BMS3-20 Drugs acting on autonomic nervous system-Assoc. Prof. Ahmet Özer ŞEHİRLİ (1).pdf

Transcript

DRUGS THAT AFFECT THE
AUTONOMİC NERVOUS SYSTEM
Doç. Dr. Ahmet Özer Şehirli

LEARNİNG OBJECTIVES
Describes of;
Adrenergic System Drugs
Colinergic System Drugs

Overview of the ANS
• Consists of the sympathetic and
parasympathetic nervous system.
• Drugs that stimulate the sympathetic
nervous system are called adrenergics.
• Adrenergics are also called adrenergic
agonists or sympathomimetics because
they mimic the effects of the SNS
neurotransmitters norepinephrine and
epinephrine (catecholamines).

Summary of sympathetic neurons
and synapses

Preganglionic neurons
•
•
•

Short
Synapse with postganglionic neurons near spinal cord
Release acetylcholine (ACH) to activate nicotinic receptors on postganglionic
neurons

Postganglionic neurons
•
•
•

Long
Synapse on the target organ
Release norepinephrine to activate adrenergic receptors on target organs

Summary of parasympathetic neurons
and synapses

Preganglionic neurons
•
•
•

Long
Synapse with postganglionic neurons at or near organ
Release acetylcholine (ACH) to activate nicotinic receptors on postganglionic
neurons

Postganglionic neurons
•
•
•

Short
Synapse on the target organ
Release acetylcholine (ACH) to activate muscarinic receptors on the target
organ

• Parasympathetic System
• “Rest and Digest"
• Body "renewal" system
• Sympathetic System
• “Fight or Flight"
• activities that require energy

Adrenergic Receptors
• Adrenergic receptors are the sites where
adrenergic drugs bind and produce their effects.
• Adrenergic receptors are divided into alphaadrenergic and beta-adrenergic receptors
depending on whether they respond to
norepinephrine or epinephrine.
• Both alpha- and beta-adrenergic receptors have
subtypes designated 1 and 2.

Alpha Receptors
• Alpha1-adrenergic receptors are located on
the postsynaptic effector cells.
• Alpha2-adrenergic receptors are located on
the presynaptic nerve terminals.

Beta Receptors
• Both beta-adrenergic receptors are located on
the postsynaptic effector cells.
• Beta1-adrenergic receptors are primarily
located in the heart.
• Beta2-adrenergic receptors are primarily
located in the smooth muscle of bronchioles,
arterioles, and visceral organs.

Dopaminergic Receptors
• Dopaminergic receptors are only stimulated
by dopamine which causes the vessels of
renal, mesenteric, coronary, and cerebral
arteries to dilate and the flow of blood to
increase.

Adrenergic Receptor Specificity
Drug
Epinephrine
Ephedrine
Norepinephrine

Phenylephrine
Isoproterenol
Dopamine
Dobutamine
terbutaline

α1

α2

β1

β2

Dopaminergic

Adrenergic Blockers
• Adrenergic blockers, also called adrenergic
antagonists or sympatholytics, have the
opposite effect of adrenergics.
• Alpha-blockers and beta-blockers bind to the
receptor sites for norepinephrine and
epinephrine blocking the stimulation of the
SNS.

Cholinergics
• Drugs that stimulate the parasympathetic
nervous system are called cholinergics.
• Sometimes called cholinergic agonists or
parasympathomimetics, these drugs mimic
the effect of acetylcholine, which is the
neurotransmitter responsible for the
transmission of nerve impulses to effector
cells in the PSNS.

Cholinergic Receptors
• The receptors that bind the acetylcholine and
mediate its actions are called cholinergic
receptors.
• These receptors consist of nicotinic receptors
and muscarinic receptors.
• Nicotinic receptors are located in the ganglia
of the PSNS and SNS and are stimulated by
nicotine.

Muscarinic Receptors
• Muscarinic receptors are located
postsynaptically in the smooth muscle, cardiac
muscle, and glands.
• These receptors are stimulated by muscarine
(found in mushrooms).

Cholinergic Drugs
• Cholinergic drugs can be direct-acting (bind to
and activate cholinergic receptors) or indirectacting (inhibit cholinesterase which is the
enzyme responsible for breaking down
acetylcholine).

Cholinergic Blockers
• Cholinergic blockers, anticholinergics,
parasympatholytics, and antimuscarinic
agents are all terms for the class of drugs that
block the actions of acetylcholine in the PSNS.
• Cholinergic blockers allow the SNS to
dominate and, therefore, have many of the
same effects as the adrenergics.

