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Title: PHL%20313%20

1
PHL 313 315 VASODILATORS Autacoids
ALHARBI, Ph.D.
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AutacoidsTEXTBOOKBasic and Clinical
Pharmacology12th edition Author
Katzung, B. Publisher Lang
Medical Books.
4
GENERAL PROPERTIES OF VASODILATORS 1-
Vasodilator drugs can be classified based on
their site of action (arterial versus venous)
3- Some drugs primarily dilate resistance vessels
(arterial dilators e.g., hydralazine) 4- while
others primarily affect venous capacitance
vessels (venous dilators e.g., nitroglycerine).
5- Most vasodilator drugs have mixed arterial
and venous dilator properties (mixed dilators
e.g., alpha-adrenoceptor antagonists, angiotensin
converting enzyme inhibitors).
5
Therapeutic Uses of VASODILATORS1-
Hypertension2- Congestive heart failure3-
Coronary artery insufficiency4- HemostasisSlow
bleeding into surgical field5-
ImpotenceIncreased erectile function 6-
Peripheral vascular disease
6

Common Side-Effects of Vasodilators 1-
Systemic vasodilation and arterial pressure
reduction can lead to a baroreceptor-mediated
reflex stimulation of the heart LEADING TO2-
TACHYCARDIA This increases oxygen demand, which
is undesirable if the patient also has coronary
artery disease.
7
Common Side-Effects of Vasodilators3-
OROTHSTATIC HYPOTENSIONVasodilators can impair
normal baroreceptor-mediated reflex
vasoconstriction when a person stands up, which
can lead to orthostatic hypotension and syncope
upon standing. 4- RENAL RETENTION Of SODIUM
AND WATERVasodilators can lead to renal
retention of sodium and water, which increases
blood volume and cardiac output and thereby
compensates for the reduced systemic vascular
resistance.
8
Common Side-Effects of Vasodilators5-
HEADACHEDue to Vasodilation of cerebral blood
vessel6- Cutaneous FlushingDue to
vasodilation of skin blood vessels.
9
MAJOR DRUG CLASSES OF VASODILATORS 1-
Nitrodilators2- potassium-channel openers3-
direct acting vasodilators (multiple actions)
only Hydralazine4- calcium channel blockers
(CCBs)5- Endothelin receptor antagonist6-
Renin inhibitors7- Angiotensin converting
enzyme inhibitors (ACE-I)8- Angiotensin-ii
receptor blockers (ARBs)9- Phosphodiestrase-type
5 inhibitors10- Activation of dopamine
receptors (D1-receptors) -
Fenoldopam
10
1- Nitrodilators There are two basic types of
nitrodilators 1- Release NO spontaneously
(e.g., sodium nitroprusside)2- organic nitrates
that require an enzymatic process to form NO.
- Organic nitrates do not directly release NO
- nitrate groups interact with enzymes and
intracellular sulfhydryl groups that reduce the
nitrate groups to NO or to S-nitrosothiol, -
which then is reduced to NO. - Nitric oxide
activates smooth muscle soluble guanylyl cyclase
(GC) to form cGMP. - Increased
intracellular cGMP inhibits calcium entry into
the cell, thereby decreasing intracellular
calcium concentrations and causing smooth muscle
relaxation
11
1- Examples of NitrodilatorsNitrogly
cerin Isosorbide dinitrate (Isordil,
Sorbitrate, Dilatrate)Isosorbide Mononitrate
Sodium nitroprusside (Nitropress)Hydralazine
(Apresoline) (actually its action is not through
nitric oxide)
12
ORGANIC NITRATES1- These agents are
prodrugs that are sources of nitric oxide (NO).
2- NO activates the soluble isoform of
guanylyl cyclase, thereby increasing
intracellular levels of cyclic GMP. 3- In
turn, cyclic GMP promotes the dephosphorylation
of the myosin light chain and the reduction of
cystolic Ca2 and leads to the relaxation of
smooth muscle cells in a broad range of tissues.

13

NONPROPRIETARY NAMES AND TRADE NAMES CHEMICAL STRUCTURE PREPARATIONS, USUAL DOSES, AND ROUTES OF ADMINISTRATIONa
Nitroglycerin (glyceryl trinitrate NITRO-BID, NITROSTAT, NITROL, NITRO-DUR, others) T 0.3-0.6 mg as needed S 0.4 mg per spray as needed C 2.5-9 mg 2-4 times daily B 1 mg every 3-5 h O 2.5-5 cm, topically to skin every 4-8 h D 1 disc (2.5-15 mg) for 12-16 h per day IV 10-20 g/min increments of 10 g/min to a maximum of 400 g/min
Isosorbide dinitrate (ISORDIL, SORBITRATE, DILATRATE-SR, others) T 2.5-10 mg every 2-3 h T(C) 5-10 mg every 2-3 h T(O) 5-40 mg every 8 h C 40-80 mg every 12 h
Isosorbide-5-mononitrate (IMDUR, ISMO, others) T 10-40 mg twice daily C 60-120 mg daily
14

Cardiovascular Effects
1- Low concentrations of nitroglycerin preferentia
lly dilate veins more than arterioles.
2- This venodilation decreases venous return,
leading to a fall in left and right ventricular
chamber size and end-diastolic pressures
3- Systemic arterial pressure may fall slightly,
and heart rate is unchanged or may increase
slightly in response to a decrease in blood
pressure.
4- Doses of nitroglycerin that do not alter
systemic arterial pressure may still produce
arteriolar dilation in the face and neck,
resulting in a facial flush, or dilation of
meningeal arterial vessels, causing headache.

Cardiovascular Effects
1- Higher doses of organic nitrates cause further
venous pooling and may decrease arteriolar
resistance as well
2- thereby decreasing systolic and diastolic
blood pressure and cardiac output and causing
pallor, weakness, dizziness, and activation of
compensatory sympathetic reflexes.
3- The reflex tachycardia and peripheral
arteriolar vasoconstriction tend to restore
systemic vascular resistance this is
superimposed on sustained venous pooling.
4- Coronary blood flow may increase transiently
as a result of coronary vasodilation but may
decrease subsequently if cardiac output and blood
pressure decrease sufficiently.
5- In diabetic patient with neuropathy, nitrates
may reduce arterial pressure and coronary
perfusion pressure significantly, producing
potentially life-threatening hypotension and even
aggravating angina.

Cardiovascular Effects
organic nitrates cause dilation and prevent
vasoconstriction of large epicardial vessels
without impairing autoregulation in the small
vessels, which are responsible for 90 of the
overall coronary vascular resistance.
sublingual nitroglycerin can dilate epicardial
stenoses and reduce the resistance to flow
In patients with angina owing to coronary artery
spasm, the ability of organic nitrates to dilate
epicardial coronary arteries, and particularly
regions affected by spasm, may be the primary
mechanism by which they are of benefit.

