Lecture 4: Renal Patho and Diuretics

Question 1

Diuretics decrease ___ due to decrease in ___ volume

Indication
- edema
- hypertension
- heart failure
- acute renal failure

Answer 1

BP, plasma

Question 2

which type of transport is likely a drug target?

Answer 2

active
- ATP-mediated
- symport
- antiport

Question 3

7 Classifications of Diuretics

Answer 3

1. inhibitors of carbonic anhydrase
2. osmotic diuretics
3. inhibitors of Na-K-Cl symport (LOOP)
4. inhibitors of Na-Cl symport (THIAZIDE)
5. inhibitors of renal epithelial Na channels
6. mineralocorticoid receptor antagonists
7. vasopressin antagonists

Question 4

Location of carbonic anhydrase inhibitors

Answer 4

proximal convoluted tubule

Question 5

Location of osmotic diuretic

Answer 5

PCT & descending limb of loop of henle

Question 6

Location of Loop diuretics

Answer 6

ascending thick limb of loop of henle

Question 7

Location of Thiazides

Answer 7

DCT

Question 8

Renal Drug handling

glomerular filtration depends on:
- GFR
- size of ___
- extent of plasma protein binding: only ___ drug is filtered

Answer 8

• drug
• unbound

Question 9

active secretion in PCT: OAT and OCT

active secretion depends on:
- amount of ___ binding
- the rate of ___ of the drug to the secretory site
- the degree of ___ of transporters
- the presence of drugs that can ___ for these transporter

Relatively ___ (competition)

Answer 9

• plasma protein
• delivery
• saturation
• compete

non-selective

Question 10

active secretion in PCT: OAT and OCT Direction

1. diffusion out of ___ to interstitial space
2. transport across ___ membrane
3. secretion across ___ membrane

Answer 10

1. capillary
2. basolateral
3. luminal

Question 11

drugs actively transported by OCT

Answer 11

amiloride
cimetidine
digoxin
metformin
morphine
procainamide
quinidine
ranitidine
triamterene
trimethoprim
vancomycin

Question 12

drugs actively transported by OAT

Answer 12

furosemide
thiazides
penicillin
cephalosporin
probenecid
NSAIDs

Question 13

Organic Anion Transporter (OAT): Probenecid and Penicillin

• ___ by probenecid at OAT to slow penicillin excretion and prolong activity
• ___ max blood concentration

Answer 13

• competition
• doubles

Question 14

1. Carbonic Anhydrase Inhibitors

• Location: ___
• inhibit both cytoplasmic and membrane bound CA
• blocks reabsorption of ___

Answer 14

• PCT
• sodium bicarbonate (NaHCO3)

Question 15

1. CA-I

acetazolamide is used prophylactically for mountain sickness.
- effective due to metabolic ___ produced by the drugs counteracts the respiratory ___ that can result from hyperventilation in this condition.

Answer 15

• acidosis, alkalosis

Question 16

1. Carbonic Anhydrase Inhibitors SAR

Derived from ___
1. sulfamoyl group essentinal for ___
2. sulfamoyl N unsubstituted to retain ___
3. derivatives with high partition coefficient and lowest pKa have > ___

Answer 16

Sulfanilamide
- diuresis
- activity
- potency

Question 17

1. Clinical Uses of CA-I

• low ___ as diuretic
• acute ___ sickness
• metabolic ___
• glaucoma
• urinary ___

Answer 17

• efficacy
• mountain
• alkalosis
• alkalinization

Question 18

1. Toxicities of CA-I

• ___ metabolic acidosis
• renal stones
• renal ___ wasting
• drowsiness/paraesthesia

Answer 18

• hyperchloreic
• stones
• K

Question 19

2 Osmotic Diuretics

• location(s): ___ , ___
• larger, inert molecules
• non - ___
• altering renal medullary blood flow contributes to ___
• example: ___

Answer 19

• PCT, descending limb of loop of henle
• reabsorbable
• diuresis
• mannitol

mannitol, glucose, urea, isosorbide, glycerine

Question 20

3) Na-K-2Cl symport inhibitor

• aka ___ or ___ ceiling diuretics
• act on ___ surface symport = must be in ___ for diuretic activity
• ___ response after IV admin
• most ___ class (used for edema)
• some possess weak ___ inhibitory activity
• chronically reduce ___ acid secretion
• problems with ___ , ___ , and ___ reuptake (wasting)