Cholinergic Blockers
• Cholinergic blockers are competitive
antagonists that compete with acetylcholine
for binding at the muscarinic receptors of the
PSNS, inhibiting nerve transmission.
• This effect occurs at the neuroeffector
junctions of smooth muscle, cardiac muscle,
and exocrine glands.
• Have little effect at the nicotinic receptors.

Autonomic Nervous System
Medications (2 of 2)
• Drugs Affecting the Sympathetic System:
– Adrenergic Receptors
– Adrenergic Agonists
– Adrenergic Antagonists
– Skeletal Muscle Relaxants

SYMPATHETIC NERVOUS SYSTEM
• a) Sympathomimetic Drugs: These are drugs
that mimic the effects of the sympathetic
nervous system.
• Catecholamines: Adrenaline, Noradrenaline,
Dopamine, Isoproterenol

Adrenergic Drugs
• Also called sympathomimetics because they
produce effects similar to those produced by
the sympathetic nervous system.
• Classified into two groups - catecholamines
and noncatecholamines.
• Also classified according to their action direct-acting, indirect-acting, and dual-acting.

Adrenergic Drugs
• Therapeutic uses depend on which
receptors they stimulate and to what
degree - alpha-adrenergic, beta-adrenergic,
and dopamine receptors.
• Most adrenergic drugs stimulate alpha and
beta receptors mimicking the action of
norepinephrine and epinephrine.
• Dopaminergic drugs act primarily on SNS
receptors stimulated by dopamine.

Catecholamines
• Stimulate the nervous system, constrict
peripheral blood vessels, increase heart rate,
and dilate the bronchi.
• Can be natural or synthetic and include:
dobutamine, dopamine, epinephrine,
norepinephrine, and isoproterenol.

Catecholamines
Pharmacokinetics:
• Not administered orally; when administered
sublingually are absorbed rapidly through the
mucous membranes; when administered SC
absorption is slowed due to vasoconstriction
around the injection site; when administered
IM absorption is more rapid.

Catecholamines
• Widely distributed throughout the body;
predominantly metabolized by the liver;
excreted primarily in the urine.
Pharmacodynamics:
• Are primarily direct-acting.
• Activation of alpha receptors generates an
excitatory response except for intestinal
relaxation.

Catecholamines
• Activation of the beta receptors mostly
produces an inhibitory response except in the
heart cells where norepinephrine produces
excitatory effects.
• The clinical effects of catecholamines depend
on the dosage and route of administration.

Catecholamines
• Positive inotropic effects - heart contracts
more forcefully.
• Positive chronotropic effects - heart beats
faster.
• Positive dromotropic effects - increased
conduction through the AV node.

Catecholamines
Pharmacotherapeutics:
• Use depends on the particular receptor site
that is activated.
• Norepinephrine - alpha activity.
• Dobutamine and isoproterenol - beta
activity.
• Epinephrine - alpha and beta activity.
• Dopamine – dopaminergic, beta, and alpha
activity.

Catecholamines
• Catecholamines that stimulate alpha
receptors are used to treat hypotension
caused by a loss of vasomotor tone or
hemorrhage.
• Catecholamines that stimulate beta1receptors are used to treat bradycardia,
heart block, low cardiac output, paroxysmal
atrial or junctional tachycardia, ventricular
fibrillation, asystole, and cardiac arrest.

Catecholamines
• Catecholamines that stimulate beta2-receptors
are used to treat acute and chronic bronchial
asthma, emphysema, bronchitis, and acute
hypersensitivity reactions to drugs.
• Dopamine that stimulates dopaminergic
receptors is used to improve blood flow to
kidneys.

Catecholamines
• Synthetic catecholamines have a short
duration of action which can limit their
therapeutic usefulness.
• Drug interactions/adverse reactions:
• Can be serious including hyper and
hypotension, arrhythmias, seizures, and
hyperglycemia.

Non-catecholamines
Uses include:
• local or systemic constriction of blood vessels phenylephrine (Beta-2 mimetic).
• Dilation of bronchioles (Beta-2 mimetic)
• Decongestion (Alpha mimetic).
• Smooth muscle relaxation (Beta-2 mimetic).

Non-catecholamines (Indirect acting
adrenomimetic): (Other sympathomimetic
amines)
Those acting on alpha receptors: Ephedrine,
phenylephrine, metaraminol, methoxamine,
etilephrine, norphenephrine, heptaminol. They
are used as antihypotensive.
Nafazolin, Tetrahydrazoline, xylometazoline,
oxymetazoline; Used as a nasal decongestant.

