Anti-Angina Agents PDF

Summary

This document provides an overview of anti-angina agents, exploring different types of angina, their causes, and treatment strategies. It discusses the mechanisms of action, alongside potential side effects and adverse reactions.

Full Transcript

Pharmacology 4th year Anti-angina agent

Anti-Angina agents
OVERVIEW
Atherosclerotic disease of the coronary arteries, also known as coronary artery disease
(CAD) or ischemic heart disease (IHD), is the most common cause of mortality worldwide.
Atherosclerotic lesions in coronary arteries can obstruct blood flow, leading to an imbalance in
myocardial oxygen supply and demand that presents as stable angina or an acute coronary
syndrome (myocardial infarction [MI] or unstable angina). Spasms of vascular smooth muscle
may also impede cardiac blood flow, reducing perfusion and causing ischemia and angina pain.
Typical angina pectoris is a characteristic sudden, severe, crushing chest pain that may radiate to
the neck, jaw, back, and arms. All patients with IHD and angina should receive guideline-
directed medical therapy with emphasis on lifestyle modifications (smoking cessation, physical
activity, weight management) and management of modifiable risk factors (hypertension,
diabetes, dyslipidemia) to reduce cardiovascular morbidity and mortality.
TYPES OF ANGINA
Angina pectoris has three patterns:
1) stable, effort-induced, classic, or
typical angina;
2) unstable angina; and
3) Prinzmetal, variant, vasospastic,or rest angina.
They are caused by varying combinations of increased myocardial oxygen demand and
decreased myocardial perfusion.
A. Stable angina, effort-induced angina, classic or typical angina
Classic or typical angina pectoris is the most common form of angina. It is usually
characterized by a short-lasting burning, heavy, or squeezing feeling in the chest. Some ischemic
episodes may present "atypically"-with extreme fatigue, nausea, or diaphoresis-while others may
not be associated with any symptoms (silent angina). Atypical presentations are more common in
women, diabetic patients, and the elderly.Classic angina is caused by the reduction of coronary
perfusion due to a fixed obstruction of a coronary artery produced by atherosclerosis.Increased
myocardial oxygen demand, such as that produced by physical activity, emotional stress or
excitement, or any other causeof increased cardiac workload may induce ischemia. Typical
angina pectoris is promptly relieved by rest or nitroglycerin. When the pattern of chest pain and
the amount of effort needed to trigger the chest pain does not vary over time, the angina is
named "stable angina:
 Pharmacology 4th year Anti-angina agent

B. Unstable angina
Unstable angina is chest pain that occurs with increased frequency, duration, and intensity
and can be precipitated by progressively less effort. Any episode of rest angina longer than 20
minutes, any new onset angina, any increasing (crescendo} angina, or even sudden development
of shortness of breath is suggestive of unstable angina.The symptoms are not relieved by rest or
nitroglycerin. Unstable angina is a form of acute coronary syndrome and requires hospital
admission and more aggressive therapy to prevent progression to Ml and death.
C. Prinzmetal, variant, vasospastic, or rest angina
Prinzmetal angina is an uncommon pattern of episodic angina that occurs at rest and is due
to decreased blood flow to the heart muscle caused by spasm of the coronary arteries. Although
individuals with this form of angina may have significant coronary atherosclerosis, the angina
attacks are unrelated to physical activity, heart rate, or blood pressure. Prinzmetal angina
generally responds promptly to coronary vasodilators, such as nitroglycerin and calcium channel
blockers.
D. Acute coronary syndrome
Acute coronary syndrome is an emergency that commonly results from rupture of an
atherosclerotic plaque and partial or complete thrombosis of a coronary artery. If the thrombus
occludes most of the blood vessel, and, if the occlusion is untreated, necrosis of the cardiac
muscle may ensue. Ml (necrosis} is typified by increases in the serum levels of biomarkers such
as troponins and creatine kinase. The acute coronary syndrome may present as ST-segment
elevation myocardial infarction, non-ST-segment elevation myocardial infarction, or as unstable
angina. [Note: In unstable angina, increases in biomarkers of myocardial necrosis are not
present.].

