Anti Hypertensive Drugs_Trans 2024.pdf

Transcript

ANTI-HYPERTENSIVE AGENTS
Professor: Dr. Jennifer T. Co, MD, FPOGS, FPIDSOG

Integrated Pharmacotherapeutics

HYPERTENSION BLOOD PRESSURE
Overview Formula

 In hypertensive patients, BP control systems are
“set” at a higher level of blood pressure
 HYPERTENSIVE CRISIS – systolic reading of 180
mmHg or higher or a diastolic reading of 110
mmHg or higher
 HYPERTENSIVE URGENCY – SBP ≥ 180 or DBP ≥ 110
BUT no associated organ damage
 HYPERTENSIVE EMERGENCY – generally occur at
blood pressure levels exceeding 180 systolic or 120
diastolic, but can occur at even lower levels in
patients whose blood pressure had not been
previously high
 Consequence – end-organ damage
- Stroke
- Loss of consciousness
- Memory loss Stroke Volume
- MI
- Renal and eye damage  Preload
- Aortic dissection o Filling volume of the heart
- Unstable angina  Afterload
- Pulmonary edema o Resistance the ventricles face on ejection
- Eclampsia of blood
o Tension the ventricle develops during
ESSENTIAL OR PRIMARY HYPERTENSION contraction
 Contractility
 Patients in whom no specific cause of o Efficiency and vigor of contraction of the
hypertension can be found heart muscle

SECONDARY HYPERTENSION DETERMINANTS

 Patients with specific etiology  LV preload or LV end diastolic pressure
o Blood volume and pulmonary vein
pressures, along with venous tone and
ETIOLOGY rate of return
 Contractility
A. Increased cardiac output o Amount of cystolic Ca++ during the
1. Hypervolemia excitation sequence (major), condition of
i. Renal artery stenosis cardiac muscle
ii. Renal disease  LV afterload or LV end systolic pressure
iii. Hyperaldosteronism o Aortic pressure, peripheral vascular
iv. Hypersecretion of ADH resistance (arterioles)
v. Aortic Coarctation
vi. Pregnancy Induced HPN (PIH) Regulation of Blood Pressure
2. Stress – sympathetic activation
3. Pheochromocytoma – increased
4 PRIMARY PHYSIOLOGIC SITES OF BP CONTROL
catecholamines
B. Increased vascular resistance
1. Stress – sympathetic activation  Autonomic nervous system
2. Atherosclerosis  Heart
3. Renal artery disease – increased  Vasculature
angiotensin II  Kidneys
4. Pheochromocytoma – increased
catecholamines
C. Thyroid dysfunction
D. Diabetes
E. Cerebral ischemia

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4 SITES OF REGULATION OF CO AND PVR DRUGS THAT ALTER SODIUM AND WATER BALANCE
(DIURETICS)
 Postcapillary venules (capacitance vessels)
 Arterioles
 Heart
 Kidneys

Thiazides
 Hydrochlorothiazide, Chlorothiazide,
Bendroflumethiazide, Hydroflumethiazide,
 Regulation of blood pressure in hypertensive
Methylclothiazide, Polythiazide,
patients differs from healthy patients in that the
Trichlomethoazide
baroreceptors and the renal blood volume
o Inhibit Na/Cl transporter predominantly in
pressure control systems appear to be set up at a
the distal convoluted tubule
higher level of blood pressure.
Loop Diuretics
SHORT-TERM REGULATION OF BP: POSTURAL BARORECEPTOR  Furosemide, Bumetanide, Torasemide, Ethacrynic
REFLEX acid
o Inhibit NaCl reabsorption in the thick
Rapid, moment to moment adjustment in BP → reduce ascending loop of Henle (Na+/K+/2Cl-
afferent signals to the CNS → reduce vagal tone → transporter)
increase sympathetic tone → regulation of BP Potassium Sparing Diuretics
 Spironolactone, Eplerenone, Triamterene,
Amiloride
LONG-TERM REGULATION OF BP: RENAL BLOOD VOLUME-
o Prevent K secretion by antagonizing the
PRESSURE CONTROL SYSTEMS
effect of aldosterone in the collecting
tubules
 Reduction in renal perfusion pressure leads to  Triamterene and amiloride
intrarenal redistribution of blood flow and o inhibit Na+ influx through ion channels
increased reabsorption of salt and water (Na/K transporters) in the luminal
 Decreased pressure in renal arterioles as well as membrane
sympathetic neural activity (via adrenoceptors)  Spironolactone, eplerenone
stimulates production of renin o direct pharmacologic antagonism of
 Renin increases production of angiotensin II mineralocorticoids receptors
 Angiotensin II causes:  Limited natriuretic activity
o Direct constriction of resistance vessels
o Stimulation of aldosterone synthesis in the Sulfonamide
adrenal cortex, which increases renal  NOT a thiazide but qualitatively similar to thiazide
sodium absorption and intravascular  Indapamide, Metolazone, Xipamide,
blood volume Chlorthalidone, Quinethazone