Non-catecholamines (Indirect acting
adrenomimetic): (Other sympathomimetic
amines)
Those acting on beta receptors:
Orciprenaline, salbutamol, terbutaline
(bronchodilator effect is evident). It is mostly
used in the treatment of bronchial asthma and
bronchospasm. However, it should be used with
caution in patients with CVS disease and
hyperthyroidism. Ritodrine is used parenterally
or orally to stop preterm labor as a uterine
relaxant.

Non-catecholamines
Pharmacokinetics:
• Since the drugs have different routes of
administration, absorption and distribution
vary; can be administered orally; metabolized
primarily by the liver; excreted primarily in the
urine.

Non-catecholamines
Pharmacodynamics:
• Direct-acting noncatecholamines that
stimulate alpha activity include phenylephrine
(Neo-Synephrine).
• Direct-acting noncatecholamines that
stimulate beta2 activity include albuterol
(Proventil/Ventolin) and terbutaline
(Brethine).

Non-catecholamines
• Indirect-acting – phenylpropanolamine.
• Dual-acting - ephedrine.

Non-catecholamines
Pharmacotherapeutics:
• Stimulate the sympathetic nervous system
and produce a variety of effects in the body.
• Example – ritodrine - used to stop pre-term
labor.
• Drug interactions/adverse reactions:
• Taken with monoamine oxidase inhibitors can
cause severe hypertension and death

Alpha1 Agonists
• Profound vasoconstriction
– Increases afterload & blood pressure when given
systemically
– Decreases drug absorption & bleeding when given
topically

Adrenergic Blocking Drugs
• Called sympatholytic drugs.
• Used to disrupt SNS function by blocking
impulse transmission at adrenergic receptor
sites.
• Classified according to their site of action:
alpha-adrenergic blockers and beta-adrenergic
blockers.

Alpha1 Antagonism
• Inhibits peripheral vasoconstriction
– Used for hypertension, congestive heart failure
and benign prostatic hypertrophy
– prazosin (Minipress®)
– doxazosin (Cardura®)
– Phentolamine (imidazoline derivative potent
competetive antagonist) (Regitine®)
• Blocks alpha1&2 receptors
-Yohumbine blocks alpha-2 receptor
Phenoxybenzamine (irreversible alpha antagonist)

Alpha-Adrenergic Blockers
• Work by interrupting the actions of the
catecholamines norepinephrine and
epinephrine at the alpha receptors resulting
in: relaxation of the smooth muscle in the
blood vessels; increased dilation of blood
vessels; and decreased blood pressure.
• Prototype drug -prazocin (Minipress)

Alpha-Adrenergic Blockers
Pharmacokinetics:
• The action of alpha blockers in the body isn’t
well understood.
• Pharmacodynamics:
• Block the synthesis, storage, release, and
uptake of norepinephrine by neurons.
• Antagonize epinephrine and norepinephrine
at alpha receptor sites.

Alpha-Adrenergic Blockers
• Do not discriminate alpha1 and alpha2
receptors.
• Occupy alpha receptor sites on the smooth
muscle of blood vessels resulting in
vasodilation, decreased peripheral vascular
resistance, and decreased blood pressure.

Alpha-Adrenergic Blockers
• Pharmacotherapeutics:
• Used to treat: hypertension; peripheral
vascular disorders, and pheochromocytoma (a
catecholamine-secreting tumor causing severe
hypertension).

Alpha-Adrenergic Blockers
Drug interactions/adverse reactions:
• Many drugs interact producing synergistic
effects such as orthostatic hypotension, severe
hypotension and vascular collapse.

Beta Antagonists (β Blockers)
• Frequently used
• Lower Blood Pressure
• Negative chronotropes & inotropes
Beta1 Selective Blockade
• atenolol (Tenormin®)
• esmolol (Brevibloc®)
• metoprolol (Lopressor®)
• Pindolol (has partial
agonistic activity)

Nonselective
• propranolol (Inderal®)
• labetalol (Normodyne®,
Trandate®)
• sotalol (Betapace®)
• Butoxamine (Beta 2
antagonist)

Beta-Adrenergic Blockers
• Prevent stimulation of the sympathetic
nervous system by inhibiting the action of
catecholamines at the beta-adrenergic
receptors (beta-blockers).
• Are selective or nonselective.
• Nonselective beta-blockers affect beta1
receptor sites located mainly in the heart
and beta2 receptor sites located in the
bronchi, blood vessels, and uterus.

Beta-Adrenergic Blockers
Pharmacokinetics:
• Absorbed rapidly and are protein-bound; the
onset of action is primarily dose and drugdependent; distributed widely with the
highest concentrations in the heart, lungs, and
liver; metabolized primarily in the liver;
excreted primarily in the urine.