TREATMENT STRATEGIES
Four types of drugs, used either alone or in combination, are commonly used to manage
patients with stable angina: ~-blockers, calcium channel blockers, organic nitrates, and the
sodium channel-blocking drug, ranolazine. These agents help to balance the cardiac oxygen
supply and demand equation by affecting blood pressure, venous return, heart rate, and
contractility.
1. ADRENERGIC BLOCKERS
The B-adrenergic blockers decrease the oxygen demands of the myocardium by blocking
B1 receptors, resulting in decreased heart rate,contractility, cardiac output, and blood pressure.
These agents reduce myocardial oxygen demand during exertion and at rest. As such, they can
reduce both the frequency and severity of angina attacks. B-Blockers can be used to increase
 Pharmacology 4th year Anti-angina agent

exercise duration and tolerance in patients with effort-induced angina. B-Blockers are
recommended as initial anti-anginal therapy in all patients unless contraindicated. [Note: The
exception to this rule is vasospastic angina, in which p-blockers are ineffective and may actually
worsen symptoms.]
-Blockers reduce the risk of death and Ml in patients who have had a prior Ml and also
improve mortality in patients with heart failure with reduced ejection fraction. Agents with
intrinsic sympathomimetic activity (ISA) such as pindolol should be avoided in patients with
angina and those with a history of MI.
Propranolol is the prototype for this class of compounds, but it is not cardioselective. Thus,
other B-blockers, such as metoprolol and atenolol, are preferred. [Note: All p-blockers are
nonselective at high doses and can inhibit P2 receptors.] p-Biockers should be avoided in
patients with severe bradycardia; however, they can be used in patients with diabetes, peripheral
vascular disease, and chronic obstructive pulmonary disease, as long as they are monitored
closely. Nonselective B-blockers should be avoided in patients with asthma. [Note: It is
important not to discontinue blocker therapy abruptly. The dose should be gradually tapered off
over 2 to 3 weeks to avoid rebound angina, Ml, and hypertension.]
2. CALCIUM CHANNEL BLOCKERS
Calcium is essential for muscular contraction. Calcium influx is increased in ischemia
because of the membrane depolarization that hypoxia produces. In turn, this promotes the
activity of several ATP-consuming enzymes, thereby depleting energy stores and worsening the
ischemia. The calcium channel blockers protect the tissue by inhibiting the entrance of calcium
into cardiac and smooth muscle cells of the coronary and systemic arterial beds. All calcium
channel blockers are, therefore, arteriolar vasodilators that cause a decrease in smooth muscle
tone and vascular resistance. These agents primarily affect the resistance of peripheral and
coronary arteriolar smooth muscle. In the treatment of effort-induced
angina, calcium channel blockers reduce myocardial oxygen consumption by decreasing
vascular resistance, thereby decreasing afterload. Their efficacy in vasospastic angina is due to
relaxation of the coronary arteries. [Note: Verapamil mainly affects the myocardium, whereas
amlodipine exerts a greater effect on smooth muscle in the peripheral vasculature. Diltiazem is
intermediate in its actions.] All calcium channel blockers lower blood pressure.
A. Dihydropyridine calcium channel blockers
Amlodipine is an oral dihydropyridine, has minimal effect on cardiac conduction and
functions mainly as an arteriolar vasodilator. The vasodilatory effect of amlodipine is useful in
the treatment of variant angina caused by spontaneous coronary spasm. Nifedipine is another
agent in this class; it is usually administered as an extended-release oral formulation. [Note:
 Pharmacology 4th year Anti-angina agent