Cardiovascular Effects
Mechanism of Relief of Symptoms of Angina
Pectoris
The ability of nitrates to dilate epicardial
coronary arteries, even in areas of
atherosclerotic stenosis, is modest
The main action is reduction in myocardial work
leading to decrease in myocardial O2 demand, as
their primary effect in chronic stable angina.
This accomplish by decrease preload

Tolerance
1- repeated or continuous exposure to high doses
of organic nitrates leads to a marked attenuation
in the magnitude of most of their pharmacological
effects.
2- The magnitude of tolerance is a function of
dosage and frequency of use.
3- Tolerance may result from a reduced capacity
of the vascular smooth muscle to
convert nitroglycerin to NO,
4- Multiple mechanisms have been proposed to
account for nitrate tolerance, including volume
expansion, neurohumoral activation, cellular
depletion of sulfhydryl groups, and the
generation of free radicals

Tolerance
5- associated with oxidative stress that is why
hydralazine (anti-oxidant) decreases organic
nitrate tolerance
6- A more effective approach to restoring
responsiveness is to interrupt therapy for 8-12
hours each day, which allows the return of
efficacy.
It is usually most convenient to omit dosing at
night in patients with exertional angina either
by adjusting dosing intervals of oral or buccal
preparations or by removing cutaneous
nitroglycerin
7- Coronary and digital arteriospasm during
withdrawal and its relaxation by nitroglycerin
also have been demonstrated radiographically.
Because of the potential problem of nitrate
dependence, it seems prudent not to withdraw
nitrates abruptly from a patient who has received
such therapy chronically.

Interaction of Nitrates with PDE5 Inhibitors
1- Erectile dysfunction is a frequently
encountered problem whose risk factors parallel
those of coronary artery disease.
2- Thus many men desiring therapy for erectile
dysfunction already may be receiving (or may
require, especially if they increase physical
activity) anti-anginal therapy.
3- The combination of sildenafil and other
phosphodiesterase 5 (PDE5) inhibitors with
organic nitrate vasodilators can cause extreme
hypotension.

Therapeutic Uses
1- ANGINA
2- CONGESTIVE HEART FAILURE
3- UNSTABLE ANGINA PECTORIS AND
NON-ST-SEGMENTELEVATION MYOCARDIAL INFARCTION
Should include antiplatelets
4- ACUTE MYOCARDIAL INFARCTION
5- VARIANT (PRINZMETAL) ANGINA
6- Diffuse Esophageal Spasm
In a limited number of patients with diffuse
esophageal spasm without gastroesophageal
reflux, isosorbide dinitrate has been used
effectively to relieve pain, dysphagia, and spasm.

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Mechanism Vessels Affected Uses
Direct effect, conversion to NO, increase cGMP Venous Angina pectoris (coronary artery disease), CHF,
Direct effect, conversion to NO, increase cGMP Arteriolar and venous Hypertensive emergencies, acute CHF
Direct effect, partially EDRF-dependent formation of NO, increase cGMP possible K channel agonist inhibition of inositol triphosphate-induced Ca release Arteriolar Hypertension, CHF (with nitrate)
Drug
Nitroglycerin and nitrates
Sodium nitroprusside
Hydralazine
26

Hydralazine Hydralazine dilates arterioles but
not veins. Hydralazine may be used more
effectively, particularly in severe hypertension.
The combination of Hydralazine with nitrates
is effective in heart failure and should be
considered in patients with both hypertension and
heart failure, especially in African-American
patients
27

Hydralazine Hydralazine has been shown to prevent
tolerance toward organic nitrate This is due to
antioxidant properties hydralazine is a highly
potent radical scavenger. Thus, the
combination with isosorbide dinitrate (ISDN) will
favorably influence the nitroso-redox balance
in the cardiovascular system in patients with
congestive heart failure Thus explain at least
in part the improvement of prognosis in patients
with chronic congestive heart failure.
28

Adverse Effects Hydralazine
The most common adverse effects of hydralazine
are
In patients with ischemic heart disease, reflex
tachycardia and sympathetic stimulation may
provoke angina or ischemic arrhythmias.
dizziness, drowsiness, headache.
CV tachycardia, angina, arrhythmias, edema,
orthostatic hypotension.
sodium retention.
drug-induced lupus syndrome.
.

29

Minoxidil 1- Minoxidil is a very efficacious
orally active vasodilator. 2- The effect
results from the opening of potassium channels in
smooth muscle membranes by minoxidil sulfate, the
active metabolite. 3- Increased potassium
permeability stabilizes the membrane at its
resting potential and makes contraction less
likely. 4- Like hydralazine, minoxidil dilates
arterioles but not veins. Because of its greater
potential antihypertensive effect, minoxidil
should replace hydralazine when maximal doses of
the latter are not effective or in patients with
renal failure and severe hypertension, USE IN
PATIENTS who do not respond well to hydralazine.
30

Minoxidil ADVESRSE EFFECTS 1- Tachycardia,
palpitations, angina, and edema are observed when
doses of CARDIAC DEPRESSANTS blockers and
diuretics are inadequate. 2- Headache, sweating
WHY ? 3- Hypertrichosis (GROWTH OF HAIR), which
is particularly bothersome in women, are
relatively common. 4- Minoxidil illustrates how
one person's toxicity may become another person's
therapy. Topical minoxidil (as Rogaine) is used
as a stimulant to hair growth for correction of
baldness.
31

Sodium Nitroprusside 1- Sodium nitroprusside is a
powerful parenterally administered
vasodilator 2- It is used in treating
hypertensive emergencies as well as severe heart
failure. 3- Nitroprusside dilates both arterial
and venous vessels, resulting in reduced
peripheral vascular resistance and venous return.
4- The action occurs as a result of activation
of guanylyl cyclase, either via release of nitric
oxide or by direct stimulation of the enzyme.
5- The result is increased intracellular cGMP,
which relaxes vascular smooth muscle.
32

Sodium Nitroprusside 1- Nitroprusside is a
complex of iron, cyanide groups, and a nitroso
moiety. 2- It is rapidly metabolized by uptake
into red blood cells with liberation of
cyanide. 3- Cyanide in turn is metabolized by
the mitochondrial enzyme rhodanase, in the
presence of a sulfur donor, to the less toxic
thiocyanate. 4- Thiocyanate is distributed in
extracellular fluid and slowly eliminated by the
kidney.
33

