ECF Volume Regulation

Question 1

What is one of the most important aspects of the ECF regulated by the kidney?

Answer 1

Volume

Question 2

Why is the distribution of TBW between the cells and the ECF determined by the number of active osmotic particles in each compartment?

Answer 2

H2O can freely cross all cell membranes so the body fluids are in osmotic equilibrium

Question 3

What are the major ECF osmoles?

Answer 3

Na and Cl

Question 4

What are the major ICF osmoles?

Answer 4

K salts

Question 5

What is regulation of ECF volume regulated by?

Answer 5

Regulation of body Na

Question 6

How is water distributer within the body?

Answer 6

Water= 60% TBW=42l

• ICF= 2/3= 28l
• ECF=1/3 =14l
• Plasma accounts for 3l and interstitial fluid accounts for 11l of the ECF

Question 7

How do changes in Na content of the ECF affect BP?

Answer 7

Changes in Na+ content of the ECF will lead to changes in ECF volume and therefore will affect the volume of blood perfusing the tissues determining effective circulating volume and therefore BP.

Question 8

What is regulation of Na basically dependent on?

Answer 8

High and low pressurebaroreceptors

Question 9

Hypovolaemia?

Answer 9

Low ECF volume

Question 10

What happens to the body in hypovolaemia?

Answer 10

• Increases in salt and H2O loss
• Decrease in pulse volume
• Decrease in venous pressure
• Decrease in venous return
• Decrease in atrial pressure
• Decrease in End diastolic volume
• Decrease in stroke volume
• Decrease in cardiac output
• Decrease in BP
• Decrease in carotid sinus baroreceptor inhibition of sympathetic discharge

Question 11

How does the body compensate for hypovolaemia?

Answer 11

• Decreases carotid sinus barocreceptor inhibition of sympathetic discharge leads to increased sympathetic discharge
• Increase VC
• Increase TPR
• Increase BP towards normal

Question 12

Give examples when there might be increase salt and water loss?

Answer 12

• Vomiting/diarrhoea

- Excess sweating

Question 13

How does the renal system respond to comepensation for hypovolaemia?

Answer 13

• Increase ADH
• Increases renal arterial constriction
• Increases renin
• Increase angiotensin II
• Increased NaCl and H2O reabsorption in proximal tubule
• Increased aldosterone which increases NaCl and H2O reabsorption in the distal tubule

Question 14

What effect does increased renin have on the proximal tubule of the kidney?

Answer 14

• Increases angiotensin II
• Decreases peritubular capillary hydrostatic pressure (+ the osmotic pressure)
• Increased Na reabsorption from the proximal tubule and less Na excreted

Question 15

What effect does renin have on the distal tubule of the kidney?

Answer 15

• Increased renin
• Increased angiotensin II
• Increased aldosterone
• Increased distal tubule Na reabsorption and less Na excreted

Question 16

What is the sympathetic discharhe on the kidney determined by?

Answer 16

Osmotic pressure

Question 17

What are changes in proximal tubule Na reabsorption due to?

Answer 17

Changes in the rate of uptake by the peritubular capillaries

Question 18

What are increases in Na reabsorption due to?

Answer 18

Greater reabsorptive forces in the peritubular capillaries

Question 19

What is the reabsorptive range of the proximal tubule?

Answer 19

• 65% in volume excess
• 75% in volume deficit.
• Big range of volume just because of changes in Starling’s forces.)

Question 20

Why is GFR largely unaffected by changes in ECF?

Answer 20

Autoregulation maintains GFR and the VC of afferent and efferent means little effect on GFR until volume depletion severe enough to cause considerable decrease in MBP.

Question 21

What maintains GFR in ECF loss?

Answer 21

• Constriction of afferent due to sympathetic VC

- Constriction of efferent mediated by angiotensin II

Question 22

What is regulation of distal tubule Na reabsorption under control of?

Answer 22

Adrenal cortical steroid hormone aldosterone

Question 23

What hormone is very important in the long-term regulation of Na and ECF volume?

Answer 23

Aldosterone

Question 24

What is aldosterone secretion controlled by?