Answer 20

• loop, high
• luminal, lumen
• rapid
• potent
• CA
• uric
• K, Ca, Mg

Question 21

3 Na-K-2Cl symport inhibitor SAR

1. sulfamoyl group in ___-position essential for optimal diuretic activity
2. substituent at 1-positing must be ___ ; ___ group provides optimal diuretic activity. Other groups such as ___ may have diuretic activity.
3. activating group in ___-position can be Cl or CF3, phenoxy, alkoxy, anilino, benzly, benzoyl

Answer 21

• 5
• acidic, carboxyl, tetrazole
• 4

Question 22

3) Na-K-2Cl symport inhibitor Clinical use

• edema
• acute ___ edema
• hypertension, heart failure
• acute hyper____
• hyper___
• acute renal failure
• ___ overdose

Answer 22

• pulmonary
• hypercalcemia
• hyperkalemia
• anion

Question 23

3) Na-K-2Cl symport inhibitor Toxicities

• dehydration
• hypo___ metabolic alkalosis
• ___toxicity
• ___uricemia
• ___magnesemia

Answer 23

• hypokalemic
• ototonicity
• hyperuricemia
• hypomagnesemia

Question 24

3) Na-K-2Cl symport inhibitors

___ is a loop diuretic that is not derived from sulfonamides
- binds with bioavailable ___ to form active conjugate

Answer 24

ethacrynic acid (Adedcrin)
- thiol

Question 25

4) inhibitors of Na-Cl symport

• aka ___ diuretics
• location: primary - ___, secondary - ___
• reduce ___ reuptake
• Examples (3)

Answer 25

• thiazide
• DCT
• PCT
• K
• chlorothiazide, hydrochlorothiazide, and metolazone

Question 26

4) inhibitors of Na-Cl symport SAR

What is this?

Answer 26

chlorothiazide

Question 27

4) inhibitors of Na-Cl symport SAR

thiazides have 2 subclasses: thiazides and hydrothiazides. In the picture, the molecule on the left is a ___ and the right is ___

Answer 27

thiazide, hydrothiazides

Question 28

4) inhibitors of Na-Cl symport Clinical Uses

• hypertension
• ___ failure
• ___ due to idiopathic hypercalciuria
• nephrogenic diabetes ___

Answer 28

• heart
• nephrolithiasis
• insipidus

Question 29

4) inhibitors of Na-Cl symport toxicities

• hypokalemic metabolic ___
• hyperuricemia
• impaired ___ tolerance
• hyperlipidemia
• ___natremia

Answer 29

• alkalosis
• carbohydrate
• hyponatremia

Question 30

Which of the following statements best explains why loop diuretics are far more effective than thiazide diuretics?
A) loop diuretics increase renin secretion
B) loop diuretucs are also weak inhibitors of CA
C) the diuretic effect of thiazides undergoes partial tolerance
D) The antihypertensive action of thiazides may reduce the glomerular filtration rate (GFR)
E) more sodium is physiologically reabsorbed at the loop of henle than at the DCT

Answer 30

E) more sodium is physiologically reabsorbed at the loop of henle than at the DCT

Question 31

5) inhibitors of renal epithelial Na Channels

• aka ___ diuretics
• location: late ___ and ___
• agents are relatively ___ diuretics
• primarily used in ___with other diuretics
• Examples (2)

Answer 31

• potassium-sparing
• DCT, collecting duct
• weak
• combination
• Amiloride, Triamterene

Question 32

5) inhibitors of renal epithelial Na Channels Clinical Uses

• adjunctive treatment with ___ or ___ diuretic in heart failure or hypertension

Answer 32

• thiazide, loop

Question 33

5) inhibitors of renal epithelial Na Channels Tox/Contraindications

toxicities:
- hyper___
- hyperchloremic metabolic acidosis

contraindications:
- ___ supplements
- ___ inhibitors

Answer 33

• hyperkalemia
• K
• ACE

Question 34

6) mineralocorticoid receptor antagonists (MRA)

