Diuretics

Question 1

Describe what happens in the proximal tubule

Answer 1

• Na and Cl are reabsorbed isosmotically: 50-70% of filtered load
• K is reabsorbed
• Bicarb is reabsorbed ( via CA)

Question 2

What happens in the ascending limb of the loop of henle

Answer 2

• Na and Cl are reabsorbed (20-30%): Active Cl is reabsorbed (remember the Na/K/2Cl transporter)
• impermeable to water so no water reabsorption
• Can compensate for increased Na delivery from proximal tubule by increasing reabsorption
• diuretic on cortical and medullary segments differ in response

Question 3

What happens in the Distal Tubule and Collecting Duct

Answer 3

• Na is reabsorbed (8-9%)
• K is secreted
• Aldosterone regulation of Na and K exchange
• Water permeability regulated by ADH

Question 4

Prototypes of Renal Vasodilators

Answer 4

**Dopamine
Fenoldapam
Caffeine
**Atriopeptins

Question 5

Characteristics of renal vasodilators

Answer 5

• some orally active
• limited clinically to hypertensive crisis and shock
• weak diruetics bc act on proximal tubule

Question 6

Mechanism of renal vasodilators

Answer 6

• *Selectively dilate the renal vasculature that modifies proximal tubular function **
• Increase renal blood flow (RBF) without changing GFR. SO Filtration Fraction decreases

Question 7

What is Filtration rate again and how is it impacted by renal vasodilators

Answer 7

FF=GFR/RBF

FF= GFR (unchanged) /RBF (increased) so FF must decrease with a renal vasodilator

Question 8

If you increase the filtration fraction what will happen to water and Na excretion

Answer 8

decrease
-if you increase filtration fraction, the protein left in the capillary will be at a high concentration trigger water and Na reabsorption and therefore decreasing excretion of water and Na

Question 9

If you decrease the Filtration Fraction what will happen to Na and water release

Answer 9

decreasing filtration fraction will decrease the concentration of protein in the capillary bc there will be water there. SO there will be less water reabsorption and therefore more water and Na excretion

Question 10

Prototypes of osmotic diuretics

Answer 10

Mannitol

Question 11

Characteristics of osmotic Diuretics

Answer 11

• Mannitol
• Freely Filtered
• Not reabsorbed
• Metabolically inert
• basically just sits in the lumen

Question 12

Mechanism of Osmotic Diuretics

Answer 12

• **Act in the tubular lumen as reabsorbable solute**
• given via IV
• urine volume and sodium excretion are proportional to the osmotic load
• increases excretion of Na, K, Cl, water, mannitol

Question 13

Uses for Osmotic Diuretics

Answer 13

• edema
• glaucoma to reduce intraocular pressure
• acute renal failure

Question 14

Prototype of Carbonic Anhydrase Inhibitors

Answer 14

Acetazolamide

Question 15

Characteristics of CA inhibitors

Answer 15

• Acetazolamide
• oral
• weak diuretic: bc working on proximal tubule
• they are inhibited by acidosis which inhibits clinical use

Question 16

Mechanism of CA inhibitors

Answer 16

• Acetazolamide
• inhibit CA in the proximal tubule
• CA normally provides H ions for bicarb reabsorption. so basically you don’t reabsorb the bicarb (or really excrete H )
• increase excretion of Na, K, bicarb, water
• Alkalinize the urine

Question 17

Side effects of Carbonic Anhydrase Inhibitors

Answer 17

• Acetazolamide
• metabolic acidosis
• Hypokalemia (bc you increase excretion of K )

Question 18

Uses of CA inhibitors

Answer 18

• Glaucoma
• Alkalinization of the urine to reduce drug toxicity
• Mountain or altitude sickness
• Anticonvulsant

Question 19

prototypes of loop diuretics

Answer 19

Furosemide, Bumetanide, Ethacrynic Acid

Question 20

Characteristics of Loop Diuretics

Answer 20

• oral or IV
• high efficacy (20-30% of filtered Na load excreted)
• rapid onset
• short duration of action

Question 21

Mechanism for loop diuretics

Answer 21

• inhibits the N/K/sCl/ symporter (reabsorption)
• Acts on the cortical and medullary segments of the ascending limb of the loop of henle
• increase excretion of Na, K, Cl, water

