ANS Medications PDF

Summary

This document provides an overview of ANS medications, including adrenergic and cholinergic drugs. It details their mechanisms of action and clinical applications.

Full Transcript

ANS Medications
Adrenergic Drugs
Drugs that mimic or block neurotransmitters like norepinephrine
and epinephrine
Adrenergic Agonists
Adrenergic agonists are drugs that stimulate adrenergic
receptors (either α or β receptors), mimicking the effects of
sympathetic neurotransmitters (norepinephrine and epinephrine).
They can act on specific receptor subtypes, and their effects vary
depending on which receptors they stimulate.

Alpha-1 (α₁) Agonists:

Alpha-1 receptors are primarily found in smooth muscles,
including blood vessels, the eye, and the urinary tract. When
stimulated, they cause vasoconstriction, leading to increased
blood pressure, pupil dilation (mydriasis), and smooth muscle
contraction
Phenylephrine treats hypotension

Alpha-2 (α₂) Agonists:

Alpha-2 receptors are primarily located in the brainstem. When
stimulated, they inhibit the release of norepinephrine and reduce
sympathetic outflow, leading to a decrease in blood pressure
and sedation.
Clonidine treats hypertension and withdrawal symptoms

Beta-1 (β₁) Agonists:
 Beta-1 receptors are located primarily in the heart. When
stimulated, they increase heart rate (chronotropy), contractility
(inotropy), and conductivity (dromotropy), improving cardiac
output.
Dobutamine: Used in acute heart failure or cardiogenic shock to
increase cardiac output.

Beta-2 (β₂) Agonists:

Beta-2 receptors are found in smooth muscles of the lungs,
uterus, and vasculature. Stimulation causes bronchodilation,
vasodilation, and relaxation of uterine smooth muscle.
Albuterol: A short-acting bronchodilator used in the treatment of
asthma and chronic obstructive pulmonary disease (COPD).
Terbutaline: Used to treat bronchospasm and premature labor.

Beta-3 (β₃) Agonists:

Beta-3 receptors are found in adipose tissue and the bladder.
Activation leads to lipolysis(fat breakdown) and relaxation of the
bladder muscle.
Mirabegron: Used to treat overactive bladder.

Adrenergic-Blocking Drugs

Adrenergic antagonists, or adrenergic blockers, inhibit the effects of
endogenous catecholamines (norepinephrine and epinephrine) by
blocking the adrenergic receptors. These drugs can be selective (acting
on specific receptor subtypes) or non-selective.

Alpha-1 (α₁) Antagonists:
 Alpha-1 blockers work by blocking the alpha-1 receptors on
smooth muscle, resulting in vasodilation, reduced blood
pressure, and relaxation of the bladder and prostate smooth
muscle.
Prazosin: Used to treat hypertension and symptoms of benign
prostatic hyperplasia (BPH).
Tamsulosin: Primarily used for BPH treatment.

Alpha-2 (α₂) Antagonists:

Alpha-2 blockers increase norepinephrine release by blocking the
inhibitory action of alpha-2 receptors. This leads to increased
sympathetic tone and potentially increased blood pressure.
Yohimbine: Used to treat erectile dysfunction and orthostatic
hypotension.

Beta-1 (β₁) Antagonists (Beta Blockers):

Beta-1 blockers primarily affect the heart, reducing heart rate,
contractility, and cardiac output. This makes beta blockers
useful in treating hypertension, arrhythmias, and heart failure.
Metoprolol, Atenolol: Selective beta-1 blockers used to treat
hypertension, arrhythmias, and heart failure.

Beta-2 (β₂) Antagonists:

Beta-2 blockers are rarely used therapeutically, as their blockade
can lead to bronchoconstriction, which is contraindicated in
asthma and COPD patients. However, non-selective beta
blockers (which block both beta-1 and beta-2 receptors) can have
such effects.
 Propranolol: Non-selective beta blocker that can cause
bronchoconstriction in susceptible individuals.

Non-selective Beta Blockers (Beta-1 and Beta-2 Blockers):

These drugs block both beta-1 and beta-2 receptors, affecting the
heart, lungs, and vasculature.
Propranolol, Carvedilol: Used for hypertension, heart failure, and
anxiety.

Indirect-Acting Adrenergic Drugs

These drugs do not directly stimulate adrenergic receptors but instead
increase the availability of norepinephrine or epinephrine in the
synaptic cleft, thus indirectly enhancing adrenergic signaling.