BASIC PHARMACOLOGY OF ANTIHYPERTENSIVE AGENTS
MOA AND HEMODYNAMIC EFFECTS

Primarily be depleting body sodium stores

 Sodium is believed to contribute to vascular
resistance by increasing vessel stiffness and neural
reactivity, possible related to altered sodium-
calcium exchange with a resultant increase in
intracellular calcium
 These effects are reversed by diuretics
 Initially: Increase Na+ excretion → decrease blood
volume → decrease in cardiac output
 After 6-8 weeks: CO return to normal and PVR
declines

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 Effect on vascular resistance (vessel stiffness and ADVERSE EFFECTS
neural reactivity)
o Decrease Na+ of vessel walls → decrease
Na+Ca2+ exchange → decrease
intracellular Ca2+ concentration

THERAPEUTIC USE

 Effectively lower the BP by 10-15 mmHg in most
patients
 As monotherapy (mild to moderate hypertension)
or in combination with other drugs

Thiazide diuretics  Hypokalemia (except for K-sparing diuretics)
 Appropriate for patients with mild or moderate  Hypomagnesemia, impaired glucose tolerance
hypertension and normal renal and cardiac  Hyperlipidemia, reduced uric acid excretion
function  K-sparing diuretics + ACE inhibitors or renal
 Chlorthalidone is likely to be more effective than insufficiency = HYPERkalemia
hydrochlorothiazide because it has a longer  Diuretics + digitalis, anti-arrhythmia, those with MI
duration of action or LV dysfunction = HYPOkalemia (hazardous)
 Hypertension, congestive heart failure,
nephrolithiasis secondary to idiopathic
hypercalciuria, nephrogenic diabetes insipidus, SUMMARY OF THE MOA AND EFFECTS OF VARIOUS CLASSES
severe resistant edema OF DIURETICS

Loop Diuretics (Furosemide)
 More powerful diuretics (e.g. those acting on the
loop of Henle)
 Necessary is severe hypertension, when multiple
drugs with sodium-retaining properties are used
 In renal insufficiency, when glomerular filtration
rate is less than 30 40 mL/min
 In cardiac failure or cirrhosis, in which sodium
retention is marked
 Hyperkalemia – enhanced by simultaneous NaCl DRUGS THAT ALTER SYMPATHETIC NERVOUS SYSTEM
and water administration
 Salt and water retention – acute pulmonary Centrally Acting Sympathoplegic Drugs
edema, chronic heart failure, hepatic cirrhosis
with ascites  Methyldopa
 Acute renal failure and hypercalcemia  Clonidine
 Anion overdose – bromide, fluoride, iodide  Guanfacine
o Saline solution administered to replace  Guanbenz
urinary loss of Na and Cl to avoid ECV
depletion MOA:
 Reduce sympathetic outflow from vasopressor
Potassium-sparing diuretics centers in brainstem and retain or with increased
 Useful both to avoid excessive potassium sensitivity to baroreceptor control
depletion and to enhance the natriuretic effects
of other diuretics
 Congestive heart failure, aldosteronism and
hyperaldosteronism, lithium-induced diabetes
insipidus

Aldosterone receptor antagonists
 Favorable effect on cardiac function in people
with heart failure

