ECF Volume Regulation

Question 1

What are the major ECF and ICF osmoles?

Answer 1

ECF - Na+ and Cl-

ICF - Potassium salts

Question 2

What determines the regulation of ECF volume

Answer 2

Regulation of ECF volume linked to regulation of body sodium

Question 3

What is the division of total blody water?

Answer 3

2/3rds are found in intracellular fluid

1/3rd is extracellular

ECF is divided into interstitial fluid (majority) and plasma

Question 4

What components of the body are involved in regulation of sodium?

Answer 4

Dependant on high and low pressure baroreceptors

Question 5

What are the causes of reduced salt and H2O loss?

Answer 5

Vomitting

Diarrhoea

Excess sweating

(decrease in plasma volume, decrease in venous pressure, decrease in venous return, decrease in atrial pressure, decrease in end diastolic volume, decrease in stroke volume, decrase in cardiac output, decreases in carotid sinus baroreceptor inhibition of sympathetic discharge).

Question 6

What is the effect of increased sympathetic discharge?

Answer 6

Increase in vasoconstriciton - increase in total peripheral resistance, increase in blood pressure - towards normal

Question 7

What is the effect of increase in sympathetic discharge on the kidney?

Answer 7

Increase in renal vasoconstriction (renal arteriolar constriction increases) - increase in renin production

Renin leads to formation of angiotensin 2 - this decreases peritubular capillary hydrostatic pressure (increases oncotic pressure) - this causes sodium reabsorption from the proximal tubule - less sodium is excreted

Angiotension 2 causes an increase in aldosterone - increase in distal tubule sodium reabsorption - less sodium excreted

Question 8

How does the reabsorption range change in times of volume excess compared to times of volume defecit?

Answer 8

Volume excess: reabsorption range is 65%

Volume defecit: reabsorption range is 75% (oncotic pressure is higher in the peritubular capillaries)

Question 9

How does GFR change when volume changes?

Answer 9

GFR remains relatively unchanged - this is because of renal arteriolar constriction

Sympathetic vasoconstriction of afferent

Angiotensin 2 constricts the efferent

Question 10

Where does aldosterone regulate sodium reabsorption?

Answer 10

Distal tubule

Question 11

What are juxtaglomerular cells?

Answer 11

Specialized portion of the smooth muscle in the media of the afferent arteriole - contains large epithelial cells with plentiful granules

Question 12

What are the juxtaglomerular cells associated with?

Answer 12

The macula densa (a specialised loop of the distal tubule)

Question 13

Where is renin produced?

Answer 13

In the juxtaglomerular cells

Question 14

What is renin?

Answer 14

A hormone

Proteolytic enzyme

Acts on angiotensinogen to produce angiotensin 1

Question 15

Where is ACE found?

Answer 15

Vascular endothelium

The greatest conversion happens when the blood passes through the pulmonary circuit

Angiotensin 1 + ACE = Angiotensin 2

Question 16

How does angiotensin 2 result in aldosterone release?

Answer 16

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

Question 17

What is the rate limiting step in the RAAS pathway?

Answer 17

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

Question 18

What controls the release of renin?

Answer 18

1.­ Pressure in afferent arteriole at the level of the JG cells falls

JG cells act as “renal baroreceptors”

2. ­ Sympathetic nerve activity causes ­increase renin release via b1 effect
3. Rate of renin secretion is inversely proportional to rate of delivery of NaCl at the macula densa (specialized distal tubule - essentially a chemoreceptor) decrease in NaCl delivery = Increase in­ renin
4. Angiotensin II feeds back to inhibit renin.
5. ADH inhibits renin release (osmolarity control).

Angiotensin 2 and ADH provide feedback

Question 19

What is the effect of angiotensin 2?

Answer 19

1. It stimulates aldosterone and \ NaCl and H2O retention.
2. It is a very potent biological vasoconstrictor, 4-8 x more potent than norepinephrine, \ contributes to ­ TPR
3. It acts on the hypothalamus to stimulate ADH secretion and increase in ­ H2O reabsorption from CD.
4. It stimulates the thirst mechanism and the salt appetite (in the hypothalamus).

Question 20

What role does the macula densa have in decreasing GFR when the GFR is raised?

Answer 20

Flow through the tubule is increased

Flow past the macula densa increases

Paracrine from macula densa to afferent arterioles

Afferent arteriole constricts

Resistance in afferent arteriole increases

Hydrostatic pressure in glomerulus decreases

GFR decreases

Question 21

When a person has lost lots of water and salt (as a result of severe diarrhoea) how does the body respond?