Amphetamines: Increase the release of norepinephrine and
dopamine, leading to central nervous system stimulation.
Cocaine: Inhibits the reuptake of norepinephrine, dopamine, and
serotonin, enhancing their effects.

Cholinergic drugs

Cholinergic drugs are medications that interact with the cholinergic
system, which uses acetylcholine (ACh) as its primary
neurotransmitter. These drugs influence cholinergic receptors located
throughout the body, primarily the muscarinic receptors (M1, M2, M3,
M4, and M5) and nicotinic receptors (Nn and Nm). The primary effects
of cholinergic drugs are related to their stimulation of the
parasympathetic nervous system, leading to a "rest-and-digest"
response in various organs.

1. Direct-Acting Cholinergic Drugs
Direct-acting cholinergic drugs are those that directly stimulate
cholinergic receptors, either muscarinic or nicotinic receptors.

Muscarinic Receptor Agonists (Parasympathomimetics)

Muscarinic agonists specifically stimulate muscarinic receptors, which
are G protein-coupled receptors found in various tissues such as the
heart, smooth muscles, and glands. These receptors mediate the typical
effects of the parasympathetic nervous system (e.g., bradycardia,
increased secretion, smooth muscle contraction).

Mechanism of Action: Muscarinic receptor agonists mimic the
action of acetylcholine, leading to a range of effects depending on
the receptor subtype activated:
○ M1: Found mainly in the central nervous system (CNS) and
gastric parietal cells, modulates cognition and gastric acid
secretion.
○ M2: Found primarily in the heart, mediates negative
chronotropy (slows heart rate) and negative
inotropy(reduces heart muscle contractility).
○ M3: Found in smooth muscles and glands, mediates smooth
muscle contraction (e.g., bronchoconstriction, miosis) and
increased glandular secretions (e.g., salivation, sweating).
Examples:
○ Pilocarpine: Used to treat glaucoma (reduces intraocular
pressure) and xerostomia (dry mouth).
○ Bethanechol: Used to treat urinary retention by
stimulating bladder contraction.

Nicotinic Receptor Agonists
Nicotinic agonists stimulate nicotinic receptors, which are ion
channels found at the neuromuscular junction (Nm receptors) and in
autonomic ganglia (Nn receptors). Activation of nicotinic receptors leads
to depolarization and stimulation of target tissues.

Mechanism of Action:
○ Nn receptors: Found in autonomic ganglia, stimulation of
Nn receptors increases sympathetic and parasympathetic
tone, depending on the organ system.
○ Nm receptors: Found at the neuromuscular junction,
activation causes muscle contraction.
Example:
○ Nicotine: Stimulates both Nn and Nm receptors, leading to
a variety of effects including CNS stimulation, increased
heart rate, and increased blood pressure.

2. Indirect-Acting Cholinergic Drugs

Indirect-acting cholinergic drugs work by increasing the
concentration of acetylcholine (ACh) at cholinergic synapses. This is
typically achieved by inhibiting the enzyme acetylcholinesterase,
which breaks down ACh.

Acetylcholinesterase Inhibitors

These drugs inhibit the enzyme acetylcholinesterase (AChE), which is
responsible for the hydrolysis of acetylcholine. By preventing
acetylcholine breakdown, these drugs increase the duration and
intensity of ACh action at both muscarinic and nicotinic receptors.

There are two main categories of acetylcholinesterase inhibitors:
 1. Reversible Inhibitors: These drugs temporarily inhibit
acetylcholinesterase.
○ Mechanism of Action: By inhibiting AChE, reversible
inhibitors allow acetylcholine to accumulate at cholinergic
synapses, enhancing both muscarinic and nicotinic
neurotransmission.
○ Examples:
Neostigmine: Used to treat myasthenia gravis (by
improving neuromuscular transmission) and to reverse
neuromuscular blockade during surgery.
Physostigmine: Used to treat anticholinergic toxicity
(e.g., from atropine overdose) and glaucoma.
Donepezil, Rivastigmine: Used to treat Alzheimer's
disease by increasing ACh levels in the brain.
2. Irreversible Inhibitors: These drugs form a covalent bond with
acetylcholinesterase, leading to prolonged inhibition.
○ Mechanism of Action: These agents permanently
inactivate acetylcholinesterase, leading to prolonged
accumulation of acetylcholine, but this effect can only be
reversed by the synthesis of new enzyme molecules.
○ Examples:
Organophosphates (e.g., malathion, sarin): Used in
pesticides and chemical warfare agents, they cause
prolonged ACh accumulation, leading to toxic effects
such as muscle paralysis and respiratory failure.
Treatment involves pralidoxime and atropine.

