β-Adrenergic Blocking AgentsAll the clinically available β -blockers are competitive antagonists. Nonselective β-blockers act at both β1 and β2 receptors, whereas cardioselective β antagonists primarily block β 1 receptors.[Note:There are no clinically useful β2 antagonists]Although all β -blockers lower blood pressure in hypertension, they do not induce postural hypotension, because the α-adrenoceptors remain functional.
Therefore, normal sympathetic control of the vasculature is maintained. β -Blockers are also effective in treating: angina, cardiac arrhythmias, myocardial infarction, congestive heart failure, hyperthyroidism, and glaucoma, as well as serving in the prophylaxis of migraine headaches.
A. Propranolol(Inderal) A nonselective β antagonistPropranolol : is the β-adrenergic antagonist and blocks both β1 and β2 receptors. Sustained-release preparations for once-a-day dosing are available.
Actions:Cardiovascular: Propranolol diminishes cardiac output, having both negative inotropic and chronotropic effects. The resulting bradycardia .Cardiac output, work, and oxygen consumption are decreased by blockade of β1 receptors; these effects are useful in the treatment of angina .
Peripheral vasoconstriction: The reduction in cardiac output leads to decreased blood pressure. This hypotension triggers a reflex peripheral vasoconstriction that is reflected in reduced blood flow to the periphery. On balance, there is a gradual reduction of both systolic and diastolic blood pressures in hypertensive patients.
No postural hypotension occurs, because the α1-adrenergic receptors that control vascular resistance are unaffected.
Bronchoconstriction: Blocking β 2 receptors in the lungs of susceptible patients causes contraction of the bronchiolar smooth muscle .This can precipitate a respiratory crisis in patients with chronic obstructive pulmonary disease (COPD) or asthma. are thus contraindicated in patients with COPD or asthma.
Increased Na+ retention: Reduced blood pressure causes a decrease in renal perfusion, resulting in an increase in Na+ retention and plasma volume .In some cases, this compensatory response tends to elevate the blood pressure. For these patients, β -blockers are often combined with a diuretic to prevent Na+ retention. By inhibiting β receptors, renin production is also prevented, contributing to Na+ retention.
Disturbances in glucose metabolism: β-blockade leads to :1-decreased glycogenolysis and decreased glucagon secretion. Therefore, if a Type I (insulin-dependent) diabetic is to be given propranolol, very careful monitoring of blood glucose is essential, because hypoglycemia may occur after insulin injection. 2- β -Blockers also attenuate the normal physiologic response to hypoglycemia.
Therapeutic effects: 1- In Hypertension: Propranolol does not reduce blood pressure in people with normal blood pressure. Propranolol lowers blood pressure in hypertension patients by several different mechanisms of action: Decreased cardiac output is the primary mechanism. 2. decreased sympathetic outflow from the CNS .
2- Glaucoma: β-Blockers, topically applied Timolol, are effective in diminishing intraocular pressure in glaucoma. This occurs by decreasing the secretion of aqueous humor by the ciliary body. Many patients with glaucoma have been maintained with these drugs for years.
They neither affect the ability of the eye to focus for near vision nor change pupil size, as do the cholinergic drugs. However, in an acute attack of glaucoma, pilocarpine is still the drug of choice. The β -blockers are only used to treat this disease chronically.
3-Migraine: Propranolol is also effective in reducing migraine when used prophylactically. β-Blockers are valuable in the treatment of chronic migraine, in which they decrease the incidence and severity of the attacks.
4- Hyperthyroidism: Propranolol and other β -blockers are effective in blunting the widespread sympathetic stimulation that occurs in hyperthyroidism. In acute hyperthyroidism, β -blockers may be lifesaving in protecting against serious cardiac arrhythmias.
5- Angina pectoris: Propranolol decreases the oxygen requirement of heart muscle and, therefore, is effective in reducing the chest pain on exertion that is common in angina. Propranolol is therefore useful in the chronic management of stable angina, but not for acute treatment.
6- Myocardial infarction: Propranolol and other β -blockers have a protective effect on the myocardium. Thus, patients who have one myocardial infarction appear to be protected against a second heart attack by prophylactic use of β-blockers. In addition, administration of a β-blocker immediately following a myocardial infarction reduces infarct size and hastens recovery.
Propranolol also reduces the incidence of sudden arrhythmic death after myocardial infarction.