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  Mechanism and site of action
o Gradual depletion of NE in the nerve
ending (peripheral)
o Neuronal uptake is necessary for the
hypotensive activity of the drug
 Main Effects:
o Decrease in PVR and HR → decrease BP
 Drug Interaction:
o Drugs that block catecholamine uptake
or displaces amines from nerve terminals,
cocaine, amphetamines, TCA,
phenothiazines, phenoxybenzamines
 Adverse Effects:
o Can produce all of the toxicities
expected from pharmacologic
sympathectomy including marked
postural hypotension, diarrhea, and
impaired ejaculation
 Pharmacokinetic:
o Poorly absorbed from the GI
o Onset slow, peak of action 1-2 weeks
o Metabolites excreted in urine
o Half-life: 5 days
 Use: Not used anymore because of severe side
effects

THERAPEUTIC USE: Reserpine
 Treatment of hypertension, either alone or with  Disrupts norepinephrine vesicular storage
other agents  Mechanism and site of action
 Usually used after other agents have failed due to o Interferes with vesicular membrane
side effects associated transporter (VMAT) →
 Also may be used for treatment of severe depletes NT (NE, dopamine, serotonin) in
dysmenorrhea, menopausal flushing, glaucoma the storage vesicle of the central and
 Clonidine is useful in the management of peripheral nerve endings
withdrawal symptoms in opioid- or nicotine- o Reserpine effects on adrenergic vesicles
dependent persons are irreversible and occurs throughout the
body
Ganglionic Blocking Agents  Main effects
o Depress CNS function centrally and
 Trimethaphan
peripherally decrease HR, contractility
 Mecamylamine
(CO) and peripheral vascular resistance
 Adverse effects
MOA:
o Depression, sedation, nightmares, ulcers,
 Competitively block nicotinic cholinoceptors on
diarrhea, abdominal cramping, nasal
postganglionic neurons in both sympathetic and
stuffiness, orthostatic hypotension, dry
parasympathetic ganglia
mouth, impotence and extrapyramidal
effects
ADVERSE EFFECTS:
 Sympathoplegia
Alpha Adrenoreceptor Antagonist
o Excessive orthostatic hypotension and
sexual dysfunction
 Prazosin
 Parasympathoplegia  Doxazosin
o Constipation, urinary retention,  Terazosin
precipitation of glaucoma, blurred vision,
dry mouth, etc. Main Effects
 Decrease PVR → decrease BP

Adrenergic Neuron-Blocking Agents Pharmacokinetics
 Terazosin – extensively metabolized but
undergoes very little first-pass metabolism with a
Guanethidine
half-life of 12 hours
 Prevents norepinephrine release from nerve
 Doxazosin has an intermediate bioavailability and
terminals
a half-life of 22 hours
 Prazosin - half-life is 22 hours

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Adverse Effects o Some patients may experience
 1st dose phenomenon which is common in withdrawal symptoms (due to
patients who are salt- and volume-depleted, fluid upregulation or super sensitivity of B-
retention, dizziness, headache, palpitations adrenoceptor, thus the drug should not
 Long term treatment causes little postural be withdrawn abruptly)
hypotension, a precipitous drop in standing blood Metoprolol and Atenolol
pressure develops in some patients shortly after  Relative cardioselectivity is advantageous in
the first dose is absorbed. Therefore, first dose treating hypertensive patients who also suffer from
should be small and should be administered at asthma, diabetes, or peripheral vascular disease
bedtime  Approximately equipotent to propranolol in
 Some patients develop a positive test for inhibiting stimulation of B1 adrenoceptors such as
antinuclear factor in serum while on prazosin those in the heart but 50- to 100-fold less potent
therapy, but this has not been associated with than propranolol in blocking 2 receptors
rheumatic symptoms  Metoprolol is extensively metabolized by CYP2D6
with high first pass metabolism. The drug has a
Clinical Use relatively short half-life of 4 to 6 hours, but the
 More effective when used in combination with B extended-release preparation can be dosed
blocker and a diuretic, than when used alone daily.
 Used primarily in men with concurrent  Atenolol is not extensively metabolized
hypertension and benign prostatic hyperplasia  Excreted primarily in the urine
 Half-life of 6 hours; usually dosed once daily
Tamsulosin  Atenolol is reported to be less effective than
 Competitive α1 antagonist with a structure quite metoprolol in preventing the complications of
different from that of most other α1-receptor hypertension
blockers Nadolol, Carteolol, Betaxelol and Bisoprolol
 High bioavailability and a half-life of 9 to 15 hours  Non-selective B-receptor antagonist
 Metabolized extensively in the liver  Betaxolol and bisoprolol are B1-selective blockers
 Higher affinity for α1A and α1D receptors than for that are primarily metabolized in the liver but have
the α1B subtype long half lives
 Relatively greater potency in inhibiting  Because of long half lives these drugs are
contraction in prostate smooth muscle versus commonly administered on once OD
vascular smooth muscle compared with other a-1  Increases in dosage to obtain a satisfactory
selective antagonists therapeutic effect should take place no more
than every 4 or 5 days
Beta Adrenergic Blocking Agents  Dose adjustment in Nadolol and Carteolol among
patients with reduced renal function