Sodium Nitroprusside ADVERSE EFFECTS 1- the
most serious toxicity is related to accumulation
of cyanide 2- metabolic acidosis 3-
arrhythmias 4- excessive hypotension 2-.
Methemoglobinemia during infusion of
nitroprusside has also been reported.
34

Diazoxide 1- Diazoxide is an effective and
relatively long-acting parenterally administered
arteriolar dilator 2- Diminishing usage
suggests that it may be withdrawn. 3- Injection
of diazoxide results in a rapid fall in systemic
vascular resistance and mean arterial blood
pressure. 4- its mechanism suggest that it
prevents vascular smooth muscle contraction by
opening potassium channels and stabilizing the
membrane potential at the resting
level. Use Hypoglycemia related to islet cell
adenoma, carcinoma, hyperplasia, or adenomatosis
nesidioblastosis leucine sensitivity
extrapancreatic malignancy
35

Diazoxide ADVERSE EFFECTS 1- hypotension 2-
The reflex sympathetic response can provoke
angina 2- in patients with ischemic heart
disease, and diazoxide should be avoided in this
situation. 3- Diazoxide inhibits insulin
release from the pancreas (probably by opening
potassium channels in the beta cell membrane) and
is used to treat hypoglycemia secondary to
insulinoma
36

Fenoldopam 1- Fenoldopam is a peripheral
arteriolar dilator used for hypertensive
emergencies And postoperative hypertension with
renal compromised function. 2- Mechanism of
Action A selective postsynaptic dopamine agonist
(D1-receptors) which exerts hypotensive effects
by decreasing peripheral vasculature resistance
with increased renal blood flow leading to
diuresis, and natriuresis 3- It is 6 times as
potent as dopamine in producing renal
vasodilatation and has minimal adrenergic
effects 4- Fenoldopam is administered by
continuous intravenous infusion. 5-As with other
direct vasodilators, the major toxicities are
reflex tachycardia, headache, and flushing. 5-
Fenoldopam also increases intraocular pressure
and should be avoided in patients with
glaucoma.
37
Inhibitors of AngiotensinMechanism Sites
of Action1- Renin release from the kidney
cortex is stimulated bya- reduced renal
arterial pressureb- sympathetic neural
stimulationc- reduced sodium delivery d-
increased sodium concentration at the distal
renal tubule Renin acts upon angiotensinogen
to split off the inactive precursor decapeptide
angiotensin I. Angiotensin I is then
converted, primarily by endothelial ACE, to the
arterial vasoconstrictor octapeptide angiotensin
II

38
Inhibitors of AngiotensinMechanism Sites
of Action Angiotensin-ii is in turn converted
in the adrenal gland to angiotensin III.
Angiotensin II has vasoconstrictor and
sodium-retaining activity. Angiotensin II and
III both stimulate aldosterone release
Angiotensin may contribute to maintaining high
vascular resistance in hypertensive states
associated with high plasma renin activity,
renal arterial stenosis has high renin level-
- Angiotensin system also induce cardiac
hypertrophy

39

Inhibitors of Angiotensin Mechanism Sites
of Action

40

Inhibitors of Angiotensin Mechanism Sites
of Action

41
. The converting enzyme involved in tissue
angiotensin II synthesis is also inhibited by ACE
inhibitors.Three classes of drugs act
specifically on the renin-angiotensin
system1- ACE inhibitors2- the competitive
inhibitors of angiotensin at its receptors
(antagonist), including losartan 3- aliskiren,
an orally active renin antagonist 4-
aldosterone receptor inhibitors (eg,
spironolactone, eplerenone)

42
Angiotensin-Converting Enzyme (ACE)
Inhibitors1- Captopril - drugs in this class
inhibit the converting enzyme peptidyl
dipeptidase that hydrolyzes angiotensin I to
angiotensin II - (under the name plasma
kininase) inactivates bradykinin, a potent
vasodilator,which works by stimulating release
of nitric oxide and prostacyclin The
hypotensive activity of captopril results both
from an inhibitory action on the
renin-angiotensin system and a stimulating
action on the kallikrein-kinin system The
latter mechanism has been demonstrated by showing
that a bradykinin receptor antagonist blunts the
blood pressure-lowering effect of captopril2-
Enalapril is an oral prodrug that is converted by
hydrolysis to a converting enzyme inhibitor,
enalaprilat, with effects similar to those of
captopril. Enalaprilat itself is available only
for intravenous use, primarily for hypertensive
emergencies.

43
Angiotensin-Converting Enzyme (ACE)
Inhibitors3- Lisinopril is a lysine
derivative of enalaprilat.4- Benazepril,
fosinopril, moexipril, perindopril, quinapril,
ramipril, and trandolapril are other long-acting
members of the class. All are prodrugs, like
enalapril, and are converted to the active agents
by hydrolysis, primarily in the liver.5-
Angiotensin II inhibitors lower blood pressure
principally by decreasing peripheral vascular
resistance. Cardiac output and heart rate are not
significantly changed. 6- Unlike direct
vasodilators, these agents do not result in
reflex sympathetic activation and can be used
safely in persons with ischemic heart disease.
7- The absence of reflex tachycardia may be due
to downward resetting of the baroreceptors or
to enhanced parasympathetic activity.. .

44
Angiotensin-Converting
Enzyme (ACE) Inhibitors8- ACE inhibitors have
a particularly useful role in treating patients
with chronic kidney disease because they diminish
proteinuria and stabilize renal function (even in
the absence of lowering of blood pressure).9-
This effect is particularly valuable in diabetes,
and these drugs are now recommended in diabetes
even in the absence of hypertension. 10- These
benefits probably result from improved intrarenal
hemodynamics, with decreased glomerular efferent
arteriolar resistance and a resulting reduction
of intraglomerular capillary pressure.10 - ACE
inhibitors have also proved to be extremely
useful in the treatment of heart failure, and
after myocardial infarction, and there is recent
evidence that ACE inhibitors reduce the incidence
of diabetes in patients with high cardiovascular
risk .

45
Adverse effects of
angiotensin-Converting Enzyme (ACE)
Inhibitors1- Severe
hypotension can occur after initial doses of any
ACE inhibitor in patients who are hypovolemic as
a result of diuretics, salt restriction, or
gastrointestinal fluid loss.2- Other adverse
effects common to all ACE inhibitors include
acute renal failure (particularly in patients
with bilateral renal artery stenosis or stenosis
of the renal artery of a solitary kidney)3-
hyperkalemia Hyperkalemia is more likely to
occur in patients with renal insufficiency or
diabetes 4- dry cough sometimes accompanied by
wheezing5- Angioedema.. Bradykinin and
substance P seem to be responsible for the cough
and angioedema seen with ACE inhibition.6- ACE
inhibitors are contraindicated during the second
and third trimesters of pregnancy because of the
risk of fetal hypotension, anuria, and renal
failure, sometimes associated with fetal
malformations or death.