Question 22

Disadvantages of Loop Diuretics

Answer 22

****Hypokalemia (bc increased excretion)

***Alkalosis (bc increase H excretion)

***Hypovolemia ( bc large water loss)

Question 23

Uses for Loop Diuretics

Answer 23

• edema of cardiac, hepatic or renal origin
• acute pulmonary edema
• HYN

Question 24

Thiazide and Thiazide like diuretics prototypes

Answer 24

Hydrochlorothiazide, Metolazone

Question 25

Thiazide and Thiazide like diuretics characteristics

Answer 25

• oral
• intermediate efficacy
• moderate onset
• long duration

Question 26

Mechanism of action for thiazide like diuretics

Answer 26

• **-Inhibits Na-Cl symporter
• **-Acts of cortical segment of distal tubule
• increases excretion of Na, K, Cl, water
• Urine is hypertonic (unable to dilute)

Question 27

Disadvantages of Thiazide diuretics

Answer 27

*****Hypokalemia-bc increase Na in the lumen (from decreased reabsorption) causes increased activity of the ENaC channel in the collecting duct and therefore increased K excretion

*****Alkalosis

Question 28

uses of thiazide diuretics

Answer 28

• edema due to CHF
• HTN
• hypercalciuria

Question 29

Prototype for K sparing diuretics

Answer 29

Aldosterone Antagonists: Spironolactone, Eplerenone

Sodium Channel Inhibitors: Amiloride, Triamterene

Question 30

Characteristics of K SParing diuretics

Answer 30

-oral 
low efficacy ( 2-3% of Na load excreted) 
-weak diuretic
-increases Na excretion without K loss 
-work on the collecting duct

Question 31

Mechanism of the K sparing diuretics

Answer 31

**Mineralocorticoid receptor antagonists: Block the action of aldosterone on the collecting duct

*****Sodium channel inhibitors: Blocks sodium entry into principal cells of the collecting duct

• ***-increase Na excretion
• ***-decrease K excretion

increase excretion of Na, Cl, H2O

Question 32

Disadvantages to K sparing diuretics

Answer 32

• low efficacy*****

- hyperkalemia***

Question 33

Uses of K sparing diuretics

Answer 33

• edema
• HTN
• seldom used alone. usually in combination with a thiazide or loop diuretic-enhanced natriuresis without K loss
• Aldosterone anatagonists improve survival rate in heart failure

Question 34

Factors in choosing a diuretic

Answer 34

1.Intrinsic Activity
2 Cost
3. Route of Administration: IV vs. oral
4. Speed of Onset: loop faster than thiazides
5. Risk to Benefit Ratio 6. Effects on Renal Hemodynamics

Question 35

compare the intrinsic activity of the diuretics

Answer 35

HIGHEST
Loop
Thiazides
K sparing

Question 36

Compare the cost of diuretics

Answer 36

HIGHEST
thiazides
loop
K sparing

Question 37

Explain the concept of the diuretic ceiling

Answer 37

there reaches a dose of diuretic where the diuretic is doing its max potential. Increasing the dose after this point will no make the diuresis more or better, in fact it may lead to some adverse effects

Question 38

What two things does the diuretic ceiling effect depend upon

Answer 38

• diuretic

- disease

Question 39

List things that decrease plasma oncotic pressure (and can cause edema)

Answer 39

• plasma oncotic pressure is the amount of protein in the blood and therefore it usually is a force that draws fluid in
• Decreased by:
• malaborption
• nephrotic syndrome
• liver failure
• malnutrition

Question 40

List things that can increase capillary hydrotic pressure (an therefore lead to edema)

Answer 40

• an out pressure
• venous obstruction
• cirrhosis
• CHF
• constriction/restriction
• renal failure
• pregnancy

Question 41

Explain the use of diuretic drugs in edema and the two point foundation of edema therapy

Answer 41

-you increase Na and water excretion by reducing renal tubular Na and water reabsorption ( so it is all excreted!!)

• Foundation of edema therapy
  1. Reduce intravascular volume
  2. Reduce ECF and edema

Question 42

Prototypic diuretic drugs used for edema

Answer 42

hydrochlorothiazide, furosemide

Question 43

List four things that the tissue compartment determines

Answer 43

1. Dictates rate of fluid mobilization (slow equilibrium between ECF and body compartment, but fast equilibrium between vasculature and ECF
2. Determines volume status

Diuresis: 1st – vascular; 2nd - edematous tissue; 3rd - compartments (peritoneal or
pleural spaces

4. Loculated Fluid Ascites: mobilize slowly 0.5 kg/d monitor diuretic effect (fluid in body leaves slowly bc of the slow equilibrium between body and ECF)

Question 44

4 facts about electrolyte imbalance relating to K

Answer 44

• K loss parallels Na excretion ( bc as more Na is lost ENaC will try to compensate in collecting duct and will cause a lot of K loss)
• to overcome loss: increase intake with K supplements or decrease output with K sparing diuretics
• Hypokalemia: rarely life threatening
• Hyperkalemia: can be fatal

