Adrenergic antagonists: Alpha blockers

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Adrenergic antagonists: Alpha blockers

Cardiology

Cardiology

Introduction to the cardiovascular system
Anatomy of the heart
Anatomy of the coronary circulation
Anatomy clinical correlates: Heart
Anatomy of the superior mediastinum
Anatomy of the inferior mediastinum
Anatomy clinical correlates: Mediastinum
Development of the cardiovascular system
Fetal circulation
Cardiac muscle histology
Artery and vein histology
Arteriole, venule and capillary histology
Cardiovascular system anatomy and physiology
Lymphatic system anatomy and physiology
Coronary circulation
Blood pressure, blood flow, and resistance
Pressures in the cardiovascular system
Laminar flow and Reynolds number
Resistance to blood flow
Compliance of blood vessels
Control of blood flow circulation
Microcirculation and Starling forces
Measuring cardiac output (Fick principle)
Stroke volume, ejection fraction, and cardiac output
Cardiac contractility
Frank-Starling relationship
Cardiac preload
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Law of Laplace
Cardiac and vascular function curves
Altering cardiac and vascular function curves
Cardiac work
Cardiac cycle
Pressure-volume loops
Changes in pressure-volume loops
Physiological changes during exercise
Cardiovascular changes during hemorrhage
Cardiovascular changes during postural change
Normal heart sounds
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Action potentials in myocytes
Action potentials in pacemaker cells
Excitability and refractory periods
Cardiac excitation-contraction coupling
Cardiac conduction system
Cardiac conduction velocity
ECG basics
ECG normal sinus rhythm
ECG intervals
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ECG axis
ECG rate and rhythm
ECG cardiac infarction and ischemia
ECG cardiac hypertrophy and enlargement
Baroreceptors
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Renin-angiotensin-aldosterone system
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Cardiac tamponade
Dressler syndrome
Cardiac tumors
Acyanotic congenital heart defects: Pathology review
Cyanotic congenital heart defects: Pathology review
Atherosclerosis and arteriosclerosis: Pathology review
Coronary artery disease: Pathology review
Peripheral artery disease: Pathology review
Valvular heart disease: Pathology review
Cardiomyopathies: Pathology review
Heart failure: Pathology review
Supraventricular arrhythmias: Pathology review
Ventricular arrhythmias: Pathology review
Heart blocks: Pathology review
Aortic dissections and aneurysms: Pathology review
Pericardial disease: Pathology review
Endocarditis: Pathology review
Hypertension: Pathology review
Shock: Pathology review
Vasculitis: Pathology review
Cardiac and vascular tumors: Pathology review
Dyslipidemias: Pathology review
Cholinergic receptors
Adrenergic receptors
Cholinomimetics: Direct agonists
Cholinomimetics: Indirect agonists (anticholinesterases)
Muscarinic antagonists
Sympathomimetics: Direct agonists
Sympatholytics: Alpha-2 agonists
Adrenergic antagonists: Presynaptic
Adrenergic antagonists: Alpha blockers
Adrenergic antagonists: Beta blockers
ACE inhibitors, ARBs and direct renin inhibitors
Thiazide and thiazide-like diuretics
Calcium channel blockers
cGMP mediated smooth muscle vasodilators
Class I antiarrhythmics: Sodium channel blockers
Class II antiarrhythmics: Beta blockers
Class III antiarrhythmics: Potassium channel blockers
Class IV antiarrhythmics: Calcium channel blockers and others
Lipid-lowering medications: Statins
Lipid-lowering medications: Fibrates
Miscellaneous lipid-lowering medications
Positive inotropic medications

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Content Reviewers

Yifan Xiao, MD,Justin Ling, MD, MS

Alpha blocker and beta blockers are two types of postsynaptic anti-adrenergic medications that prevent their respective receptors from being stimulated by catecholamines, like norepinephrine and epinephrine.

The nervous system is divided into the central nervous system, so the brain and spinal cord; and the peripheral nervous system, which includes all the nerves that connect the central nervous system to the muscles and organs.

The peripheral nervous system can be divided into the somatic nervous system, which controls voluntary movement of our skeletal muscles; and the autonomic nervous system, which is further divided into the sympathetic and the parasympathetic, and controls the involuntary movement of the smooth muscles and glands of our organs.

Now, the autonomic nervous system - which includes both the sympathetic and parasympathetic nervous system - is made up of a relay that includes two neurons.