Pindolol, Acebutolol, Penbutolol
 Partial agonists, i.e., B blockers with some intrinsic
sympathomimetic activity
 Lower blood pressure but are rarely used in
hypertension
 Beneficial for patients with bradyarrhythmia or
peripheral vascular disease
 In severe hypertension, all beta blockers are useful
in preventing the reflex tachycardia that often Labetalol, Carvedilol, Nebivolol – both beta blocking and
results from treatment of direct vasodilators vasodilating effects
 Reduce mortality after MI and some also reduce Labetalol
mortality in patients with heart failure  Has 3:1 ratio of beta:alpha antagonism after oral
dosing
Propranolol  Blood pressure is lowered by reduction of systemic
 Mechanism and Sites of Action vascular resistance (via blockade) without
o Decreases blood pressure primarily as a significant alteration in heart rate or cardiac
result of a decrease in cardiac output output
o Inhibits the stimulation of renin production  Useful in treating the hypertension of
by catecholamines (mediated receptor) pheochromocytoma and hypertensive
o Propranolol’s effect is due in part to emergencies
depression of the RAAS
 Pharmacokinetics Carvedilol
o Resting bradycardia and a reduction the  S (-) isomer is a non-selective B adrenoreceptor,
heart rate during exercise but both S (-) and R (+) have approximately equal
 Adverse Effects and Toxicity α-blocking potency
o Result primarily from cardiac vascular or  Useful in patients with both heart failure and
bronchial beta receptors activity hypertension

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Nebivolol  Adverse effects
 Highly selective B1 blocking effects thus its effect o Reflex tachycardia, headache, flushing,
is not mediated by α blockade increase intraocular pressure
 Vasodilating effect may be due to an increase in  Clinical uses
endothelial release of NO via induction of o Hypertensive emergencies,
endothelial nitric oxide synthase postoperative hypertension

Esmolol Hydralazine
 Rapidly metabolized via hydrolysis by RBC  Mechanism of action
esterases o Interferes with IP3 on Ca+2 release from
 Has a short half life of 9 minutes and is sarcoplasmic reticulum
administered by IV route  Site of action – arterioles but not veins
 Used for management of intraoperative and  Clinical use
postoperative hypertension, and sometimes for o Severe hypertension, hypertension in
hypertensive emergencies, particularly when pregnancy
hypertension is associated with tachycardia  Pharmacokinetics
o Absorption: Well absorbed orally
Proposed Mechanisms: (Propranolol and other beta o Distribution: 25% bioavailability
blockers) o Metabolism: Liver (Acetylation)
1. Block cardiac B1 receptors → lower CO  Rapid acetylators have greater
2. Block renal B1 receptors → lower renin → lower first pass metabolism, lower blood
angiotensin II → lower PVR levels, and less antihypertensive
3. Decrease sympathetic vasoconstrictor nerve benefit from a given dose than
activity do slow acetylators
 For slow acetylators 400 mg/day
Vasodilators (10-20% incidence) LE syndrome
may develop
A. Calcium antagonist  T ½ = 1.5 – 3 H
B. Drugs that activate potassium channels  Adverse effect
C. Drugs that act via cyclic nucleotides o Headache, nausea, anorexia
D. Cyclase activation cGMP o Sympathetic stimulation: palpitations,
E. Indirectly acting vasodilator drugs reflex tachycardia, angina, ischemic
arrhythmia
 All the vasodilators that are useful in hypertension o Lupus erythematosus like syndrome
relax the muscle of arterioles (decrease in PVR) (arthralgia, myalgia, skin rashes, and
 Decreased arterial resistance and decreased fever)
mean arterial pressure elicit compensatory o Peripheral neuropathy and drug fever
responses
 These responses are mediated by baroreceptor,
DRUGS THAT ACTIVATE THE POTASSIUM CHANNEL
SNS and renin, angiotensin, and aldosterone