• aka ___ antagonists, ___ diuretics
• bind to ___ but do not stimulate ___ production
• only diuretics that do not act within the ____
• example: ___
• strutures resemble ___

Answer 34

• aldosterone, potassium sparing
• MR, AIP
• tubular lumen
• spironolactone
• hormones

AIP = aldosterone induced proteins

Question 35

6) mineralocorticoid receptor antagonists clinical uses

• hypertension of heart failure with other diuretics
• ___ excess
• ___ (primary or secondary resulting from HF, hepatic cirrhosis, or nephrotic syndrome)

Answer 35

• mineralocorticoid
• aldosteronism

Question 36

6) mineralocorticoid receptor antagonists tox/contraindications

Toxicities
- hyper___
- hyperchloremic metabolic acidosis
- ___
- impotence
- benign ___ hyperplasia

Contraindications:
- ___ supplements
- ___ inhibitors
- chronic ___ insufficiency

Answer 36

• hyperkalemia
• gynecomastia
• prostatic
• K
• ACE
• renal

Question 37

7) Vasopressin Antagonists

• vasopressin is also called ___
• V2 receptors = fluid ___ at the kidneys to increase ___
• V1 receptors = ___ of blood vessels to increase systemic vascular ___
• When bound to both V1 and V2, results in increase of ___
• Examples (2)

Answer 37

• ADH
• reabsorption, blood volume
• constriction, resistance
• arterial pressure
• Convaptan, Tolvaptan

Question 38

7) Vasopressin Antagonists MOA

1. vasopressin is blocked from binding to the ___ receptor on the ___ membrane.
2. prevents aquaporins from relocating to the ___ membrane.
3. water cannot be ___ and is instead peed out as ___ urine
4. ___ plasma concentration is increased

Answer 38

1. V2, basolateral
2. luminal
3. reabsorbed, dilute
4. Na

Question 39

7) Vasopressin Antagonists

Conivaptan Dosing:
IV ___ mg daily for ___ days

Tolvaptan Dosing:
PO ___ to ___ mg daily

Which drug is more selective?

Answer 39

• 40 mg, 4 days
• 15-60 mg
• Tolvaptan (29.0 V2:V1 selectivity ratio vs 5.7)

Question 40

Pharmacokinetic/dynamic determinants of diuretic response

• site of action is ___
• CA-I, furosemide, and thiazide diuretic are all highly bound to ___ = ___ not filtered
• secretion is ___ = dose ___
• secretion of diuretics decreased with progressive renal failure, reducing their ___
• sensitivity to diuretics is reduced due to homeostatic responses in ___ (including hyperaldosteronism)

Answer 40

• luminal
• plasma protein, secreted
• saturable, dependent
• effectiveness
• CRF (chronic renal failure)

Question 41

Braking Phenomenon

• water follows ___
• when Na excretion > Na intake, BW and ECF ___
• activation of ___ and ___ nervous system = braking phenomenon
• when Na excretion = Na intake, BW and ECF stabilize at ___ level due to breaking effect
• when Na excretion < Na intake, BW and ECF ___

Answer 41

• salt (Na)
• decreased
• RAAS, SNS, lower
• rise

Question 42

Determinants of diuretic response Graph

sodium excretion rate vs loop excretion rate
Thank: what does the altered dose response relationship (braking) look like compared to normal

Answer 42

Question 43

T or F: as CHF progresses, diuretic potency goes down

Answer 43

F; efficacy drops

Question 44

T or F: CRF causes efficacy to shift, but potency can still be obtained with increased dose

Answer 44

F; caused POTENCY to shift, but EFFICACY can still be obtained with increased dose

Question 45

T or F: combination of diuretics with different mechanisms is more effective than dose increases of a single agent

Answer 45

T

Question 46

Location of renal epithelial Na channel inhibitors

Answer 46

Late DCT and collecting duct

Question 47

Location of mineralocorticoid receptor antagonist

Answer 47

Late DCT and collecting duct

Question 48

Location of vasopressin antagonists

Answer 48

Late DCT and collecting duct