Body Fluid Volume Maintenance

Question 1

Rule of Na balance

Answer 1

Input = Output

Question 2

Positive Na balance

Answer 2

input > output

Question 3

Negative Na balance

Answer 3

output > input

Question 4

When you’re in +/- Na balance, which compartment is affected?

Answer 4

ECF volume will expand/contract, has nothing to do with plasma sodium concentration

**CHANGE IN NA+ IS EQUIVALENT TO ECF VOLUME

Question 5

effective circulating volume is related to adequate perfusion of vascular beds (brain, heart, and other vital organs) and is dependent on these 3 factors

Answer 5

• cardiac output
• MAP (BP)
• vascular volume (plasma) (that gets pushed into vital organs)

Question 6

ECV sensors

Answer 6

high pressure: carotid sinus, aortic arch, juxtaglomerular apparatus in kidney (HGA)

low pressure: pulmonary vessels, atria

Question 7

Changes in ECV will be picked up by volume sensors, which then send these 4 important signals to the kidney. List the ones that respond to increases in ECV and to decreased ECV.

Answer 7

Increased ECV: atrial natriuretic peptide (ANP) –excretin sodium

Decrease ECV: SNS, RAAS, and ADH (from posterior pituitary)

Question 8

An increase in sympathetic nervous system (increases/decreases) 5 important things

Answer 8

1. increases cardiac output
   (beta1 receptors, inotrophy, chronotropy, lusitropy)
2. increases vascular tone (alpha1 receptors, constricts and increases resistance on arteriole side and venous side, moves blood from venous to circular side to increase preload)
3. Decreases RPF and GFR (constricts afferent arteriole, decreases glomerular pressure, decreases filtration) causes….
4. decrease in NaCl excretion
5. increase renin release

Question 9

Function of renin, and where is it released?

Answer 9

angiotensinogen —renin—> angiotensin I –ACE–> Angiotensin II

renin is rate limiting step release from JG cells in kidney

Question 10

3 factors causing renin release from JG cells

Answer 10

1. SNS
2. Baroreceptor type phenomenon in JG cells - increase pressure, increase stretch, alters renin release
3. direct input from macula densa - sense alteration in electrolyte distribution

Question 11

An increase in SNS causes an (increase/decrease) in renin release

Answer 11

increase in renin release

Question 12

a decrease in MAP causes an (increase/decrease) of renin release

Answer 12

increase (decrease in MAP causes a decrease in arteriole stretch, renin is released, causing an increase in MAP, an increase in AA stretch, and a decrease of renin release)

Question 13

in what situation does the macula densa cause a direct increases of renin release?

Answer 13

when the macula densa receives a decrease in solut delivery

Question 14

what feedback loop causes a decrease in renin release?

Answer 14

Angiotensin II

Question 15

Function of aldosterone and where in nephron and what channels

Answer 15

increases Na reabsoprtion in CD (principal cell)

• increases Na channel (reabsorption on apical side)
• increases K channel (increased secretion due to paracellular transport of Cl)
• increases ATPase on basal side

long term: increases the number of transporters/channels by acting on TFs

Question 16

renal effects of AII

Answer 16

change in RPF/GFR and increases NaCl reabsoprtion in PT

Question 17

extrarenal effects of AII (4)

Answer 17

potent vasoconstrictor, increases aldo release, increases ADH release, increases thirst

Question 18

Euvolemia

Answer 18

normal ECV volume, input = output

Question 19

major player during euvolemia

Answer 19

aldosterone in CD

Question 20

filtered load of Na

Answer 20

GFR x P(Na)

Question 21

The goal of maintaining constant NaCl delivery to the CD is done by these two factors

Answer 21

1. autoregulation (MAP vs flow)

2. glomerulotubular balance

Question 22

3 aspects of glomerulotubular balance that try and keep NaCl delivery to CD constant

Answer 22

1. starling forces
2. filtered load: glucose/AA
3. tubuloglomerular feedback

Question 23

How do starling forces contribute to glomerulotubular balance and thus constant delivery of NaCl to CD?

Answer 23

• if lie down, increase hydrostatic pressure of glomerular capillary, thus more gets filtered
• increased filtration causes increase in osmotic pressure in peritubular capillaries (since holding protein back)
• since also moving more fluid out, hydrostatic pressure in capillaries decreases
• favors reabsorption

Question 24

how does filtered load of glucose and amino acids contribute to glomerulotubular balance?

Answer 24

glucose and Na are coupled with Na in symporter

-if want to reabsorb them, will also reabsorb more Na

Question 25

how does tubuloglomerular feedback contribute to glomerulotubular balance?

Answer 25

• JGA will release renin

- signals to MD

Question 26

When there is a decrease in ECV, where is the most Na reabsorbed so that the same amount is delivered to CD? Who are the major players and where are they acting on the nephron?