 Minoxidil
 Diazoxide
 Cromikalim
 Lemakalim
 Nicorandil

Minoxidil
 Mechanism of action
o Opening of potassium channel by
minoxidil sulphate (active metabolite) →
K efflux → hyperpolarization →
DIRECT ACTING VASODILATORS vasodilatation
 Site of action – arterioles but not vein
Fenoldopam  Pharmacokinetics
 Mechanism of action o Absorption: Well absorbed from GIT,
o D1 – dopamine receptor agonist Bioavailability of 90%
o Site of action: peripheral arteries o Distribution: action may persist for 24H
 Pharmacokinetics o Metabolism: Liver (Conjugation)
o Metabolism: liver (conjugation)  T ½ = 4 hours
o T ½ = 10 mins  Adverse Effects
o Administered by continuous infusion and o Sympathetic stimulation: Tachycardia /
initiated at low doses palpitations, angina, edema, headache,
sweating, hypertrichosis

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Diaxozide o Thiocyanate toxicity maybe manifested
 Mechanism of Action as weakness, disorientation, psychosis,
o Bind to SUR1 subunit of K+/ATP channels in muscle spasm, and convulsion. This is
pancreatic B cells → stabilizes ATP-bound confirmed by serum concentration
(open) state → B cells hyperpolarized → greater than 10 mg/dL
inhibit insulin secretion o Methemoglobinemia maybe observed
 Site of Action: arteriole  Antidote:
 Pharmacologic actions o Sodium thiosulfate as sulfur donor
o Rapid fall in ABP, increase in cardiac o Hydroxocobalamin combined with
output cyanide to form non-toxic
o Similar chemically with thiazide but has no cyanocobalamin
diuretic activity
 Pharmacokinetics CALCIUM CHANNEL ANTAGONISTS/BLOCKERS
o Distribution: Bound extensively to serum
albumin and vascular tissue
o Onset of action: 5 minutes
o Duration of action: 4-12 hours
o Metabolism: Not well characterized
T ½ = 24 hours, unchanged
Excretion: unchanged
 Adverse effects
o Excessive hypotension, reflex sympathetic
response → angina → ischemia →
cardiac failure
o Hyperglycemia, cardiac failure
 Clinical uses
o Hypertensive emergencies
o Treatment of hypoglycemia secondary to
insulinoma
 Drug interaction
o Hypotensive activity is greater if
pretreated with B-blockers

DRUGS THAT ACT VIA CYCLIC NUCLEOTIDES CYCLASE
ACTIVATION CGMP

 Mechanism of Action (in hypertension and in part
Nitroprusside (Nitropress) in angina)
 Mechanism of action o Inhibition of calcium influx into arterial
o Activates guanylyl cyclase either via smooth muscle
release of nitric oxide or by direct  Pharmacokinetics
stimulation of the enzyme → increase o Hemodynamic differences may influence
cGMP → relaxes vascular smooth muscle the choice of particular agent
 Sites of action: arteries and veins o Nifedipine and other DHP agents are
 Pharmacological actions: more selective as vasodilators and have
o Reduces the peripheral vascular less cardiac depressant effect than
resistance and venous return verapamil and diltiazem
o No change or slight decrease in CO o Reflex sympathetic activation with slight
 Pharmacokinetics tachycardia maintains or increase
o Metabolism: rapidly metabolized within cardiac output in DHP
RBC → liberating cyanide which is o Verapamil has the greatest depressant
metabolized by rhodanese in the effect on the heart and may decrease HR
presence of sulfur donor → Thiocyanate and CO
(less toxic) → distributed then in ECF and o DHP sustained release (SR) or those with
eliminated longer half-lives provide smoother blood
o Excretion: Kidneys pressure control than short acting oral
o Duration of action: 1 to 10 minutes DHP. These are the preferred drugs in
 Clinical uses: hypertensive emergencies, severe chronic hypertension
heart failure  Clinical Use
 Adverse effects: (due to accumulation of o Emergency management of severe
cyanide) hypertension, safe in pregnancy
o Metabolic acidosis, arrhythmias,
excessive hypotension, death

