Regulation of homeostasis by the kidney

Question 1

What are the 2 roles of the kidney in homeostasis?

Answer 1

(1)Role of the kidney in volume regulation

Fluid balance: The amount of water gained by the body each day equals the amount lost

Electrolyte balance: The ion gain each day equals ion loss

(2) Control of acid-base balance by the kidneys

Acid-base balance: H+ gain is offset by H+ loss

Question 2

What is the normal pH range of arterial blood?

What is the survival pH range?

Answer 2

Question 3

What are the consequences of pH outside of 7.35-7.45?

Answer 3

• If plasma levels fall below 7.35 (acidaemia), acidosis results
• If plasma levels rise above 7.45 (alkalaemia), alkalosis results

Alterations outside these boundaries affects all body systems

• Can result in coma, cardiac failure and circulatory collapse
• At pH < 6.8 or > 8.0 death occurs

Question 4

Define acid, base and how they’re grouped

Answer 4

Acids

• Release H+ into solution

Bases

• Remove H+ from solution

Acids and bases

• Grouped as strong or weak

Question 5

What is pH?

Answer 5

pH = potential of hydrogen: specifies acidity or basicity of an aqueous solution

Question 6

Define buffer

What are the 3 buffer systems in the body?

Answer 6

Buffers: Resist changes in pH

• When H+ added, buffer removes it
• When H+ removed, buffer replaces it

Types of buffer systems

• Carbonic acid/bicarbonate
• Protein
• Phosphate

Question 7

Why must the kidneys maintain acid-base homeostasis?

Answer 7

•This is important because all biochemical processes must occur within an optimal pH window (pH 7.2 - 7.4)

Question 8

Write the acid-base homeostasis equation

Answer 8

Question 9

What are the sources of acid in the body?

Answer 9

• The lungs excrete a large amount of CO2 – this is a potential acid formed by metabolism (CO2 reacts with water to form carbonic acid)
• The kidneys also secrete and excrete non-volatile acids produced from normal metabolism, e.g. lactic acid, which the lungs can’t excrete

Question 10

How is the production of acid countered?

Answer 10

• HOWEVER, to maintain acid-base balance, the kidneys must also reabsorb virtually all filtered HCO3-
• This is important as HCO3- acts as a physiological buffer
• This control of acid-base balance prevents ACIDOSIS or ALKALOSIS

Question 11

What is the equation for pH?

Answer 11

Question 12

• Blood pH = ____
• Urine pH ____
• Blood [HCO3-] = _____ mM
• Blood pCO2 = partial pressure of CO2 = _____ mmHg
• Plasma osmolality = _____ mOsm/kg water

Urine osmolality = _____ mOsm/kg water

Answer 12

• Blood pH = 7.4
• Urine pH ~ 6.0
• Blood [HCO3-] = 24 mM
• Blood pCO2 = partial pressure of CO2 = 40 mmHg
• Plasma osmolality = 285 mOsm/kg water

Urine osmolality = 600 mOsm/kg water

Question 13

What does urine osmolalilty depend on?

Answer 13

(but urine osmolality depends upon hydration status –

it can vary between 50-1200 mOsm/kg, e.g. depending on fluid intake)

Question 14

What is the The relationship between
pH, HCO3- and CO2?

Answer 14

Inverse relationship between pH and plasma concentration of CO2

i.e. when one goes up the other goes down and vice versa…….

So when pCO2 increases, e.g. in COPD, pH decreases (acidosis) as CO2 reacts with water to form carbonic acid

Question 15

How does respiratory regulation of acid-base balance work?

Answer 15

Respiratory regulation of pH is achieved via the HCO3-/CO2 (carbonic acid) buffer system:

• as pCO2 levels increase, pH decreases
• as pCO2 levels decrease, pH increases

Changes in pH levels are detected by peripheral chemoreceptors

These then act on respiration centres in the brain to adjust respiration rates:

Question 16

How does renal regulation of acid-base balance work?

Answer 16

•Most HCO3- in filtrate is reabsorbed, H+ is also secreted

(pH urine ~ 6.0). “Renal tubular acidosis (RTA)” may occur if the kidneys don’t do this effectively, e.g. in renal failure

• If pH of ECF falls (acidaemia): more secretion of H+ into filtrate AND reabsorption of HCO3- back into ECF cause pH to increase
• Secretion of H+ inhibited when urine pH falls below 4.5
• If pH of ECF increases (alkalaemia): secretion of H+ into filtrate and reabsorbtion of HCO3- declines. Extracellular pH decreases

Question 17

What is the most efficient regulator of acid-base balance?

Answer 17

Kidneys

Question 18

What is the kidneys response to acidaemia?

Answer 18

we want to increase (1) H+ secretion and

(2) HCO3- reabsorption and (3) HCO3- generation in the Distal Tubule & CD (Intercalated Cells)

Question 19

What is acidosis?

Answer 19

Acidosis: pH of body fluids falls below 7.35

Too much H+. Solution: Get rid of H+ out of the body:

(i) Excrete it via the lungs (as CO2) and the kidneys (as H+)
(ii) Generate more buffer (HCO3-) in the kidneys

Question 20

What is alkalosis?

Answer 20

Alkalosis: pH of body fluids climbs above 7.45

Too little H+. Solution: Increase H+ levels in the body:

(i) Reduce excretion of CO2 via the lungs (increase blood CO2)
(ii) Increase excretion of HCO3- buffer via the kidneys
(iii) Increase generation of H+ by the kidneys

Question 21

What is the difference between respiratory and metabolic acidosis?

