Salt and Water Handling powerpoint

Question 1

Natriuresis

Answer 1

Discharge of Na+ through urine

Question 2

How Na+ is regulated on venous side

Answer 2

1) Right atrial sensors
- when stretched release ANP, inhibit release ADH, decrease vascular resistance
2) Pulmonary receptors
- nerves located adjacent to pulmonary capillaries
- may sense early pulmonary edema leading to inhibition of sympathetic activity ?

Question 3

How Na+ is regulated on arterial side

Answer 3

1) senses effective circulating volume via carotid sinus baroreceptor stretch —> leads to natriuresis
2) Sense increased renal BP (also relates to effective circulating volume) –> leads to natriuresis

Question 4

How Na+ is regulated via chemoreceptors

Answer 4

-senses Na+ concentration

Question 5

Effectors of Na+ regulation (5)

Answer 5

1) RAAS
2) Prostaglandins
3) Renal sympathetic nerves
4) Atrial natriuretic peptide
5) Nitric oxide

Question 6

RAAS

Answer 6

1) Release renin from kidneys
2) Acts on liver to convert angiotensinogen to angiotensin I
3) Angiotensin I converted to Angiotensin II via ACE
e

Question 7

Effects of Ang II

Answer 7

1) Na+ reabsorption in the proximal tubule (and likely distal sites as well)
2) at high concentrations AII causes vasoconstriction
3) Secretion of aldosterone

Question 8

What is the function of aldosterone

Answer 8

-allows Na+ reabsorption in DCT/collecting duct in exchange for K+

Question 9

Origin of prostaglandins

Answer 9

Arachidonic acid released from membrane phospholipids is metabolized to PGs by cyclooxygenase (COX-1 and COX-2)

Question 10

Main PG in the kidneys

Answer 10

PGI2 (prostacyclin)

Question 11

Overall effect of PGI2

Answer 11

-afferent arteriolar vasodilation and natriuresis

Question 12

PGI2 synthesis in healthy subjects

Answer 12

There is little to no basal PGI2 synthesis

Question 13

Trigger for PGI2 synthesis

Answer 13

-low ECFV states (ex CHF or cirrhosis)
-levels rise to maintain renal perfusion in the settng of high AII, SNS activity
CHF = low CO –> want to vasodilate afferent arteriole to increase GFR of kidney (overall will be getting more natriuresis because of increase GFR)

Question 14

Effect of use of NSAIDs in low ECFV states

Answer 14

• remove counterregulation to low ECFV by prostaglandins

- resulting in Na+ retention and renal failure

Question 15

What triggers renin release

Answer 15

Low bp (detected at juxtaglomerular apparatus) –> because overall going to cause Na+ reabsorption and H2O follows to increase intravascular volume

Question 16

Effect of increasing SNS activity

Answer 16

-renin secretion (leading to increase Na+/H2O reabsorption)

Question 17

What are kidney transplant patients who lack renal innervation prone to

Answer 17

ECF volume depletion

Question 18

Types of natriuretic peptides-

Answer 18

1) Atrial natriuretic peptide (ANP)

2) B-type natriuretic peptide (BNP)

Question 19

Renal effects of ANP/BNP

Answer 19

• increase GFR and natriuresis

- antagonism of almost all actions of the RAAS

Question 20

What type of diuretics are ANP/BNP like

Answer 20

-effects similar to K+ sparing diuretics that act on the distal tubule/collecting duct

Question 21

Uroguanylin production

Answer 21

-produced in the intestines in response to salt intake

Question 22

Uroguanylin effect

Answer 22

-reduces renal sodium reabsorption (helping to compensate for ingestion of dietary sodium)

Question 23

Nitric oxide diuretic properties

Answer 23

• appears to have diuretic properties separate from its vasodilatory powers
• NO deficiency/resistance implicated in some models of hypertension