Beta-Adrenergic Blockers
Pharmacodynamics:
• Effect adrenergic nerve endings as well as
the adrenal medulla.
• Effects on the heart include: decreased
peripheral vascular resistance; decreased
blood pressure; decreased force of heart
contractions; decreased oxygen
consumption; slowed impulse conduction;
and decreased cardiac output.

Beta-Adrenergic Blockers
• Selective beta1-blockers reduce stimulation of
the heart (also called cardioselective betaadrenergic blockers).
• Nonselective beta1 and beta2-blockers not
only reduce stimulation of the heart but can
also cause the bronchioles of the lungs to
constrict.

Beta-Adrenergic Blockers
Pharmacotherapeutics:
• Clinical usefulness is based largely upon how
they affect the heart.
• Used to treat heart attacks, angina,
hypertension, hypertrophic cardiomyopathy,
and supraventricular arrhythmias.

Beta-Adrenergic Blockers
• Also used to treat anxiety, cardiovascular
symptoms associated with thyrotoxicosis,
essential tremor, migraine headaches, openangle glaucoma, and pheochromocytoma.
• Drug interactions/adverse reactions:
• Many causing cardiac and respiratory
depression, arrhythmia, severe
bronchospasm, and severe hypotension.

Autonomic Nervous System
Medications (1 of 2)
• Drugs Affecting the Parasympathetic
System:
– Cholinergics
– Anticholinergics
– Ganglionic Blocking Agents
– Neuromuscular Blocking Agents
– Ganglionic Stimulating Agents

Drugs Affecting the Parasympathetic
System:
Receptor type: muscarinic, neurotransmitter is
acetylcholine.
Direct acting cholinomimetic agent
Parasympathomimetic Drugs (muscarinic,
cholinergic):
Acetylcholine (Rapid hydrolyzed so it isn’t
used in clinical practice) and similar
(Acetylcholine, Carbachol, Betanekol (both
muscarinic and nicotinic), Methacholine)
Cholinergic alkaloids (Pilocarpine, muscarine,
nicotine)

Cholinergic Drugs
• Promote the action of the neurotransmitter
acetylcholine.
• Also called parasympathomimetic drugs
because they produce the effects that mimic
parasympathetic nerve stimulation.
• Two major classes of cholinergic drugs:
cholinergic agonists and anticholinesterase
drugs.

Cholinergic Drugs
• Cholinergic agonists mimic the action of the
neurotransmitter acetylcholine.
• Anticholinesterase drugs inhibit the
destruction of acetylcholine at the cholinergic
receptor sites.

Cholinergic Agonists
• Mimic the action of acetylcholine.
• Include the drugs acetylcholine (rarely used),
bethanechol (Urocholine), carbachol
(Miostat), and pilocarpine.
• Pharmacokinetics:
• Administered topically (eye), orally, and
subcutaneously; metabolized by
cholinesterases; excreted by the kidneys.

Cholinergic Agonists
Pharmacodynamics:
• Mimic the action of acetylcholine on the
neurons of target organs producing:
salivation, bradycardia, vasodilation,
constriction of bronchioles, increased GI
activity, increased tone and contraction of
the bladder muscles, and constriction of
pupils (myozis).

Cholinergic Agonists
Pharmacotherapeutics:
• Used to treat: atonic bladder conditions and
post-operative and postpartum urinary
retention; GI disorders such as post-operative
abdominal distention and GI atony; reduce
eye pressure in glaucoma patients and during
eye surgery; and salivary hypofunction.

Cholinergic Agonists
Drug interactions/adverse reactions:
• Taken with other cholinergic drugs can
increase the effects.
• Taken with cholinergic blocking drugs can
reduce the effects.
• Can produce adverse effects in any organ
innervated by the parasympathetic nerves.

Cholinergic Agonists
Cholinergic agents
cause SLUDGE!

These effects are
predictable by knowing
PNS physiology

Salivation
Lacrimation
Urination
Defecation
Gastric motility
Emesis

The symptoms of mushroom poisoning: Salivation, lacrimation, nausea,
vomiting, headache, abdominal colic, Bradycardia, hypotension and
shock

Anticholinesterase Drugs
• Block the action of the enzyme
acetylcholinesterase, which breaks down
acetylcholine, at the cholinergic receptor
sites.
• Divided into two categories - reversible and
irreversible.
• Reversible have a short duration and
include: donepezil (Aricept) and
edrophonium (Tensilon).