Answer 21

Respiratory: - Caused by inadequate ventilation

• Can be acute or chronic

Metabolic: - Results from all conditions other

than respiratory that decrease pH

• Always chronic

Note: Only chronic states cause marked change in HCO3-

Question 22

How can you gain H+?

Answer 22

–CO2 in blood (combines with H2O to form carbonic acid)

–Non-volatile acids from metabolism (e.g. lactic acid)

–Loss of HCO3- in diarrhoea or non-gastric GI fluids

–Loss of HCO3- in urine

Note: Loss of HCO3- is like gaining H+

Question 23

What is the difference between metabolic and respiratory alkalosis?

Answer 23

Respiratory: - Caused by hyperventilation

• Can be acute or chronic

Metabolic: - Results from all conditions other

than respiratory that increase pH

• Always chronic

Question 24

What is the treatment of metabolic alkalosis?

Answer 24

• Give electrolytes to replace those lost
• Give IV Cl- containing solution
• Treat the underlying disorder

Question 25

How is respiratory alkalosis treated?

Answer 25

• Treat underlying cause
• Breathe into paper bag

(increases pCO2)

• Give IV Cl- containing solution (­HCO3- excretion)

Question 26

Answer 26

Question 27

What are the actions of anti-diuretic hormone?

Answer 27

Interacts with V2 receptors on basolateral surface of principal cells in collecting duct of tubule

Results in increased permeability of collecting duct to H2O by insertion of aquaporin-2 (AP-2) water channels on apical surface

Maximal ADH leads to production of low amounts of concentrated urine

Question 28

What causes ADH to be released?

Answer 28

ADH released in response to changes in plasma osmolality and effective circulating volume (ECV)

These changes are detected by osmoreceptors and baroreceptors

Question 29

What is the role of osmoreceptors in dehydration?

Answer 29

Increased plasma osmolality stimulates osmoreceptors in the hypothalamus which trigger ADH release…

Result: more water reabsorbed from collecting ducts in kidney back into circulation. This leads to ­ ECV

Increased osmolality also stimulates a second group of osmoreceptors in the hypothalamus which trigger thirst…

Result: promotes water intake which enters circulation. This also ­ ECV

Question 30

Answer 30

Question 31

What are the 2 types of baroreceptors?

Answer 31

“Central” vascular sensors

• ‘Low pressure’ blood volume receptor (very important)
• Large systemic veins
• Cardiac atria
• Pulmonary vasculature
• ‘High pressure’ arterial stretch receptor (less important)
• Carotid sinus
• Aortic arch
• Renal afferent artery (the renal baroreceptor)

Sensors in the CNS and liver (less important)

Question 32

Changes in ECV trigger 4 parallel effector pathways which act on the kidney…

Answer 32

(1) RAAS
(2) sympathetic nervous system
(3) ADH release
(4) ANP release

•Together, these change renal haemodynamics and Na+ transport by renal tubule cells

ECV regulation = Na+ regulation

Question 33

How is the renin angiotensin aldosterone system activated?

Answer 33

•Principal factor controlling plasma AngII levels is renin release from the JGA

Question 34

•Decreased ECV stimulates renin release via…

Answer 34

–Decreased renal perfusion pressure detected in the afferent arteriole - the “renal baroreceptor”

–Decreased Na+ concentration in distal tubule detected by the macula densa cells - the “renal Na+ sensor”

–Decreased systemic BP also triggers effects of the sympathetic nervous - system supplying the JGA

Question 35

What are the actions of angiotensin II?

Answer 35

All the actions of AngII actions are designed to increase ECV:

(1) Enhances tubular Na+ transport

in the kidney - this promotes Na+ and water reabsorption from tubule

(2) Stimulation of aldosterone release from adrenal cortex so more Na+ and water is reabsorbed from distal tubule/collecting duct
(3) Acts on the hypothalamus to stimulate thirst and ADH release into circulation

…water intake adds to ECV

…ADH increases water reabsorption from the collecting duct

•Vasoconstriction of renal and other systemic vessels so systemic BP increases

Question 36

What are the longer term effects of RAAS?

Answer 36

•AngII causes renal cell hypertrophy

…so more protein synthesis of

Na+ transporters and channels

??? Role in hypertension

Re: ACE inhibitors and ARBs

for treatment of hypertension

Question 37

What are the actions of aldosterone?

Answer 37

All the actions of aldosterone are designed to increase ECV (in collaboration with AngII)

• Stimulates Na+ reabsorption (and K+ excretion) in the distal tubule and collecting duct
• Aldosterone also exerts indirect negative feedback on the RAAS by increasing ECV and by lowering plasma K+ concentrations
• Important in conserving Na+ and water, but also important in preventing large variation in plasma K+ levels (by causing its excretion out of the kidney)

Question 38

Answer 38

Question 39

Answer 39

Question 40

Answer 40

Question 41

Answer 41

Question 42

How does ANP work?

Answer 42

• Atrial myocytes synthesize and store ANP.
• ­ECV causes atrial stretch which leads to ANP release into circulation
• ANP promotes natriuresis (­ Na+ excretion from the kidney)
• Also causes renal vasodilatation so increased blood flow ® increase in GFR…so more Na+ excreted
• More Na+ reaches the macula densa so renin release by JGA is reduced – reduces the effects of AngII
• Overall effect: inhibits actions of renin and opposes effects of AngII

Question 43

What does anti-natriuretic peptide do?

Answer 43

•In contrast, actions of ANP are all designed to lower ECV

Question 44

Answer 44