We’ll focus on just the sympathetic nervous system.

Signals for the autonomic nervous system start in the hypothalamus, at the base of the brain.

Hypothalamic neurons have really long axons that carry signals all the way down to the thoracic and lumbar spinal cord nuclei, where they synapse with preganglionic neuron cell bodies.

From there, the signal goes from the preganglionic neurons down its relatively short axon, exits the spinal cord, and reaches the nearby sympathetic ganglion, which is made up of lots of postganglionic neuron cell bodies.

The postganglionic neurons are also called adrenergic neurons because they release the neurotransmitter norepinephrine, which is also called noradrenalin; and to a much lesser degree, epinephrine, or adrenaline.

These two catecholamines activate the adrenergic receptors on the many different organs, which allow the sympathetic nervous system to trigger the fight or flight response that increases the heart rate and blood pressure, as well as slowing digestion.

All of this maximizes blood flow to the muscles and brain, and can help you either run away from a threat, or fight it, which is why it’s also called the fight or flight response.

Now, there are two main groups of adrenergic receptors: the alpha receptors, and beta receptors.

Let’s focus on alpha receptors, which have two subtypes: alpha-1 and alpha-2. alpha-1 adrenergic receptors are mainly located on the walls of blood vessels, and when stimulated, they cause vasoconstriction, thus decreasing blood flow to tissues.

In the eyes, alpha-1 adrenergic receptors also trigger mydriasis, or pupil dilation.

In the bladder, they cause sphincter constriction and urinary retention, or holding the urine within the bladder.

And in males, they trigger ejaculation.

Now, alpha-2 adrenergic receptors are primarily found on the presynaptic neuron.

So when a presynaptic nerve ending is stimulated to release noradrenaline in the synaptic cleft, some of that norepinephrine turns around and binds to alpha-2 receptors on the presynaptic membrane.

This inhibits further release of norepinephrine and serves as a mechanism of negative feedback control.

Alright, so medications that inhibit peripheral postsynaptic adrenergic neurons are called peripheral postsynaptic anti-adrenergics.

And based on the type of receptors they block, they are divided into two main categories - alpha blockers, and beta blockers.

Now, alpha blockers are subdivided into two groups of their own; non-selective alpha blockers and selective alpha blockers.

Non-selective alpha blockers work on both alpha-1 and alpha-2 adrenergic receptors and include phenoxybenzamine and phentolamine.

By blocking alpha-1 receptors, they cause vasodilation and lower blood pressure.

But what sets these two apart is that phenoxybenzamine is an irreversible, noncompetitive antagonist, while phentolamine is a reversible, competitive antagonist.

So, phenoxybenzamine binds irreversibly, to a different site on the receptor from catecholamines, and changes the shape of the receptor so it can no longer bind to catecholamines.

This effect cannot be overcome, even if the levels of catecholamines increase.

In fact, the only way out is to synthesize new adrenergic receptors, which takes about 24 hours.

This makes phenoxybenzamine perfect for the treatment of pheochromocytoma, a rare tumor of the adrenal medulla, which secretes too much of the catecholamines; adrenaline and noradrenaline.

On the other hand, phentolamine competes with catecholamines for the exact same binding site on the receptor, but is reversible; meaning that it can be kicked off after a while, especially if there’s a lot of catecholamines around.

Now, phentolamine can also be used in pheochromocytoma, but it’s mainly used to treat hypertensive crisis caused by the combination of a Monoamine oxidase inhibitors, or MAOIs for short, and tyramine-rich food and drinks, such as cheese, wine, and beer.

Okay, so since alpha-1 receptor inhibition causes vasodilation, we get side effects like hypotension; headache, due to vasodilation in the brain; and nasal congestion, due to vasodilation of nasal mucosa.

In men, it can cause difficulty in ejaculation, due to alpha-1 receptor inhibition in the seminal tract.

Key Takeaways

Adrenergic antagonists are a type of drug that blocks the action of adrenaline in the body. Adrenaline is a hormone that is released in response to stress or excitement, and it causes the heart rate to speed up and the blood vessels to narrow.

Alpha-blockers are a type of adrenergic antagonist that blocks the action of adrenaline on the alpha receptors. The alpha receptors are found in the muscles around the blood vessels, and when they are activated, they cause the blood vessels to narrow. Alpha-blockers, therefore, cause the blood vessels to widen, which lowers blood pressure and improves symptoms of congestive heart failure.

Sources

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