Question 45

How do Carbonic Anhydrase Inhibitors influence acid-base balance

Answer 45

Metabolic Acidosis (dont reabsorb HCO3-)

Question 46

How do Loop Diuretics influence acid-base balance

Answer 46

Metabolic Alkalosis

Question 47

How do Thiazide Diuretics influence acid-base balance

Answer 47

Metabolic Alkalosis

Question 48

How would a diuretic work to help with hypertension

Answer 48

it would increase salt and water excretion by reducing renal tubular sodium and water reabosporption

*increase excretion by reducing reabsorption

1. lower BP
2. Prevent salt and water retention and enhance blood pressure lowering by other antihypertensive drugs

Prototypic drugs: hydrochlorothiazide, furosemide

Question 49

How is is thought that diuretics decrease BP according to looking at the CV system

Answer 49

they decrease the vascular volume which would decrease venous return which would decrease Cardiac Output which would decrease Blood Pressure

Question 50

So what actually happens when you give someone a diuretic for a BP medication

Answer 50

it works at first exactly as you would like, but then it is no longer effective at decreasing the blood pressure

then the arteries dilate and the peripheral resistance resistance decreases, so the Cardiac output increases back to what it was before and all goes back to normal

Question 51

How do diuretics decrease peripheral resistance/vasodilate

Answer 51

1. decreased Na/water in vessel wall
2. PGI2 and NO release
3. Vascular K channel activation
4. decreased sensitivity to NE
5. Increase Na-Ca exchange

Question 52

Diuretic use in chronic heart failure

Answer 52

• mainstay of heart failure management
• reduce fluid volume and ventricular preload (stop the cylce of heart failure at fluid and sodium retention)
• reduction in heart size improves efficiency
• reduce edema (and its symptoms)
• not associated with a reduction in mortality

Question 53

What do diuretics do to SV and LVEDP

Answer 53

they allow you in a failing heart to pump at the same SV, with a lower LVEDP

Question 54

Actions of Angiotensin II on the heart

Answer 54

• stimulates vascular smooth muscle cells migration proliferation and hypertrophy
• increases vascular smooth muscle cell extracellular matrix production
• causes cardiac myocyte hypertrophy
• increases cardiac fibroblast extracellular matrix production
• stimulates growth factors (TGF-B, FGF, PDGF)
• Angiotensin II also alters extracellular matrix formation and degradation indirectly by increasing aldosterone

Question 55

SO what happens to your heart when Angiotensin II is inappropriately elevated

Answer 55

• Cardiac Fibrosis-both ventricles

- Left Ventricular Hypertrophy

Question 56

Explain the effect of RAAS in heart failure in my own words

Answer 56

Increase in angiotensin II stimulates aldosterone release which causes Na and water retention which causes and increase in preload so the heart has to work harder

Also increase in AngII causes vasoconstriction which increases the after load (blood left in the heart) so the heart has to work harder

Question 57

What are the Compensatory mechanisms in congestive heart failure

Answer 57

• expanded activation of the sympathetic system (increases HR, forcec and preload)
• Activation of the renin angiotensin aldosterone axis (increases preload, afterload, and causes hypertrophy)

Question 58

If the compensatory mechanisms in heart failure make heart failure worse (aka are bad for the heart) what is their goal

Answer 58

to maintain perfusion of vital organs by increasing preload, stimulating contractility and increasing arterial tone

Question 59

3 things Aldosterone does to CV system *****

Answer 59

• cardiac fibrosis
• LVH
• HTN

Question 60

Aldosterone Antagonists and chronic heart failure

Answer 60

• weak diuretics: small effect on preload
• Reduce potassium loss and hypokalemia and enhance the natriuresis due to other diuretics (when used w others)
• Block cardiac effects of aldosterone- decrease fibrosis and hypertrophy and arrhythmias
• IMPROVE SURVIVAL

Question 61

Prototypic aldosterone antagonists

Answer 61

Spironolactone, Eplerenone

Question 62

Effects of spironolactone and eplerenone

Answer 62

Reduce edema, anti-
arrhythmic, and decrease
fibrosis in the myocardium
and vessels (i.e.,
counteracts adverse
remodeling)

Question 63

What diuretics work in the proximal tubules cortex

Answer 63

CAI: Acetazolamide

Question 64

What diuretics work in the proximal tubule medulla

Answer 64

osmotic diuretics: Mannitol

Question 65

What diuretics work in the Thin ascending loop of henle

Answer 65

Loop Diuretics:
Furosemide
Bumetanide

Question 66

What Diuretics work in the cortical segment of distal tubule

Answer 66

Thiazide:

• Indapamide
• Hydrochlorothiazide
• Chlorthalidone

Question 67

What diuretics work in the collecting duct

Answer 67

K sparing