Answer 24

Reflexes involving the kidneys themselves

Question 25

What cells are present in the smooth muscle media of the afferent arteriole just before it enters the glomerulus?

Answer 25

Juxtaglomerular cells (JG): specialized, containing large epithelial cells with plentiful granules

Question 26

What are the 2 components of the juxtaglomerular apparatus?

Answer 26

• Juxtaglomerular cells

- Macula densa

Question 27

What are the JG cells closely associated with?

Answer 27

A histologically specialized loop of the distal tubule known as the macula densa

Question 28

What do JG cells produce?

Answer 28

Renin

Question 29

What is renin?

Answer 29

A proteolytic enzyme which acts on a large protein in the 2-globulin fraction of the plasma proteins known as angiotensinogen.

Question 30

What does renin do the angiotensinogen?

Answer 30

Renin splits off the decapeptide angiotensin I which is then converted by enzymes in the endothelium to the active octapeptide = angiotensin II

Question 31

What does ACE stand for?

Answer 31

Angiotensin converting enzyme

Question 32

Where is ACE found?

Answer 32

It is found throughout the vascular endothelium, but the greatest proportion of the conversion occurs as the blood passes through the pulmonary circuit, but all of the endothelium is important.

Question 33

What does angiotensin II do?

Answer 33

Angiotensin II stimulates the aldosterone- secreting cells in the zona glomerulosa of the adrenal cortex

Question 34

What does aldosterone do?

Answer 34

The aldosterone passes in the blood to the kidney where it stimulates distal tubular Na+ ion reabsorption

Question 35

What is the rate-limiting step in the renin-angiotensin-aldosterone system?

Answer 35

The rate limiting-step is the release of renin since angiotensinogen is always present in plasma.

Question 36

When is renin release increased?

Answer 36

When the pressure in afferent arteriole at the level of the JG cells is decreased

Question 37

How do JG cells act as renal baroreceptors?

Answer 37

Less distension leads to increased secretion of renin. Intrinsic property occurs if denervated

Question 38

Why does increased sympathetic nerve activity cause increases in renin?

Answer 38

Via B1 effect

Question 39

What is rate of renin secretion inversely proportional to?

Answer 39

Rate of delivery of NaCl at the macula densa (specialised distal tubule)

Question 40

What inhibits renin?

Answer 40

• Angiotensin II feed back

- ADH r

Question 41

What does the close relationship between the afferent arteriole with JG cells and the macula densa provide a mechanism for?

Answer 41

Controlling input and output of tubules and basis of tubuloglomerular balance

Question 42

How are volume deficits restored in hypovolaemia?

Answer 42

Increases in proximal AND distal tubule Na+ reabsorption together with osmotic equivalents of H2O, helps restore volume deficits, mediated by CV reflexes

Question 43

Why is angiotensin II fundamentally important in the body’s response to hypovolaemia

Answer 43

• It stimulates aldosterone and therefore NaCl and H2O retention
• It is a very potent biological vasoconstrictor, 4-8x more potent than norepinephrine therefore contributes too increased TPR
• It acts on the hypothalamus to stimulate ADH secretion which increases H2O reabsorption from CD
• It stimulates the thirst mechanism and the salt appetite

Question 44

What does tubuloglomerular feedback contribute to?

Answer 44

GFR constancy

Question 45

If there is conflicting information received by osmoreceptors and baroreceptors what happens?

Answer 45

Volume considerations have primacy if ECV is compromised

Question 46

What is normally the main determinant of [ADH]?

Answer 46

Osmolarity

Question 47

When does volume become the primary driver of [ADH]?

Answer 47

If there is sufficient volume change to compromise brain perfusion

Question 48

What is the simple rule when it comes to normalising ECF?

Answer 48

Simple rule, lose salt and water, replace salt and water.

Question 49

What does aldosterone promote?

Answer 49

Na reabsorption

Question 50

What is ANP?

Answer 50

Atrial natriuretic peptide

Question 51

What does ANP promote?

Answer 51

Na excretion

Question 52

What effect does aldosterone have at the distal tubule?