Shortacting dihydropyridines should be avoided in CAD because of evidence of increased
mortality after an Ml and an increase in acute Ml in hypertensive patients.]
B. Non-dihydropyridine calcium channel blockers
Verapamil slows atrioventricular (AV) conduction directly and decreases heart rate,
contractility, blood pressure, and oxygen demand. Verapamil has greater negative inotropic
effects than amlodipine, but it is a weaker vasodilator. Verapamil is contraindicated in patients
with preexisting depressed cardiac function or AV conduction abnormalities. Diltiazem also
slows AV conduction, decreases the rate of firing of the sinus node pacemaker, and is also a
coronary artery vasodilator. Diltiazem can relieve coronary artery spasm and is particularly
useful in patients with variant angina. Nondihydropyridine calcium channel blockers can worsen
heart failure due to their negative inotropic effect, and their use should be avoided in this
population.
4. ORGANIC NITRATES
These compounds cause a reduction in myocardial oxygen demand, followed by relief of
symptoms. They are effective in stable, unstable, and variant angina.
A. Mechanism of action
Organic nitrates relax vascular smooth muscle by their intracellular conversion to nitrite
ions and then to nitric oxide, which in turn activates guanylate cyclase and increases synthesis of
cyclic guanosine monophosphate (cGMP). Elevated cGMP ultimately leads to
dephosphorylation of the myosin light chain, resulting in vascular smooth muscle relaxation
Nitrates such as nitroglycerin cause dilation of the large veins, which reduces preload (venous
return to the heart) and, therefore, reduces the work of the heart. Nitrates also dilate the coronary
vasculature, providing an increased blood supply to the heart muscle.

B. Pharmacokinetics
Nitrates differ in their onset of action and rate of elimination. The onset of action varies
from 1 minute for nitroglycerin to 30 minutes for isosorbide mononitrate.Sublingual
nitroglycerin, available in tablet or spray formulation, is the drug of choice for prompt relief of
an angina attack precipitated by exercise or emotional stress. All patients should have
nitroglycerin on hand to treat acute angina attacks. Significant first-pass metabolism of
nitroglycerin occurs in the liver. Therefore, it is commonly administered via the sublingual or
transdermal route (patch or ointment), thereby avoiding the hepatic first-pass effect. lsosorbide
mononitrate owes its improved bioavailability and long duration of action to its stability against
 Pharmacology 4th year Anti-angina agent

hepatic breakdown. Oral isosorbide dinitrate undergoes denitration to two mononitrates, both of
which possess antianginal activity.
C. Adverse effects
Headache is the most common adverse effect of nitrates. High doses of nitrates can also
cause postural hypotension, facial flushing, and tachycardia. Phosphodiesterase type 5 inhibitors
such as sildenafil potentiate the action of the nitrates. To preclude the dangerous hypotension
that may occur, this combination is contraindicated. Tolerance to the actions of nitrates develops
rapidly as the blood vessels become desensitized to vasodilation. Tolerance can be overcome by
providing a daily "nitrate-free interval" to restore sensitivity to the drug. The nitrate-free interval
of 10 to 12 hours is usually taken at night when myocardial oxygen demand is decreased.
However, variant angina worsens early in the morning, perhaps due to circadian catecholamine
surges. Therefore, the nitrate-free interval in patients with variant angina should occur in the late
afternoon. Nitroglycerin patches are worn for 12 hours and then removed for 12 hours to provide
the nitrate-free interval.
5. SODIUM CHANNEL BLOCKER
Ranolazine inhibits the late phase of the sodium current (late INJ, improving the oxygen
supply and demand equation. Inhibition of late INa reduces intracellular sodium and calcium
overload, thereby improving diastolic function. Ranolazine has anti-anginal as well as
antiarrhythmic properties. It is most often used in patients who have failed other antianginal
therapies. The antianginal effects of ranolazine are considerably less in women than in men. The
reason for this difference in effect is unknown. Ranolazine is extensively metabolized in the
liver, mainly by the CYP3A family and also by CYP2D6. It is also a substrate of P-glycoprotein.
As such, ranolazine is subject to numerous drug interactions. In addition, ranolazine can prolong
the QT interval and should be avoided with other drugs that cause QT prolongation.