46
Adverse
effects of angiotensin-Converting Enzyme (ACE)

Inhibitors7- recent evidence also implicates
first-trimester exposure to ACE inhibitors in
increased teratogenic risk. 8- Captopril,
particularly when given in high doses to patients
with renal insufficiency, may cause neutropenia
or proteinuria.9- Minor toxic effects seen
more typically include altered sense of
taste10- allergic skin rashes, and drug fever,
which may occur in up to 10 of patients.11-
Important drug interactions include those with
potassium supplements or potassium-sparing
diuretics, which can result in hyperkalemia.
12- Nonsteroidal anti-inflammatory drugs may
impair the hypotensive effects of ACE inhibitors
by blocking bradykinin-mediated vasodilation,
which is at least in part, prostaglandin
mediated. .

47
Angiotensin II Receptor Antagonists

48
The AngII receptor blockers 1-
Candesartan2- olmesartan 3- irbesartan 4-
eprosartan5- telmisartan 6- valsartan (the
active metabolite of losartan) 7-
losartan.
Angiotensin II Receptor Antagonists

49

Angiotensin II Receptor Antagonists
The AngII receptor blockers bind to the AT1
receptor with high affinity and are more than
10,000-fold selective for the AT1 receptor over
the AT2 receptor. The rank-order affinity of
the AT1 receptor for ARBs is candesartan
olmesartan gt irbesartan
eprosartan gt telmisartan valsartan
(the active metabolite of losartan) gt losartan.

Do ARBs have therapeutic efficacy equivalent
to that of ACE inhibitors?
Although both classes of drugs block the RAS
they differ in several important aspects
ARBs reduce activation of AT1 receptors more
effectively than do ACE inhibitors.
ACE inhibitors reduce the biosynthesis of AngII
by the action of ACE, but do not inhibit
alternative non-ACE AngII-generating pathways.
ARBs block the actions of AngII via the AT1
receptor regardless of the biochemical pathway
leading to AngII formation.

Angiotensin II Receptor Antagonists
51

In contrast to ACE inhibitors, ARBs permit
activation of AT2 receptors.
Because ARBs block AT1 receptors, this increased
level of AngII is available to activate AT2
receptors.
ACE inhibitors increase the levels of a number of
ACE substrates, including bradykinin and Ac-SDKP.
Whether the pharmacological differences between
ARBs and ACE inhibitors result in significant
differences in therapeutic outcomes is an open
question.

Angiotensin II Receptor Antagonists
52

Angiotensin II Receptor Antagonists Candesartan
Cilexetil (Atacand) Candesartan cilexetil is an
inactive ester prodrug that is completely
hydrolyzed to the active form, candesartan, The
plasma clearance of candesartan is affected by
renal insufficiency but not by mild-to-moderate
hepatic insufficiency. Candesartan cilexetil
should be administered orally once or twice daily
for a total daily dose of 4- 32 mg. Eprosartan
(Teveten) . Clearance is by renal elimination and
biliary excretion. The plasma clearance of
eprosartan is affected by both renal
insufficiency and hepatic insufficiency. The
recommended dosage of eprosartan is 400-800
mg/day in one or two doses.
53

Irbesartan (Avapro) . cleared by renal
elimination (20) and biliary excretion (80).
The plasma clearance of irbesartan is unaffected
by either renal or mild-to-moderate hepatic
insufficiency. The oral dosage of irbesartan is
150-300 mg once daily.
54

. Losartan (Cozaar) Losartan is converted to
the 5-carboxylic acid metabolite EXP 3174, which
is more potent than losartan as an AT1 receptor
antagonist. The plasma clearances of losartan
and EXP 3174 are due to renal clearance and
hepatic clearance (metabolism and biliary
excretion). The plasma clearance of losartan
and EXP 3174 is affected by hepatic but not renal
insufficiency Losartan should be administered
orally once or twice daily for a total daily dose
of 25-100 mg. In addition to being an ARB,
losartan is a competitive antagonist of the
thromboxane A2 receptor and attenuates platelet
aggregation
55

. Olmesartan Medoxomil (Benicar)
Olmesartan medoxomil is an inactive ester prodrug
that is completely hydrolyzed to the active form,
olmesartan
Plasma clearance of olmesartan is due to both
renal elimination and biliary excretion.
Although renal impairment and hepatic disease
decrease the plasma clearance of olmesartan
no dose adjustment is required in patients with
mild-to-moderate renal or hepatic impairment.
The oral dosage of olmesartan medoxomil is 20-40
mg once daily.

Telmisartan (Micardis)
Telmisartan is cleared from the circulation
mainly by biliary secretion of intact drug.
The plasma clearance of telmisartan is affected
by hepatic
but not renal insufficiency.
The recommended oral dosage of telmisartan is
40-80 mg once daily.

57

Valsartan (Diovan) Valsartan is cleared from the
circulation by the liver (70 of total
clearance). The plasma clearance of valsartan
is affected by hepatic but not renal
insufficiency. The oral dosage of valsartan is
80-320 mg once daily. .
58

Therapeutic Uses of AngII Receptor
Antagonists 1- All ARBs are approved for the
treatment of hypertension. 2- In addition,
irbesartan and losartan are approved for diabetic
nephropathy 3- losartan is approved for stroke
prophylaxis 4- and valsartan is approved for
heart failure and to reduce cardiovascular
mortality in clinically stable patients with left
ventricular failure or left ventricular
dysfunction following myocardial infarction. 5-
The efficacy of ARBs in lowering blood pressure
is comparable with that of ACE inhibitors and
other established antihypertensive drugs, with a
favorable adverse-effect profile..
59

Current recommendations are to use ACE inhibitors
as first-line agents for the treatment of heart
failure and to reserve ARBs for treatment of
heart failure in patients who cannot tolerate or
have an unsatisfactory response to ACE
inhibitors. ARBs are renoprotective in type 2
diabetes mellitus, in part via blood
pressureindependent mechanisms Based on these
results, many experts now consider them the drugs
of choice for renoprotection in diabetic
patients. Losartan is superiority of an ARB
compared with alpha 1 adrenergic receptor
antagonist with regard to reducing stroke in
hypertensive patients with left ventricular
hypertrophy). irebesartan appears to maintain
sinus rhythm in patients with persistent,
long-standing atrial fibrillation. Losartan is
reported to be safe and highly effective in the
treatment of portal hypertension in patients
withcirrhosis and portal hypertension without
compromising renal function...
60