Answer 52

• Increased Na reabsorption

- Increased K secretion

Question 53

What does administering aldosterone lead to?

Answer 53

• Increased weight because of retention of H2O with increased Na
• Volume expansion
• Stimulation of release of ANP from atrial cells
• Loss of Na and H20
• Continued K loss due to increased K secretion

Question 54

What is aldosterone escape?

Answer 54

ANP overrides aldosterone effects on Na+ reabsorption because of volume expansion

Question 55

When is ANP secreted?

Answer 55

ANP is secreted by atrial cells in response to expansion of ECF volume and causes natriuresis, loss of Na+ and H2O in urine

Question 56

When is osmotic diuresis particularly important to consider?

Answer 56

In uncontrolled diabetes (hyperglycaemic coma)

Question 57

What happen in uncontrolled DM where [BG] is not kept within strict control?

Answer 57

The high plasma glucose level exceeds the maximum reabsorptive capacity in the proximal tubule

Question 58

What happens when glucose levels exceed the maximum reabsorptive capacity?

Answer 58

Glucose remains in the tubule and exerts an osmotic effect to retain H2O in the tubule.

Question 59

Why is there a decreased ability to reabsorb glucose in uncontrolled diabetes?

Answer 59

• [Na+] in the lumen is decreased because the Na+ is present in a larger volume.
• Since Na+ gains access to the proximal tubule cells by passive diffusion down a concentration gradient created by the active transport out of the basolateral surfaces, Na+ reabsorption will be decreased
• This decreases the ability to reabsorbe glucose since it shares a symport with Na

Question 60

In uncontrolled diabetes, why is the movement of H2O out of the tubule into the interstitium reduced in the descending loop of Henle?

Answer 60

The glucose and excess Na exert an osmotic effect to retain H2O therefore fluid in the descending limb is not so concentrated

Question 61

If the fluid in the descending loop of Henle is less concentrated in uncontrolled diabetes, what does that mean for the ascending limb?

Answer 61

The fluid delivered to the ascending limb is less concentrated

Question 62

Why is there a large volume of NaCl and H2O delivered to the distal tubule and the interstitial gradient is gradually abolished in uncontrolled diabetes?

Answer 62

• Since the NaCl pumps in the ascending limb are gradient limited, medullary interstitial gradient is much less
• Therefore there is a considerable reduction in the volume of NaCl and H2O reabsorbed fro the loops of Henle

Question 63

Under normal conditions what does a large volume of NaCl and H2O delivered to the distal tubule mean?

Answer 63

There is excess ECF volume and therefore the need to get rid of NaCl and H2O

Question 64

What detects high rates of delivery of NaCl to the distal tubule?

Answer 64

The macula densa

Question 65

How does the macula densa respond to high rates of NaCl delivery to the distal tubule?

Answer 65

• Renin secretion is supressed

- Na reabsorption at the distal tubule is decreased

Question 66

What type of urine do uncontrolled diabetics produce?

Answer 66

Large volumes of nearly isotonic urine which decreases the PV

Question 67

What will decreased PV stimulate in uncontrolled diabetes?

Answer 67

ADH release via baroreceptors but they cannot be effective because the interstitial gradient has run down

Question 68

How much urine can a patient with uncontrolled diabetes produce?

Answer 68

Up to 6-8l per day causing slat and water depletion

Question 69

What is one of the first signs of DM?

Answer 69

Raging thirst

Question 70

Why does hyperglycaemic comas occur?

Answer 70

Hypotension may become so severe

Question 71

What is a hyperglycaemic coma due to?

Answer 71

Inadequate blood flow to the brain

Question 72

What is a hypoglycaemic coma due to?

Answer 72

Inadequate glucose to the brain

Question 73

What can cause an osmotic diuresis in uncontrolled diabetes?

Answer 73

Any solute which remains in the tubule can cause an osmotic diuresis eg NaCl or urea but this helps to eliminate their excess.

Question 74

Why is osmotic diuresis not self-limiting in uncontrolled diabetes?

Answer 74

The liver keeps producing glucose

Question 75

What affect can loop diuretics have on K?

Answer 75

Can cause K wasting