Sodium chloride transporter

Distal convoluted tubule

Question 85

What is the effect of thiazides?

Answer 85

Reduces sodium uptake and increases tubular sodium concentration

Question 86

What is the side effect concerned with thiazides?

Answer 86

increase in calcium reabsorption

Question 87

Why is there an increase in calcium reabsorption with using thiazides?

Answer 87

Calcium is reabsorbed across the lumen membrane down its concentration gradient that is generated by the activity of the sodium calcium exchanger

Blocking the entyr of sodium into the cell through the Na-Ca exchanger , whilst the Na-K still works means that the return of sodium into the cell via the Na-Ca is increased

This reduces sodium calcium concentration in the cell and therefore increases the potential for calcium to be removed from the tubular fluid

Question 88

How do potassium sparing diuretics work?

Answer 88

Inhibitors of aldosterone function (Spironolactone as a MR antagonist)

Decreases sodium reabsorption and subsequently water retention is impaired

Question 89

What risk is associated with Spironolactone?

Answer 89

Hyperkalaemic acidosis

Question 90

Which is the main ion intracellularly?

Answer 90

Potassium

Question 91

How is a high intracellular potassium ion maintained?

Answer 91

By the sodium potassium ATPase

Question 92

What effect does high K+ have?

Answer 92

Depolarises membrane, action potentials, heart arrhythmias (Tented T waves).

Question 93

What effect does a low K+ have?

Answer 93

Heart arrhythmias (asystole)

Question 94

What effect does insulin have on potassium?

Answer 94

Plasma insulin mediates the tissue uptake of potassium

Question 95

How does insulin mediate increased potassium uptake?

Answer 95

Stimulates the activity of the sodium proton exchanger which increases intracellular sodium

The increase in intracellular sodium activates sodium potassium ATPase, increasing potassium uptake

Question 96

What % of filtrate potassium is reabsorbed in the proximal convoluted tubule?

Answer 96

67%

Question 97

Which factors influence plasma secretion?

Answer 97

Plasma potassium, aldosterone, tubular flow rate , and plasma pH

Question 98

Which cells are responsible for plasma potassium?

Answer 98

Principal cells

Question 99

How do principal cells increase potassium excretion?

Answer 99

Increased activity of the sodium potassium ATPase, and reduce return of potassium into the plasma so increased potassium excretion

Question 100

What type of flow regulates potassium excretion?

Answer 100

Tubular flow

Question 101

How does tubular flow regulate potassium excretion ?

Answer 101

Activates cilia, activates PDK1

This increases calcium ions within the cell, stimulating the opening of potassium channels on the apical membrane

Question 102

What are the causes of hypokalaemia?

Answer 102

Common electrolyte imbalances (20% of hospitalised patients).
• Inadequate dietary intake (Processed food).
• Diuretics (Due to increase tubular flow rates)
• Surreptitious vomiting
• Diarrhoea
• Genetics (Gitelman’s syndrome: Mutation in the Na/Cl transporter in the distal nephron).
 Increases aldosterone synthesis in response to low sodium – thus hypokalaemia.

Question 103

What is Gitelman’s syndrome?

Answer 103

• Genetics (Gitelman’s syndrome: Mutation in the Na/Cl transporter in the distal nephron).
 Increases aldosterone synthesis in response to low sodium – thus hypokalaemia.

Question 104

What are the common causes of hyperkalaemia?

Answer 104

• Common electrolyte imbalance present in 1-10% of hospitalised patients.
• Response to K+ sparing diuretics (spironolactone)
• ACE-inhibitors
• Elderly
• Severe diabetes
• Kidney disease