Adverse Effects of ARBs 1- The incidence of
angioedema and cough with ARBs is less than that
with ACE inhibitors. 2- ARBs have teratogenic
potential and should be discontinued in
pregnancy. 3- In patients whose arterial blood
pressure or renal function is highly dependent on
the RAS (e.g., renal artery stenosis), ARBs can
cause hypotension, oliguria, progressive
azotemia, or acute renal failure. 4- ARBs may
cause hyperkalemia in patients with renal disease
or in patients taking K supplements or
K-sparing diuretics. 5- There are rare
postmarketing reports of anaphylaxis, abnormal
hepatic function, hepatitis, neutropenia,
leukopenia, agranulocytosis, pruritus, urticaria,
hyponatremia, alopecia, and vasculitis, including
Henoch-Schönlein purpura. .
61

Direct Renin Inhibitors DRIs are a novel class
of antihypertensive drugs that inhibit the RAS at
its origin. Angiotensinogen is the only
specific substrate for renin, and its conversion
to AngI presents a rate-limiting step for the
generation of downstream components of the
RAS. Aliskiren (TEKTURNA) is the only DRI
approved for clinical use. Aliskiren, a
second-generation renin inhibitor that was
approved by the U.S. FDA in 2007 for the
treatment of hypertension. Aliskiren has blood
pressurelowering effects similar to those of ACE
inhibitors and ARBs. .
62

Direct Renin Inhibitors .
63

Aliskiren Aliskiren is a potent competitive
inhibitor of renin. It binds the active site of
renin to block conversion of angiotensinogen to
AngI, thus reducing the consequent production
of AngII. In healthy volunteers, aliskiren
(40-640 mg/day) induces a dose-dependent decrease
in blood pressure, aliskiren is similar to the
high dose of valsartan in lowering blood
pressure, reducing albuminuria, normalizing serum
creatinine, and protecting against end-organ
damage
64

Therapeutic Uses of Aliskiren 1- Aliskiren is an
effective antihypertensive agent that is well
tolerated in monotherapy and combination therapy.
2- It has cardioprotective and renoprotective
effects in combination therapy 3- Aliskiren is
recommended in patients who are intolerant to
other antihypertensive therapies or for use in
combination with other drugs for further blood
pressure control. .
65

Adverse Aliskiren 1- hyperkalemia in diabetics
on combination therapy, 2- Angioedem. 3-
Like other RAS inhibitors, aliskiren is not
recommended in pregnancy. . .
66
CA2 CHANNEL ANTAGONISTS
DRUGS VASODILATION (CORONARY FLOW) SUPPRESSION OF CARDIAC CONTRACTILITY SUPPRESSION OF AUTOMATICITY (SA NODE) SUPPRESSION OF CONDUCTION (AV NODE)
Amlodipine 5 1 1 0
felodipine 5 1 1 0
Isradipine NR NR NR NR
Nicardipine 5 0 1 0
Nifedipine Clevidipine (I.V. Only) 5 1 1 0
Diltiazem 3 2 5 4
Verapamil 4 4 5 5
67

DRUGS USED IN DIASTOLIC HEART FAILURE 1- BETA
BLOCKER 2- CALCIUM CHANNEL BLOCKER 3- ACE
INHIBITORS OR ARB 4- Ranolazine a novel anti
anginal drug known to inhibit late sodium current
(INaL) Ranolazine Prevents Heart Failure with
Preserved Ejection Fractionuggested that
Ranolazine (RAN), a novel anti anginal drug known
to inhibit late sodium current (INaL) may improve
diastolic dysfunction (DD) caused by HTN induced
oxidative stress. By improving diastolic
dysfunction RAN can improve Heart Failure
with Preserved Ejection Fraction (HFPEF).
Methods A mouse model
68

DRUGS USED IN HEART FAILURE
Class Group Commonly Used Agent(s)
Diuretics Thiazide diuretics HCTZ
Loop diuretics Furosemide
Potassium sparing diuretics Spironolactone
Cardiac glycosides Digitalis preparations Digoxin
Inotropic drugs Dobutamine
Vasoactive drugs Vasodilators Hydralazine
Isosorbide
ACE inhibitors Enalapril
Captopril
Angiotensin II receptor blockers
Losartan
Angiotensin II receptor blockers
69

DRUGS USED IN HEART FAILURE
Class Group Commonly Used Agent(s)

-Blockers Metoprolol CR/XL
Carvedilol
Antiarrhythmic drugs Amiodarone
Dofetilide
Aldosterone receptor antagonists Spironolactone
Eplerenone
Natriuretic peptides Nesiritide
Vasopressin receptor antagonists Tolvaptan
70
Autacoids
71

TOPICS WILL BE COVERED
1- Pharmacology of Histamine and its analogues
2- Pharmacology of Antihistamines(H1 H2) mast
cell sabilizers
3- Pharmacology of The Eicosanoids Products of
Cyclooxygenases
- Prostaglandins, Thromboxanes, Related
Compounds
- Analogues of Cyclooxygenases Products
and their inhibitors
Second Assessment Test
4- Autacoids Pharmacology of The
EicosanoidsLipoxygenase products and their
blockers
5- Pharmacology of Serotonin, agonists and
antagonists the Ergot AlkaloidsAutacoids
6- Pharmacology of Nitric oxide and Vasoactive
Peptides and their blockers such as endothelins,
angiotensin, neurotensin, substance P.

72
AUTACOIDS

Introduction
Means self remedy
Naturally occurring substances
Localized in tissues
Do not normally circulate
Diverse physiological and pharmacological
activities
Differ from hormones and neurotransmitters
Short duration of action
Usually involved in a response to injury
Sites of action restricted to the synthesis area

73
CLASSIFICATION
1. Biogenic amines Histamine,
5-hydroxytryptamine 2. Biogenic Peptides
Angiotensin and kinins 3. Small Proteins
cytokineins 4. Membrane derived lipids LTs,
PGs, TxA2 PAF 5. Endothelium-derived agentsNO
(gas) ET (peptide)
74
Histamine

1- Synthesis
2- Histamine Storage
- mast cell
3- DISTRIBUTION OF HISTAMINE
4- Metabolism Histamine
The more important of these involves ring
methylation to form N-methylhistamine
It increases mastocytosis

Release Histamine
unexpected anaphylactoid reactions
As a result of the interaction of antigen with
immunoglobulin E (IgE) antibodies on the mast
cell surface
Histamine Release by Drugs, Peptides, Venoms, and
Other Agents.
These drugs stimulate the release of histamine
from mast cells directly and without prior
sensitization.