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  Adverse Effects
o Severe hypotension
o Acute renal failure especially among
patients with bilateral renal stenosis
o Hyperkalemia, dry cough with wheezing
and angioedema
o Minor reactions: altered sense of taste,
allergic skin rashes and drug fever
 Contraindications
o Pregnancy
INDIRECTLY ACTING VASODILATORS
o Renal insufficiency
 Drug interaction
1. Inhibit vasoconstriction Clonidine, Methydopa o Potassium supplement or potassium
2. Renin-angiotensin sparing
system o NSAIDs
Drugs that block renin Propranolol
secretion Angiotensin Receptor Blockers (ARBs)
Renin inhibitors Aliskiren  Mechanism
ACE Inhibitors Sulfhydryl 2containing: o NO effect on bradykinin
Captopril, Fentiapril, o More selective blocker of angiotensin
Pivalopril, Zofenopril, and more complete inhibition of
Alacepril angiotensin action compared to ACEI
 Adverse effect
Dicarboxyl 2containing: o Cough and angioedema are uncommon
Enalapril, Lisonopril, o Similar to ACE inhibitors including the
Benazepril, Quinapril, hazard of use during pregnancy
Moexipril, Ramipril,  More commonly used among patients who have
Spirapril, Perindopril, had adverse effects to ACEI
Pentopril, Cilazapril
DIURETICS
Phosphorous containing:
Fosinopril  Act by reduction of blood volume and direct
Angiotensin II Candesartan, Irbesartan,  vascular effects
Receptor Blockers Telmisartan, Valsartan,  Deplete body sodium stores
Losartan, Olmesartan  Often provide adequate treatment for mild to
moderate hypertension
ACE Inhibitors  In more severe hypertension combined with
 Mechanism of Action sympathoplegic and vasodilators
o Inhibits peptidyl dipeptidase and
inactivates bradykinin
o Hypotensive action results from both
inhibitory action on RAAS and stimulatory
action Kallikrein-Kinin system
 Enalapril is a product that is converted by
hydrolysis to an enalaprilat, a converting enzyme
inhibitor
 Enalaprilat in itself is primarily use for hypertensive
emergencies and given thru IV
 Main effects
o Decreased PVR, decreased BP
o Cardiac output and heart rate are not
significantly changed
o These agents do not result in reflex
sympathetic activation
o There is no correlation between plasma
renin activity and hypotensive effects of
the drug
 Clinical Use
o Recommended among diabetics
o Patients with chronic kidney disease
o Heart failure and MI are proved to be
responsive with these drugs

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 Classes of Diuretics CARBONIC ANHYDRASE INHIBITORS

 Acetazolamide: used for glaucoma, altitude
sickness, and to reduce metabolic alkalosis
 Block carbonic anhydrase in the brush border and
cytoplasm of proximal tubule cells and other
tissues (eye and brain)
 Orally active; some members of the group
(dorzolamide) are available in topical form for
glaucoma; duration of action: 8 — 12 hours
 Toxicities:
o Oral: GI upset, paresthesias, hepatic
encephalopathy (if with severe hepatic
impairment)
o Cross-allergenicity with sulfonamides