Adverse effects: 1- Bronchoconstriction: Propranolol has a serious and potentially lethal side effect when administered to an asthmatic . Deaths by asphyxiation for asthmatics administered the drug. Therefore, propranolol must never be used in treating any individual with COPD or asthma.
2- Arrhythmias: Treatment with β-blockers must never be stopped quickly because of the risk of precipitating cardiac arrhythmias, which may be severe. The β-blockers must be tapered off gradually for 1 week. Long-term treatment with a β antagonist leads to up-regulation of the β-receptor. On stop of therapy, the increased receptors can worsen angina or hypertension.
3- Disturbances in metabolism: β -Blockade leads to decreased glycogenolysis and decreased glucagon secretion. Fasting hypoglycemia may occur.
4- Drug interactions: Drugs that interfere with the metabolism of propranolol, such as cimetidine, fluoxetine (inhibit metabolism), may potentiate its antihypertensive effects. Conversely, those that stimulate its metabolism, such as barbiturates, phenytoin, and rifampin, can decrease its effects.
B- Timolol and Nadolol: Nonselective β antagonistsTimolol and Nadolol also block β1- and β2- adrenoceptors and are more potent than propranolol. Nadolol has a very long duration of action . Timolol reduces the production of aqueous humor in the eye. It is used topically in the treatment of chronic open-angle glaucoma and, occasionally, for systemic treatment of hypertension.
C- Acebutolol, Atenolol, and Esmolol: Selective β1 antagonistsDrugs that block the β1 receptors have been developed to eliminate the unwanted bronchoconstrictor effect (β 2 effect) of propranolol seen among asthmatic patients. This cardioselectivity is thus most at low doses and is lost at high doses.
Therapeutic use in hypertension: The cardioselective β -blockers are useful in hypertensive patients with impaired pulmonary function. Because these drugs have less effect on peripheral vascular β2 receptors, the coldness of extremities (a common side effect of β -blocker therapy) is less frequent. Cardioselective β -blockers are useful in diabetic hypertensive patients who are receiving insulin or oral hypoglycemic agents.
Pindolol and Acebutolol: (Antagonists with partial agonist activity)
Actions:Cardiovascular: are not pure antagonists; they have the ability to weakly stimulate both β1 and β2 receptors and are said to have intrinsic sympathomimetic activity (ISA). These partial agonists stimulate the β receptor to which they are bound, yet they inhibit stimulation by the more potent endogenous catecholamines, epinephrine and norepinephrine.Decreased metabolic effects: Blockers with ISA minimize the disturbances of lipid and carbohydrate metabolism that are seen with other β -blockers.
Therapeutic use in hypertension: β -Blockers with ISA are effective in hypertensive patients with moderate bradycardia, because a further decrease in heart rate is less pronounced with these drugs. Carbohydrate metabolism is less affected with Acebutolol and pindolol than it is with propranolol, making them valuable in the treatment of diabetics.
Drugs Affecting Neurotransmitter Release or Uptake amphetamine and tyramine, they exert their effects indirectly on the adrenergic neuron by causing the release of neurotransmitter from storage vesicles. Similarly, some agents act on the adrenergic neuron : either to interfere with neurotransmitter release or to alter the uptake of the neurotransmitter into the adrenergic nerve.
A. Reserpine Reserpine a plant alkaloid, blocks the Mg2+/adenosine triphosphate (dependent transport of biogenic amines) norepinephrine, dopamine, and serotonin from the cytoplasm into storage vesicles in the adrenergic nerves of all body tissues. This causes the ultimate depletion of biogenic amines.
Sympathetic function, in general, is impaired because of decreased release of norepinephrine. The drug has a slow onset, a long duration of action, and effects that persist for many days after discontinuation. Guanethidine blocks the release of stored norepinephrine as well as displaces norepinephrine from storage vesicles (thus producing a transient increase in blood pressure).
This leads to gradual depletion of norepinephrine in nerve endings except for those in the CNS. Guanethidine commonly causes orthostatic hypotension . Supersensitivity to norepinephrine due to depletion of the amine can result in hypertensive crisis in patients with pheochromocytoma.
C. Cocaine Although cocaine inhibits norepinephrine uptake, it is an adrenergic agonist. norepinephrine accumulate in the synaptic space ,resulting in enhancement of sympathetic activity and potentiation the action of epinephrine, norepinephrine.