76
Examples of Agents Release Histamine 1-amides,
amidines, quaternary ammonium compounds,
pyridinium compounds, piperidines, and
alkaloids (Tubocurarine, succinylcholine,
morphine 2- radiocontrast media 3- certain
carbohydrate plasma expanders also may elicit the
response.
77
Release Histamine 4- some antibiotics,
Vancomycin-induced "red-man syndrome" involving
upper body and facial flushing and hypotension
may be mediated through histamine release.
Beta-lactam antibiotics such amoxil as well as
cephalosporin Polymyxin B is also very active.
5- food
78
PHARMACOLOGY OF HISTAMINE
79
Histamine receptors 1- H1 receptor - Smooth
muscle - brain 2- H2 receptor - Gastric
mucosa 3- H3 receptor - Presynaptic brain,
myenteric plexus 4- H4 receptor -
Eosinophils, neutrophils, CD4 T cells
80

1- Central Nervous System
Histamine increases wakefulness via H1
receptors
explaining the potential for sedation by
classical antihistamines
Histamine is a powerful stimulant of sensory
nerve endings, especially those mediating pain
and itching via H1

Gastric Acid Secretion
Acting at H2 receptors, histamine is a powerful
gastric secretagogue
and evokes a copious secretion of acid from
parietal CELL
it also increases the output of pepsin and
intrinsic factor.

IMMUNE SYSTEM
H4 receptors are on immune active cells such as
eosinophils and neutrophils
Activation of H4 receptors on eosinophils
induces
- H4 antagonists may be useful inhibitors of
allergic and inflammatory responses

83
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84

IMMUNE SYSTEM
- suggesting that the histamine released from
mast cells acts at H4 receptors to recruit
eosinophils.
- H4 antagonists may be useful inhibitors of
allergic and inflammatory responses

Histamine-induces Vasodilation
Vasodilation involves both H1 and H2 receptors
distributed throughout the resistance vessels in
most vascular beds
1- Activation H1 receptors
Medaites its action via endothelium-NO-depen
dent dilation that is relatively rapid in onset
and short-lived.
Increase calcium which lead to release Nitric
oxide
.

Histamine-induces Vasodilation
2- activation of H2 receptors
H2 receptors couple via GS to the activation of
adenylyl cyclase
- (stimulating the cyclic AMP-PKA pathway in
smooth muscle)
- causes dilation that develops more slowly
and is more sustained

Histamine-induces Vasodilation

Increased "Capillary" Permeability
Causes edema formation.
H1 receptors on endothelial cells are the major
mediators of this response
Role of H2 receptors is uncertain.

Triple Response of Lewis
it elicits a characteristic phenomenon known as
the triple response (Lewis, 1927).
(1) a localized red spot
The initial red spot results
from the direct vasodilating effect of histamine
(H1-receptor-mediated NO production)
extending for a few millimeters around the site
of injection
that appears within a few seconds
and reaches a maximum in about a minute

Triple Response of Lewis
2) a brighter red flush, or "flare,"
the flare is due to histamine-induced stimulation
of axon reflexes
that cause vasodilation indirectly
- extending about 1 cm or so beyond the
original red spot
- and developing more slowly

Triple Response of Lewis
(3) a wheal that is discernible in 1 to 2 minutes
- and occupies the same area as the
original small red spot at the injection site.
- the wheal reflects histamine's capacity to
increase capillary permeability (edema formation).

CLINICAL USES OF HISTAMINE
HISTAMINE ANALOQUE
BetaSERC 16 tabletsCOMPOSITION
Each tablet contains betahistine dihydrochloride
16 mg.

CLINICAL USES OF HISTAMINE
SERC 16 tabletsPHARMACOLOGICAL
ACTIONBetahistine The mechanism of action
Pharmacological testing in animals has shown
that
- the blood circulation in the striae vascularis
of the inner ear improves
- probably by means of a relaxation of the
precapillary sphincters of the microcirculation
of the inner ear.

CLINICAL USES OF HISTAMINE
SERC 16 tabletsIn pharmacological studies,
betahistine was found to have weak H1 receptor
agonistic
- and considerable H3 antagonistic properties in
the CNS and autonomic nervous system.
- Betahistine was also found to have a dose
dependent inhibiting effect on spike generation
of neurons in lateral and medial vestibular
nuclei.
The importance of this observation in the action
against Ménières syndrome or vestibular vertigo,
however, remains unclear.

CLINICAL USES OF HISTAMINE
SERC 16 tabletsINDICATIONSSymptomatic
treatment of the vertigo associated with
Ménières Syndrome.CONTRA-INDICATIONS-
Patients with active peptic ulcer.- Patients
with phaeochromocytoma.DOSAGE AND DIRECTIONS
FOR USEAdult dosageThe usual initial dose is 8
to 16 mg three times daily to be taken preferably
with meals. Maintenance doses of up to 48 mg
daily have been recommended.

CLINICAL USES OF HISTAMINE
SERC 16 tabletsSIDE-EFFECTS AND SPECIAL
PRECAUTIONSGastro-intestinal disturbances,
headache and skin rashes have been reported.
Special precautionsCaution should be exercised
when betahistine dihydrochloride is given to
patients with a history of peptic ulcer or
asthmatic patients.Concomitant use with
antihistamines should be avoided.

97
ANTIHISTAMINESH1-RECEPTOR
BLOCKERS

FIRST GENERATION ANTIHISTAMINES (H1
BLOCKERS)SEDATING
1- Ethanolamines
- Carbinoxamine maleate
- Clemastine fumarate
- Diphenhydramine HCl
- Dimenhydrinate (DIZINIL)-ANTI-MOTION
SICKNESS)
2- Ethylenediamines
- Pyrilamine maleate
- Tripelennamine HCl
- Tripelennamine citrate

3- Alkylamines
- Chlorpheniramine maleate
- Brompheniramine maleate
4- Piperazines
- Hydroxyzine HCl
- Hydroxyzine pamoate
- Cyclizine HCl
- Cyclizine lactate
- Meclizine HCl

100

5- Phenothiazines
- Promethazine HCl
6- Piperidines
- Cyproheptadine HCl(periactin)
- Phenindamine tartrate
7-OTHERS
- ketotifen and olopatadine
- effective in allergic conjunctivitis and
rhinitis. Nasal sprays or topical ophthalmic
preparations

101

Second-Generation H1 blockers
(non-sedating H1 blockers)
1- Alkylamines
- Acrivastine
2- Piperazines
- Cetirizine hydrochloride(ZYRTEC)
3- Phthalazinones
- Azelastine hydrochloride

102

4- Piperidines
- Levocabastine hydrochloride
- Loratadine
- Desloratadine
- Ebastine
- Mizolastine
- Fexofenadine