Question 24

Water and Na+ reabsorption in the kidney - @ different sites in the nephron

Answer 24

1) 27000 mmol of Na+ filtered/day
2) 18000 reabsorbed @ proximal convoluted tubule - 9000 remaining, [Na+] = 150
3) 6000 reabsorbed @ loop of henle, 3000 remaining [Na+] = 45
4) 2000 reabsorbed @ distal convoluted tubule - 1000 remaining [Na+] = 100 (more concentrated by reabsorbed H2O)
5) Cortical collecting duct
-700 reabsorbed
-300 remaining
-[Na+] = 100
6) Medullary collecting duct
150 reabsorbed, 150 remaining [Na+] = 150

Question 25

Purpose of water regulation

Answer 25

To maintain a physiological Na+

Question 26

Effect of disturbances in [Na+]

Answer 26

• change in ADH secretion
  1) Loss H20
  2) Increase [Na+]
  3) Increase osmo
  4) Cell shrinkage hypothalamus (H2O moves out of cells)
  5) Increase release of ADH by posterior pit + the same osmotic stimulus in the hypothalamus increases thirst

Question 27

Effect loss of pituitary function on regulation of water

Answer 27

-can lead to loss of ADH (central diabetes insipidus) but does not usually impair thirst

Question 28

2 main vasopressin (ADH) receptors

Answer 28

1) V1

2) V2

Question 29

Location of V1 receptor

Answer 29

• arterioles
• glomerular mesangial cells
• brain

Question 30

Effect of V1 receptor

Answer 30

Mediates vasoconstriction

Question 31

Location of V2 receptor

Answer 31

-located on the blood side of cells in the TAL and the collecting duct

Question 32

Effect of V2 receptor

Answer 32

Mediates water movement down its gradient (water reabsorption)

Question 33

Effect of V3 receptor

Answer 33

May lead to ACTH release by the pituitary

Question 34

Physiological concentrations of ADH and activation of V1 receptors

Answer 34

Physiological ADH concentrations do not appear to be sufficient to cause activation of the V1 receptors

Question 35

Non-osmotic stimuli of ADH release

Answer 35

1) Volume depletion
2) Nausae/vomiting
3) Pain
4) Medications (narcotics, chlorpropamide, carbamazepine)
5) Exercise

Question 36

t1/2 of ADH

Answer 36

-minutes

Question 37

Vasopressin (drug) - MOA

Answer 37

Selective V1 agonist

Question 38

DDAVP MOA

Answer 38

Selective V2 agonist -leading to water reabsorption

Question 39

What determines ECFV

Answer 39

Serum Na+ content

Question 40

What determines intracellular fluid volume

Answer 40

Serum sodium concentration

Question 41

What does the serum [Na+ ]reflect

Answer 41

The ratio of Na+ to H2O

Question 42

What does serum [Na+] not correlate with

Answer 42

• ECFV (volume status)

- body sodium content

Question 43

What do alterations in [Na+] reflect

Answer 43

• reflect imbalances in the ratio of salt to water

- this imbalance is almost always due to disturbances in water content

Question 44

Principal extracellular osmoles

Answer 44

• main = NaCl

- to lesser extent K+, HCO3-

Question 45

Principal intracellular osmoles

Answer 45

• K+

- to lesser extent organic phosphates (DNA, RNA, ATP, phospholipids etc)

Question 46

Na+ location

Answer 46

Is restricted to the extracellular compartment

Question 47

Why changes in body salt content result in corresponding changes in body water content

Answer 47

1) Na+ restricted to extracellular compartment
2) Loss/gain Na+ changes osmolarity extracellular compartment - H2O moves in/out of extracell compart to balance intra/extracell
3) Overall = ECG volume changes but Na+ concentration remains fixed

Question 48

Cerebral edema

Answer 48

• low extracellular osmolarity vs. intracellular space

- water flows into cells in brain to reach new equilibrium

Question 49

How to avoid problem with water flowing into cells (causing lysis)/how Na+ content determines ECF volume

Answer 49

• excrete excess water

i. e. if Na+ is added/subtracted from the body water will be retained or excreted in order to keep osmolarity normal

Question 50

Consequence of CHF

Answer 50

1) Reduced CO
2) Decrease pressure loading of arterial sensor (decreased effective circulating volume)
3) initiation of processes leading to salt retention
4) Water retention -increase intravascular volume (volume loading?)