ANTIDIURETIC HORMONE AGONISTS
Electrolyte Changes Produced by Diuretic Drugs

 Vasopressin, desmopressin (analogue of
vasopressin)
o For pituitary deficiency diabetes insipidus
o Collecting ducts are responsive to
vasopressin and insert additional water
channels (aquaporins) into the luminal
membrane facilitate water resorption —>
restores urine concentrating power to
normal
 NOT useful for nephrogenic diabetes insipidus
o Does not respond to pituitary peptides;
OSMOTIC DIURETICS treated INDIRECTLY with thiazides urine
osmolality is increased but not to normal
maximal levels
 Mannitol: for acute glaucoma, increased ICP,
o Thiazides decrease blood volume —>
protects kidney from solute overload due to crush
lead to compensatory water
injury or chemotherapy
reabsorption from proximal tubule —>
 Small, non-absorbable molecule; osmotically
reduces urine volume
inhibits resorption of water in water-permeable
 Duration of action
portions of the nephron
o Vasopressin and desmopressin 4 — 8 hrs
 Given IV; duration of action: 1 —2 hours
o Thiazides —> up to 12 hours
 Toxicities: headache, GI upset, hypotension, mild
 Toxicities
hyponatremia, followed by hypernatremia
o Vasopressin and desmopressin — rarely
 REMEMBER: In HF, the increased hydrostatic
cause vasoconstriction with hypertension
pressure proximal to the left atrium causes
or coronary spasm
transudation in the lungs
o Thiazides — hyponatremia,
o Prior to diuresis, mannitol initially increases
hyperlipidemia, hyperuricemia
plasma volume due to its effects on
 Demeclocycline — prevents hyponatremia in
elevating plasma oncotic pressure
SIADH; MOA unclear
o Increased plasma volume -Y increased
o Can cause iatrogenic diabetes insipidus
left atrial preload in the face of
(like lithium) by blocking ADH-like
decompensation (even at a lower
peptides
preload) —> increased left atrial preload
o Used orally; duration of action 10 — 16 hrs
and PCWP —> exacerbation of fluid
o Toxicities:
transudation in the lungs
 Like other tetracyclines —
 Mannitol is confined to the extracellular
disorders of developing bones
compartment exclusively raises osmolarity of the
and teeth in children; rash, GI
ECF -Y draws water out of intracellular
upset, hepatic dysfunction
compartment -Y higher over all extracellular
volume -Y volume overload and edema

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  Conivaptan  Chlorothiazide — less lipid soluble and given in
o Antagonist at Via, V2 receptors large doses
o Clinical applications: SIADH,  Chlorthalidone slowly absorbed, longer duration
hyponatremia of action
o PK: administered parenterally  Bendrofluazide, Hydrochlorothiazide,
o Toxicities: infusion site reactions Cyclopenthiazide and Chlorothiazide — onset of
 Tolvaptan
action 12 hrs, maximum 4-6 hrs, duration 8-12 hrs
o like conivaptan but more selective for V2
 Indapamide — excreted primarily by the biliary
receptors
system
 All secreted by organic secretory system and
LOOP DIURETICS
compete with secretion of UA by that system
 CLINICAL USES
 Furosemide, ethacrynic acid; used for conditions o Hypertension,
associated with moderate or severe hypertension o Congestive heart failure,
or fluid retention (heart failure, cirrhosis, nephrotic o Nephrolithiasis 2' to idiopathic
syndrome) hypercalciuria,
 Most efficacious diuretics currently available o Nephrogenic diabetes insipidus,
 Block Na+/K+/2Cl- symporter in the ascending o Severe resistant edema
limb of the loop of Henle  TOXICITIES:
o Indirect effect: increase calcium and o hypokalemic metabolic alkalosis,
magnesium excretion hyperuricemia, impaired carbohydrate
o Useful in the management of severe tolerance, hyperlipidemia (5-15%
hypercalcemia; must be given with saline increase in serum cholesterol and LDL),
infusion to prevent hemoconcentration hyponatremia, hypercalcemia, allergic
 Orally active but can also be used IV; duration of reactions, weakness, fatigability, and
action: 2 —4 hours paresthesias, impotence has been
 Toxicities: hypokalemia, hyperurecemia, reported probably related to volume
hypomagnesemia, ototoxicity, renal impairment depletion
o Effects are diminished by NSAIDs
o All are sulfonamides EXCEPT ethacrynic
acid POTASSIUM-SPARING (ALDOSTERONE ANTAGONIST)
DIURETICS

 Used to prevent potassium wasting by
otherdiuretics
 Spironolactone and eplerenone
o Particularly effective in treating heart
failure and other high aldosterone
THIAZIDES
conditions
o Block cytoplasmic aldosterone receptor;
 Prototype: Hydrochlorothiazide weak antagonism of androgen receptors
 One of the first-line agents for hypertension o Eplerenone — more selective for
 Inhibit Na/Cl transporter predominantly in the mineralocorticoid receptor
distal convoluted tubule
 Reduces blood/extracellular volume and cardiac  Amiloride and triamterene
output initially o Block sodium channels in the
 Eventually, normal cardiac output, I PVR (due to collecting tubule
depleted sodium stores)  Orally active; duration of action is 12 — 72
hours
 Toxicities: hyperkalemia (major), GI upset
o Spironolactone — antiandrogen
effects

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  In the general population