Cholinesterase Reactivators
Some drugs (e.g., pralidoxime) can reactivate acetylcholinesterase
that has been inhibited by organophosphates, reversing the toxic
effects.

3. Clinical Applications of Cholinergic Drugs

Cholinergic drugs have various therapeutic applications based on their
mechanism of action:

Direct-Acting Muscarinic Agonists:

Pilocarpine: Used to treat glaucoma by reducing intraocular
pressure and xerostomia (dry mouth) caused by Sjögren’s
syndrome or radiation therapy.
Bethanechol: Used to treat urinary retention or gastric atony
by stimulating smooth muscle contraction.

Indirect-Acting Acetylcholinesterase Inhibitors:

Neostigmine: Used for myasthenia gravis, postoperative ileus, and
to reverse neuromuscular blockade after surgery.
Donepezil, Rivastigmine: Used to treat Alzheimer's disease by
increasing ACh availability in the brain.
Physostigmine: Used for the treatment of anticholinergic
toxicity (e.g., atropine overdose).

Toxicology (Cholinergic Poisoning):

Organophosphates (e.g., sarin gas, pesticides): Cause severe
poisoning by irreversibly inhibiting acetylcholinesterase, leading
to muscle paralysis, seizures, and respiratory failure.
Treatment includes atropine(to block excessive muscarinic
stimulation) and pralidoxime (to reactivate acetylcholinesterase).
4. Side Effects and Toxicity

While cholinergic drugs can be beneficial, they may also lead to
unwanted effects due to overstimulation of the parasympathetic
system (excessive muscarinic or nicotinic effects).

Muscarinic Effects:
○ Bradycardia, hypotension, bronchoconstriction,
salivation, sweating, diarrhea, miosis (pupil constriction).
○ Toxicity: SLUDGE syndrome (Salivation, Lacrimation,
Urination, Defecation, Gastrointestinal distress, Emesis).
Nicotinic Effects:
○ Muscle weakness, fasciculations, and paralysis (due to
overstimulation of neuromuscular junctions).

In cases of toxicity or overdose, atropine (a muscarinic antagonist) is
used to counteract muscarinic effects, and pralidoxime is used for
organophosphate poisoning to regenerate acetylcholinesterase.

Cholinergic blocking drugs

known as anticholinergics or antimuscarinic drugs, are substances
that block the action of acetylcholine (ACh) at cholinergic receptors,
primarily the muscarinic receptors. These drugs interfere with the
normal parasympathetic nervous system (PNS) functions, as
acetylcholine is the primary neurotransmitter for the parasympathetic
system.

The main effect of cholinergic blockers is to produce
sympathomimetic effects (i.e., mimicking the effects of the
sympathetic nervous system), leading to a "fight or flight" response.
This results in a range of physiological changes, such as increased
heart rate, bronchodilation, dilated pupils, reduced
gastrointestinal motility, and drying of secretions (saliva, mucus,
etc.).

Muscarinic Antagonists (Antimuscarinics)

These are the most commonly used cholinergic blocking drugs, and
they block muscarinic receptors selectively, often without affecting
nicotinic receptors.

Atropine: One of the most well-known antimuscarinic drugs. It is
used for a variety of purposes:
○ Bradycardia: Increases heart rate by blocking the
parasympathetic influence on the heart (useful in cases of
sinus bradycardia or AV block).
○ Antidote for cholinergic poisoning: Used to counteract the
effects of organophosphate poisoning (e.g., nerve agents,
pesticides).
○ Pupil dilation: Used in ophthalmology for mydriasis
(dilation of the pupil) for eye exams and treatment of iritis
or uveitis.
○ Pre-anesthetic medication: To reduce salivation and
bronchial secretions during surgery.
Scopolamine: A potent muscarinic antagonist used for:
○ Motion sickness: Used as a transdermal patch or oral form
to prevent nausea and vomiting caused by motion sickness.
○ Pupil dilation and cycloplegia in eye exams.
Ipratropium and Tiotropium: Antimuscarinic bronchodilators
used to treat:
 ○ Chronic obstructive pulmonary disease (COPD) and
asthma. These drugs block muscarinic receptors in the
airways to cause bronchodilation.
Glycopyrrolate: Used in perioperative settings to reduce
salivation and secretions during anesthesia and to treat peptic
ulcers by reducing gastric acid secretion.
Oxybutynin, Tolterodine, Solifenacin: These drugs are used to
treat overactive bladder by relaxing the bladder smooth muscle
(antispasmodic effect).