103

PHARMACOLOGY OF ANT-IHISTAMINES(H1)
1- Competitive antagonism for the same receptor
2- do not prevent histamine release
3- do not cause physiological antagonism (smooth
muscle dilatation)
- NOT SUITABLE FOR ACUTE BRONCHIAL ASTHMA
Do not block gastric acid production
(blocked by H2)

104

PHARMACOLOGY OF ANTI-HISTAMINES(H1)
4- Protect against shock and allergic reactions
5- CNS depression, a side effect first generation
WHILE SECOND GENERATION DO NOT)
6- ANTICHOLINERGIC ACTIVITY (mainly sedating
H1-blockers)
the principle of antimotion sickness
- dimenhydrinate

105

PHARMACOLOGY OF ANTI-HISTAMINES(H1)
6- Local anesthetic effect suh as promethazine
7- Adrenoceptor-blocking actions such as
promethazine
8- Serotonin-blocking action such as
cyproheptadine

106
Therapeutic uses of H1 BLOCKERS 1-allergic
reactions such as hay fever 2- motion sickness,
verigo 3- NAUSEA AND VOMITING OF PREGNANCY 4-
sedation 5-common cold

107
Common Adverse Effects of H1 blockers 1- The
most frequent side effect in the first-generation
H1 antagonists is sedation. - Concurrent
ingestion of alcohol or other CNS depressants
produces an additive effect that impairs motor
skills. 2- dizziness, tinnitus, lassitude,
incoordination, fatigue 3- blurred vision,
diplopia (due to atropine like action) 4-
Tachycardia

108
Common Adverse Effects 5- some H1 antagonists
increase appetite such as cyproheptadine
due to serotonin blocking activity 6-
antimuscarinic actions of some of the
first-generation H1-receptor antagonists
include - dryness of the mouth and
respiratory passages (sometimes inducing cough)
- urinary retention or frequency, and dysuria.
These effects are not observed with
second-generation H1 antagonists

109
Common Adverse Effects OF SECOND GENERATION
H1-BLOCKERS 1- Lethal ventricular arrhythmias
in early second-generation agents 1- terfenadine
2- or astemizole

110
Common Adverse Effects OF SECOND GENERATION
H1-BLOCKERS 3- The mechanism of this toxicity
involves blockade of potassium channels in the
heart 4- The result is prolongation of the
action potential 5- excessive prolongation leads
to arrhythmias. 6- Both terfenadine and
astemizole were withdrawn from the United States
market in recognition of these problems.

111
H1 blockers-Drug Interactions- Drugs inhibit
CYP3A4 such as - ketoconazole -
itraconazole - macrolide antibiotics such
as erythromycin OR CLARITHROMYCIN. These
antimicrobial drugs cause significant increases
in blood concentrations of the antihistamines(SECO
ND GENERATION).

112

H1 blockers-Drug Interactions
7- Terfenadine and astemizole should be
considered to be contraindicated in patients
taking
- ketoconazole
- itraconazole
- macrolides
- and in patients with liver disease.
8- Grapefruit juice also inhibits CYP3A4 and has
been shown to increase terfenadine's blood levels
significantly as well as other drugs.

113

MAST CELL STABILIZERS
Mechanism of Actioninhibits mast cell
degranulation
CROMOLYN NEDOCROMIL
Cromolyn sodium (disodium cromoglycate) and
nedocromil sodium)
they effectively inhibit both antigen- and
exercise-induced asthma,

114

CROMOLYN NEDOCROMIL have no effect on
1- airway smooth muscle tone
2- and are ineffective in reversing asthmatic
bronchospasm
3-they are only of value when taken
prophylactically

115

CLINICAL USE OF CROMOLYN NEDOCROMIL1-allergen
inhalation,
by sulfur dioxide
and by a variety of causes of occupational
asthma.
2- Cromolyn solution is also useful in reducing
symptoms of allergic rhinoconjunctivitis.(EYE
DROP)

116

ADVERSE EFFECTS
Because the drugs are so poorly absorbed,
adverse effects of cromolyn and nedocromil are
minor and are localized to the sites of
deposition.
These include such minor symptoms as
throat irritation,
cough,
mouth dryness,

117
H2 Antagonists

Effect Block all phases of gastric acid
secretion due to histamine.
proton pump inhibitors (NEXIUM OR LOSEC,
OMEPRAZOLE) are steadily replacing H2 antagonists
for most clinical indications.

118
H2 Antagonists

1- Cimetidine
2- Ranitidine
3- Nizatidine
4- Famotidine

119

CLINICAL USES OF H2 ANATGONIST
1- GASTROESOPHAGEAL REFLUX DISEASE (GERD)
2- PEPTIC ULCER DISEASE ranitidine, 150 mg
famotidine, 20 mg
3- PREVENTION OF BLEEDING FROM STRESS-RELATED
GASTRITIS

120

ADVERSE EFFECTS OF H2 ANATGONIST
1- CENTRAL NERVOUS SYSTEM
- confusion, hallucinations, agitation)
If given I.V.
These events may be more common with
cimetidine.
- rarely occur in ambulatory patients.

121

ADVERSE EFFECTS OF H2 ANATGONIST
2- ENDOCRINE EFFECTS
- Cimetidine inhibits binding of
dihydrotestosterone to androgen receptors
- inhibits metabolism of estradiol
- and increases serum prolactin levels.
When used long-term or in high doses
- it may cause gynecomastia
- impotence in men and galactorrhea in women.
These effects are specific to cimetidine and do
not occur with the other H2 antagonists.

122

ADVERSE EFFECTS OF H2 ANATGONIST
3- Increases liver enzymes BUT reversible

123

H2 blockers-Drug Interactions
1- Cimetidine interferes with several important
hepatic cytochrome P450 drug metabolism pathways,
- including those catalyzed by CYP1A2,
CYP2C9, CYP2D6, and CYP3A4
- Half-lives of drugs metabolized by these
pathways may be prolonged.

124
SEROTONIN (5-HT)

1- It formed from L-tryptophan
2- In the pineal gland, serotonin serves as a
precursor of melatonin, a melanocyte-stimulating
hormone.
3- over 90 of the serotonin in the body is found
in enterochromaffin cells in the gastrointestinal
tract.

125
Physiological role of SEROTONIN (5-HT)

1- Brain serotonergic neurons are involved in
numerous diffuse functions such as
- mood
- sleep
- appetite
- temperature regulation

126
Physiological role of SEROTONIN (5-HT)

2- the perception of pain
3- the regulation of blood pressure, and vomiting
4- Serotonin also appears to be involved in
clinical conditions such as depression, anxiety,
and migraine(blood vessels).
5- Serotonergic neurons are also found in the
enteric nervous system of the gastrointestinal
tract and around carcinoid tumor.