Answer 21

ADH serves to increase water reabsorption (however this will effectively lower the already low blood osmolarity) but this is seen as beneficial regardless - normally osmolarity is the main determinant of ADH

Issues in volume take priority over issues in osmolarity - this is because there can be issues in brain perfusion if there is a loss in volume

Question 22

When does ADH increase?

Answer 22

ECF osmolarity increase

ECF volume decrease

Question 23

What is the solution to losses of salt and water?

Answer 23

Infuse or drink saline.

Question 24

What is the effect of ANP on sodium excretion?

Answer 24

ANP promotes sodium excretion

Question 25

What is the effect of aldosterone on potassium?

Answer 25

Causes potassium secretion

Question 26

How is ANP linked to aldosterone?

Answer 26

Aldosterone causes sodium reabsorption

Increase in weight because of retention of H2O with sodium reabsorption

Release of ANP from atrial cells

ANP overrides aldosterone effects on Na+ reabsorption because of volume expansion = “Aldosterone escape”.

Question 27

What are the imbalances in the blood present when the patient presents with conn’s syndrome? - Hyperaldosteronism

Answer 27

Potassium is depleted but the patient is not hypernatraemic

ANP still works and causes loss of sodium in urine

Question 28

What hormones does ANP have a controlling effect on?

Answer 28

Acts on the hypothalamus to reduce ADH secretion

Acts on the kidney to decrease the release of renin

Acts on the adrenal cortex to reduce the secretion of aldosterone

Question 29

What is the effect of ANP on GFR?

Answer 29

Acts on the kidney - Increases GFR

Question 30

What organ does ANP act on to decrease blood pressure?

Answer 30

Medulla oblongata

Question 31

What is the effect of elevated blood glucose levels on reabsorption in the proximal tubule?

Answer 31

Glucose remains in the tubule because the high plasma glucose exceeds the maximum reabsorptive capacity in the proximal tubule.

Glucose exerts an osmotic effect to retain H2O in the tubule

Question 32

How does the osmotic effect of glucose affect sodium reabsorption?

Answer 32

Glucose retains more H2O in the tubule

Sodium is removed from the tubule by passive diffusion down a concentration gradient (created by the active transport out of the basolateral surfaces, sodium reabsorption will be decreased)

SInce there is water retention - the concentration of sodium is less and so less is reabsorbed by diffusion.

The ability to reabsorb glucose is reduced since it shares a symport with sodium

Question 33

How does glucose retention in the descending limp of henle affect the movement of H2O?

Answer 33

Movement of H2O into the interstitium is reduced because of the glucose and sodium - retains H2O

Fluid in the descending limb is not so concentrated

Question 34

If water is not reabsorbed from the descending loops of henle, what is the effect on the ascending loops?

Answer 34

Since the NaCl pumps in ascending limb are gradient limited, medullary interstitial gradient is much less.

The increasing gradient of the interstitium is dependant on the increasing concentration of fluid from the descending limb to the ascending limb

There is considerable reduction in the volume of NaCl and H2O reabsorbed from the loops of henle

Large volumes of sodium chloride and H2O is delivered to the distal tubule

The interstitial gradient is gradually abolished

Question 35

Here is a summary of the osmolarity in the different parts of the kidney

Answer 35

Question 36

What is the effect of renin when levels of NaCl and H2O are increased?

Answer 36

Elevation of Na/Cl volume and H2O indicate that there is excess ECF volume - there is a ned to get rid of NaCl and H2O

Renin acts to increase blood pressure and reabsorb water and sodium

Therefore

The macula densa will detect the high rate of delivery of NaCl so that renin secretion will be suppressed and therefore Na+ reabsorption at the distal tubule will be decreased.

Question 37

What parts of the nephron are sodium chloride and water reabsorbed?

Answer 37

Question 38

Where is reabsorption affected in diabetes?

Answer 38

Question 39

What type of urine is excreted from diabetic patients?

Answer 39

A large volume of nearly isotonic urine will be excreted

This results in a decreased plasma volume

Patients with uncontrolled DM can produce urine volumes of up to 6-8 l/day, causing severe salt and water depletion.

If ingestion is not adequate, a raging thirst is one of the first signs of DM, then the hypotension may be so severe as to cause a hyperglycaemic coma.

Question 40

Why doesn’t ADH work in diabetes?

Answer 40

It isn’t effective because the interstitial gradient has run down

Question 41

What is the difference between a hyperglycaemic coma and a hypoglycaemic come?

Answer 41

Hyperglycaemic come - inadequate blood flow to the brain - hypoglycaemic coma is due to inadequate glucose for the brain

Question 42

Normally a solute in the tubule can cause osmotic diuresis to help eliminate their excess, why isn’t the problem with glucose self-limiting?

Answer 42

The liver continues to produce glucose

Question 43

Potassium is also involved

Answer 43