Question 51

Result increase Na+

Answer 51

Edema

Question 52

Result decreased Na+

Answer 52

Hypovolemia, or shock

Question 53

Result increase H2O

Answer 53

Cerebral edema

Question 54

Result decreased H2O

Answer 54

Osmotic demyelination

Question 55

Osmoregulation vs volume regulation (Na+ concentration vs. Na+ content)
a) what is being sensed

Answer 55

Osmoregulation:
-plasma osmolarity
Volume regulation
-effective circulating volume

Question 56

Osmoregulation vs volume regulation (Na+ concentration vs. Na+ content)
b) sensors

Answer 56

Osmoregulation
-hypothalamus
Volume regulation
-carotid sinus
-atria renal circulation

Question 57

Osmoregulation vs volume regulation (Na+ concentration vs. Na+ content)
c) effectors

Answer 57

Osmoregulation
-ADH
Volume regulation
-sympathetic nerves
-RAAS
-natriuretic peptides
-pressure natriuresis
-ADH

Question 58

Osmoregulation vs volume regulation (Na+ concentration vs. Na+ content)
d) what is affected

Answer 58

Osmoregulation
-water excretion (via ADH)
-water intake (via thirst)
Volume regulation 
-Na+ excretion

Question 59

What is happening to H20/solutes at each point in the nephron

Answer 59

1. Prox. tubule = lots of isotonic reabsorption
2. Descending limb = concentrating segment (water reabsorbed)
3. Ascending limb = diluting segment (solutes reabsorbed)
4. Distal tubule = some additional salt/H2O reabsorbed but urine is dilute
5. Collecting duct = if ADH acting, water reabsorbed down its gradient, otherwise urine remains dilute

Question 60

Concentrating segment

Answer 60

Descending loop of henle (H2O reabsorbed)

Question 61

Diluting segment

Answer 61

Ascending loop of henle (Na+ reabsorbed)

Question 62

Principles of concentrating urine (what does movement of H2O rely on)

Answer 62

• water is never pumped –> can only diffuse to area of higher tonicity
  i. e. the kidney must maintain an area of high tonicity

Question 63

What is responsible for getting water to diffuse from nephron

Answer 63

• active transport in the TAL (thin ascending limb)
• Na/ K ATPase –> create concentration in the interstitium
• water is not permeable at this segment (but sets up gradient for movement of water in adjoining segments that are permeable to water)
  ie. in the DCT and CD ADH sensitive H2O channels allow water to leave as long as [urine] <[interstitium]

Question 64

Max [urine]

Answer 64

-1200 mM (concentration in interstitial deep in the medulla)

Question 65

Extremes of renal function in healthy people

a) water conservation
b) salt conservation
c) water excretion
d) salt excretion

Answer 65

1) as little as 450 ml of urine per day can be normal
2) as little as 1-2 mmol/L Na{
3) 10+ L/day of very dilute urine
4) up to 800 mmol/day or 18g

Question 66

What is oncotic pressure equal to

Answer 66

= colloid osmotic pressure = osmotic pressure exerted by proteins (colloids)

Question 67

Permeability of blood vessel walls and how this affects osmotic gradient

Answer 67

-blood vessel walls are permeable to salt and water (therefore no osmotic gradient

Question 68

Albumin

Answer 68

• largest

- most plentiful pasma protein

Question 69

Location of most of the body albumin

Answer 69

In the interstitium

-however concentration here is lower ue to high volume of interstitial vs. intracascular fluid

Question 70

Net trans-capillary pressure -forces involved

Answer 70

1) Hydraulic pressure: Favours movement of fluid out of the capillaries
2) Oncotic pressure favours rention in the capillaries

Question 71

What does balance of trans-capillary pressure cause (net result)

Answer 71

Slight movement out with lymphatics returning this fluid to venous circulation

Question 72

Causes of trans-capillary fluid shifts + consequence

Answer 72

1) Increase capillary permeability (sepsis)
2) Increase hydraulic pressure (venous congestion)
3) Decrease albumin (decreased production, loss via GI tract or urine)
- all can lead to edema

Question 73

Sodium content in people with edema

Answer 73

Always increased