2. Ganglionic Blockers

Ganglionic blockers inhibit the transmission of nerve impulses through
autonomic ganglia by blocking nicotinic receptors (Nn) on the cell
bodies of sympathetic and parasympathetic neurons. These drugs are
rarely used today due to significant side effects, as they affect both the
sympathetic and parasympathetic systems.

Hexamethonium and Trimethaphan: Once used to treat
hypertension in emergency situations, but largely replaced by
other agents due to their widespread and unpredictable effects
on both sympathetic and parasympathetic systems.

3. Centrally Acting Muscarinic Antagonists

These drugs exert their effects on the CNS and are used in specific
conditions, particularly those related to motion sickness or Parkinson's
disease.

Benztropine and Trihexyphenidyl: Used in the treatment of
Parkinson's disease to reduce tremors and rigidity. They block
 muscarinic receptors in the CNS, particularly the striatum, to
restore balance between dopamine and acetylcholine.
Procyclidine: Another drug used to treat the extrapyramidal
symptoms of Parkinson's disease or antipsychotic-induced
movement disorders.

Physiological Effects of Cholinergic Blockers

The effects of cholinergic blockers are largely a result of reduced
parasympathetic activity. Some of the key effects include:

1. Cardiovascular Effects:
○ Increased heart rate (tachycardia): By blocking M2
receptors in the heart, cholinergic blockers reduce vagal
tone, leading to increased heart rate.
○ Decreased cardiac output and blood pressure: In some
cases, due to reduced parasympathetic control of the
vasculature.
2. Respiratory Effects:
○ Bronchodilation: Blocking M3 receptors in the lungs
reduces bronchoconstriction and can be useful in conditions
like asthma or COPD.
○ Dry mouth and throat: Blockage of salivary gland activity
reduces secretions.
3. Gastrointestinal Effects:
○ Decreased gastrointestinal motility: By blocking M3
receptors in the GI tract, cholinergic blockers can reduce
peristalsis, leading to constipation.
○ Reduced gastric acid secretion: Drugs like scopolamine
can reduce the secretion of gastric acid.
4. Urinary System Effects:
 ○ Urinary retention: Blockage of muscarinic receptors in the
bladder smooth muscle can result in difficulty emptying the
bladder, leading to urinary retention.
5. Pupil Dilation (Mydriasis):
○ Cholinergic blockers cause pupil dilation by blocking the M3
receptors in the iris, leading to mydriasis and cycloplegia
(paralysis of the ciliary muscle).
6. CNS Effects:
○ Cognitive effects: Central muscarinic blockade can cause
confusion, memory disturbances, and even hallucinations,
particularly in elderly patients.
○ Sedation or drowsiness: Some anticholinergics, like
scopolamine, have sedative effects and are used in motion
sickness.

Clinical Uses of Cholinergic Blocking Drugs

Cholinergic blockers are used in a variety of clinical situations:

Pre-anesthesia medication (e.g., atropine, scopolamine)
Treatment of motion sickness (e.g., scopolamine)
Management of COPD and asthma (e.g., ipratropium,
tiotropium)
Treatment of overactive bladder (e.g., oxybutynin,
tolterodine)
Management of Parkinson's disease (e.g., benztropine,
trihexyphenidyl)
Eye exams (e.g., atropine, scopolamine for mydriasis and
cycloplegia)
Management of bradycardia (e.g., atropine)
Side Effects and Toxicity

While cholinergic blockers are useful therapeutically, they can have
unwanted side effects, especially when used excessively or in the
elderly.

Common side effects:
○ Dry mouth, blurred vision, photophobia, urinary
retention, constipation, and tachycardia.
○ Cognitive impairment and delirium (especially in elderly
patients).
Toxicity:
○ Symptoms of anticholinergic toxicity include "hot as a hare,
blind as a bat, dry as a bone, red as a beet, mad as a
hatter": Hyperthermia (due to sweating inhibition), blurred
vision (due to pupil dilation), dry mouth, flushed skin, and
agitation or confusion.

Treatment of Toxicity

Physostigmine (an acetylcholinesterase inhibitor) can be used to
reverse anticholinergic toxicity by increasing acetylcholine levels
at the receptor site.