127

PHARMACOLOGY
OF
SEROTONIN (5-HT)

128

1- Cardiovascular system
5-HT2
- Serotonin directly causes the contraction of
vascular smooth muscle, mainly through 5-HT2
receptors.
- In humans, serotonin is a powerful
vasoconstrictor
(AGONIST MAY PRECIPITATE ANGINA AND HEART ATTACK
)
- Serotonin can also elicit reflex bradycardia
by activation of 5-HT3 receptors on chemoreceptor
nerve endings.

129

Cardiovascular system
- Serotonin also constricts veins
venoconstriction with a resulting increased
capillary filling appears to be responsible for
the flush that is observed following release from
a carcinoid tumor.

130

2- Gastrointestinal tract
5-HT2
Serotonin is a powerful stimulant of
gastrointestinal smooth muscle
increasing tone and facilitating peristalsis.
This action is caused by the direct action of
serotonin on 5-HT2 smooth muscle receptors
5-HT4
Activation of 5-HT4 receptors in the enteric
nervous system causes increased acetylcholine
release
increase motility or "prokinetic" effect of
partial serotonin agonists such as Tegaserod
Overproduction of serotonin in carcinoid tumor
is associated with severe diarrhea.

131

2- Gastrointestinal tract
Zelnorm
(tegaserod maleate)
INDICATIONS AND USAGE
IBS with Constipation
Zelnorm (tegaserod maleate) is indicated for the
short-term treatment of women with irritable
bowel
syndrome (IBS) whose primary bowel symptom is
constipation.
lished.
Chronic Idiopathic Constipation
Zelnorm (tegaserod maleate) is indicated for the
treatment of patients less than 65 years of age
with
chronic idiopathic constipation.

132

2- Gastrointestinal tract
Zelnorm
(tegaserod maleate)
Post Marketing Experience
Voluntary reports of adverse events occurring
with the use of Zelnorm include the following
ischemic
Colitis
1- mesenteric ischemia, gangrenous bowel,
2- electrolyte disorders
3- suspected sphincter of Oddi spasm, bile duct
stone,
cholecystitis with elevated transaminases,

133

5-HT1D/1B Agonists Migraine HeadacheThe
5-HT1D/1B agonists (triptans) are used almost
exclusively in migraine headache.
Migraine in its "classic" form is characterized
by an aura of variable duration
that may involve nausea, vomiting, and visual
scotomas
or even hemianopsia and speech abnormalities
followed by a severe throbbing unilateral
headache that lasts for a few hours to 1-2 days
. "Common" migraine lacks the aura phase, but the
headache is similar. Although the symptom pattern
varies among patients,
the severity of migraine headache justifies
vigorous therapy in the great majority of cases.

134

5-HT1D/1B Agonists
Almotriptan
Eletriptan
Frovatriptan
Naratriptan
Rizatriptan
Sumatriptan
Zolmitriptan

135

The efficacy of triptan 5-HT1 agonists in
migraine is equal to or greater than that of
other acute drug treatments, eg, parenteral,
oral, or rectal ergot alkaloids.
Most adverse effects are mild and include
altered sensations (tingling, warmth, etc),
dizziness, muscle weakness, neck pain,
for parenteral sumatriptan

136

chest pain has been reported,
probably because of the ability of these drugs to
cause coronary vasospasm.
They are therefore contraindicated in patients
with coronary artery disease and in patients with
angina.
Another disadvantage is the fact that their
duration of effect (especially that of
almotriptan, sumatriptan, rizatriptan, and
zolmitriptan is often shorter than the duration
of the headache.

137

zolmitriptan
Contraindications
Known or suspected ischemic heart disease (e.g.,
angina pectoris, myocardial infarction, silent
ischemia)
coronary vasospasm (e.g., Prinzmetal variant
anginaother serious underlying cardiovascular
disease (e.g., uncontrolled hypertension),
or cerebrovascular syndromes (e.g., stroke
syndromes, transient ischemic attacks).
Treatment within the previous 24 hours with
another 5-HT1 receptor agonist or with an ergot
alkaloid (e.g., ergotamine, dihydroergotamine,
methysergide).
Concurrent or recent (within 2 weeks) treatment
with a monoamine oxidase-A (MAO-A)(stop here)

138

As a result, several doses may be required during
a prolonged migraine attack, but their adverse
effects limit the maximum safe daily dosage.
Naratriptan and eletriptan are contraindicated in
patients with severe hepatic or renal impairment
or peripheral vascular syndromes
frovatriptan is contraindicated in patients with
peripheral vascular disease
zolmitriptan is contraindicated in patients with
Wolff-Parkinson-White syndrome

139

SEROTONIN-RECEPTOR
ANTAGONISTS
1- Cyproheptadine
- 5-HT2-blocker (STIMULATE
APPETITE CARCINOID SYNDROME)
- H1-receptor-blocker
- causes sedation
- antimuscarinic effects
- use in carcinoid tumor in GIT
- serotonin syndrome

140

5-HT3 ANTAGONISTS
1- Selective 5-HT3-receptor antagonists have
potent antiemetic
2- mediated mainly through central
5-HT3-receptor blockade in the vomiting center
and chemoreceptor trigger zone
3- blockade of peripheral 5-HT3 receptors
on extrinsic intestinal vagal and spinal afferent
nerves.
4- The antiemetic action of these agents is
restricted to emesis attributable to vagal
stimulation (eg, postoperative) and chemotherapy

141

5-HT3 ANTAGONISTS
1- ondansetron
2- granisetron
3- dolasetron (prolong QT interval)
These three drug used once daily by oral or
intravenous routes. .
4- palonosetron.
It is a newer intravenous agent that has greater
affinity for the 5-HT3 receptor and a long serum
half-life of 40 hours.
- All of them do not inhibit dopamine or
muscarinic receptors
- They do not have effects on esophageal or
gastric motility

142

Therapeutic uses 5-HT3 ANTAGONISTS
1- CHEMOTHERAPY-INDUCED NAUSEA AND VOMITING
5-HT3-receptor antagonists prevent of acute
chemotherapy-induced nausea and emesis
The drugs are most effective when given as a
single dose by intravenous injection 30 minutes
prior to administration of chemotherapy
Or oral dose given 1 hour before chemotherapy
When used alone, these drugs have little or no
efficacy for the prevention of delayed nausea and
vomiting (ie, occurring gt 24 hours after
chemotherapy
the efficacy is enhanced by combination therapy
with a corticosteroid (dexamethasone) and
Neurokinin-1 receptor antagonist (Aprepitant ).
2- POSTOPERATIVE AND POSTRADIATION NAUSEA AND
VOMITING