Answer 26

More absorbed in the PT/Thick descending loop
(normal is 67%, now its 75%)

TAL-will respond to amount being delivery by either increase or decreasing its capacity (normal is 25%, now it’s 15%

• glomerulus: SNS and AII increase
• PT: SNS and AII increase
• DT: Aldo increases
• CD: Aldo and ADH increase (enhances water reabsorption)

Question 27

When there is an increase in ECV, where is the most Na absorbed so that the same amount is delivered to the CD? Who are the major players and where are they acting on the nephron?

Answer 27

Less absorbed in the PT/Thick descending loop (normal is 67%, now its 60%)

TAL goes from 25% to 30% since flooded with stuff the PT didn’t absorb

SNS, AII, Aldo, and ADH decrease
ANP increases in CD

Question 28

changes in ____ will release ADH directly from ______

Answer 28

osmolality, posterior lobe of pituitary gland

Question 29

changes in ______ reflect water balance

Answer 29

plasma Na

Question 30

(+) H2O balance - 3 ways to describe it

Answer 30

input > output ….. low plasma[Na]….hyponatremic

Question 31

(-) H2O balance - 3 ways to describe it

Answer 31

output > input ….high plasma[Na]….hypernatremic

Question 32

most important osmoles in ECF:

most important osmoles in ICF:

Answer 32

ECF: Na+
ICF: K+

Question 33

Na is an (ineffective/effective) osmole, meaning….

Answer 33

effective. doesn’t pass through membrane easily, sets gradient for water
ineffective: urea and glucose

Question 34

What happens to the following (increase/decrease) when you drink a lot of water:

• Posm
• Osmoreceptors
• ADH secretion
• Thirst + H20 intake
• Water Excretion
• net effect on Posm

Answer 34

• Posm decreases
• osmoreceptors swell
• ADH secretion decreases
• thirst and H20 uptake decreases
• water excretion increases
• Posm increases

Question 35

What happens to the following (increase/decrease) you eat a salty bag of chips

• Posm
• Osmoreceptors
• ADH secretion
• Thirst + H20 intake
• Water Excretion
• net effect on Posm

Answer 35

• Posm increases
• osmoreceptors shrink (water moves from inside cell to outside)
• ADH secretion increases
• thirst/H2O intake increases
• water excretion decreases
• Posm decreases

Question 36

What are 3 main factors regulating ADH secretion

Answer 36

1. Body fluid osmolality (Posm)
2. Change in effective circulating volume (non-osmotic)
3. Non-physiologic factors (pain, nausea, drugs)

Question 37

change in ECV has a (more/less) sensitive response for ADH release

Answer 37

less sensitive-goes all out when reaches threshold

Question 38

Which is more important in causing ADH release?

Answer 38

Non-osmotic change change in ECV–most important factor-survival mechanism

Question 39

As change in ECV becomes more negative (decreases), ADH (increases/decreases)

Answer 39

ADH increases exponentially

Question 40

ECV depletion vs. dehydration

Answer 40

ECV depletion: water AND sodium depletion

dehydration: ONLY water depletion

Question 41

When urine flow rate (V) is low, urine osmolality is (low/high)

Answer 41

high (little amount, very concentrated)

Question 42

when ADH is low, amount of urine is (low/high)

Answer 42

high, since ADH is responsible for water absorption.

Question 43

While urine flow rate (V) and urine osmolality are inversely exponentially proportional, what factor stays constant?

Answer 43

Solute excretion (predominantly Na)
excretion rate: Uoxm x V

Question 44

Kidney can regulate solute excretion independently from what? What disease causes problems with this?

Answer 44

independently from water intake. renal disease disrupts this

Question 45

Kidney can regulate solute excretion independently of water intake. Where does this occur in the nephron and explain the mechanism.

Answer 45

Principal cell of CD is where this regulation occurs. ADH binds to V2 receptors on basolateral side, causes addition of AQP channels on apical side, allows for H2O reabsorption.

Question 46

Dilute urine:

Urine osmolality </> Plasma Osmolality

Answer 46

Posm > Uosm (Uosm min = 50 mOsm/L)

Question 47

Concentrated urine:

Urine osmolality </> Plasma osmolality

Answer 47

Uosm > Posm (Uosm max = 1200 mOsm/L)

+ADH

Question 48

What determines Uosm?

Answer 48

Water balance

Question 49

Reference Posm

Answer 49

~300 mOsm/Kg H20

Question 50

Diluting segments of the nephron and why

Answer 50

Thick ascending limb & distal tubule

water impermeable region of nephron

Question 51

3 factors for max excretion (max dilute urine)

disease entities correspond to these

Answer 51

1. in tact tubules (diluting segments)
2. adequate delivery of H2O and solute (GFR)
3. need absence of ADH

Question 52

5 important factors for max reabsorption (max concentrated urine)

Answer 52

1. in tact tubules (need TAL to establish a gradient by actively transporting NaCl out of lumen)
2. adequate delivery of H2O and solute
3. hyperosmotic medullary gradient (gradient set-up for water to be reabsorbed)
4. need ADH–signal to tell principal cells to integrate AQP channels
5. proper cell response to ADh signal

Question 53

Diuretics have direct impact on which part of the nephron?

Answer 53

on the diluting segment, blocking NaCl reabsorption