Reversible ChE Inhibitors
• neostigmine (Prostigmine®)
– Myasthenia Gravis at nicotinicM receptors
– Can reverse nondepolarizing neuromuscular
blockade

• physostigmine (Antilirium®)
– Shorter onset of action
– Used for iatrogenic atropine overdoses at
muscarinic receptors

Anticholinesterase Drugs
• Irreversible anticholinesterase drugs have
long-lasting effects.
• Used primarily as toxic insecticides and
pesticides or as a nerve gas in chemical
warfare.

Irreversible ChE Inhibitors (MALATION,
PARATION, PARAOXON, ECOTHIOPHATE, ISOFLUROPHATE)

• Very rarely used clinically
• Very common in insecticides & chemical
weapons
– VX and Sarin gas
– Cause SLUDGE dammit and paralysis

• Tx: atropine and pralidoxime (2-PAM®)
– Anticholinergics

Anticholinesterase Drugs
Pharmacokinetics:
• Most are readily absorbed from the GI tract,
SC, and mucous membranes; distribution
varies among drugs; metabolized by enzymes
in the plasma; excreted in the urine.

Anticholinesterase Drugs
Pharmacodynamics:
• Depending on the site, dosage, and duration
of action, stimulant or depressant effects can
be produced.

Anticholinesterase Drugs
Pharmacotherapeutics:
• Therapeutic uses include: reduce eye
pressure; increase bladder tone; improve GI
tone and peristalsis; promote muscular
contraction; diagnose myasthenia gravis; an
antidote to cholinergic blocking drugs; treat
dementia due to Alzheimer’s.

Anticholinesterase Drugs
Drug interactions/adverse reactions:
• Taken with other cholinergic drugs can
increase the risk of toxicity.
• Nausea, vomiting, diarrhea, respiratory
distress, and seizures.

Cholinergic Blocking Drugs (Atropine,
scopolamine, oxyphencyclimine, propantheline,
Hyosin N-methylbromide)
• Interrupt parasympathetic nerve impulses in
the central and autonomic nervous systems.
• Also referred to as anticholinergic drugs
because they prevent acetylcholine from
stimulating the muscarinic cholinergic
receptors.
• Drugs include the belladonna alkaloids- the
prototype is atropine.
• The salivary, bronchial and sweat glands are
the most sensitive to atropine

Cholinergic Blocking Drugs
Pharmacokinetics:
• Absorbed from the eyes, GI tract, mucous
membranes, and skin; when given IV atropine
works immediately; distributed widely; cross
the BBB; moderate protein-binding;
metabolized by the liver; excreted by the
kidneys.

Cholinergic Blocking Drugs
Pharmacodynamics:
• Can produce a stimulating or depressing
effects depending on the target organ.
• In the brain low drug levels stimulate and high
drug levels depress.

Cholinergic Blocking Drugs
Pharmacotherapeutics:
• Often used to treat GI disorders and
complications.
• Scopoplamin (rapidly and fully distributed into
CNS) is used to treat vestibular disorders
• Atropine is administered pre-operative to
reduce GI and respiratory secretions,
salivation secretion (use dentist) and prevent
bradycardia caused by vagal nerve stimulation
during anesthesia.

Cholinergic Blocking Drugs
• Other uses include treatment of motion
sickness, Parkinson’s, bradycardia,
arrhythmias, pupil dilation, and
organophosphate pesticide poisoning.
• Drug interactions/adverse reactions:
• Many drugs increase the effects: cholinergic
agonists and anticholinesterase drugs
decrease the effects.

Cholinergic Blocking Drugs
• Dry mouth, reduced bronchial secretions,
increased heart rate, and decreased sweating
can occur.

Anticholinergics
• Muscarinic antagonists
– Atropine

• Ganglionic antagonists
– block nicotinicN
receptors
– Turns off the ANS!
– trimethaphan (Arfonad®)
• Hypertensive crisis

-Depolarizing blocker:
• Succinylcholine
• -Competitive blocker:
• Pancuronium,
vencuronium etc.

• Atropine Overdose
– Dry mouth, blurred
vision, anhidrosis

Hot as Hell
Blind as a Bat
Dry as a Bone
Red as a Beet
Mad as a Hatter

REFERENCES

Prof. Dr. S. Oğuz Kayaalp, Rasyonel Tedavi Yönünden Tıbbi
Farmakoloji, 10. Baskı, Hacettepe Taş, 2002.
Bertram G. Katzung, Basic&Clinical Pharmacology, 7th
edition, Appleton&Lange, 1998.
•https://www.slideshare.net/Pharmacologist/l1-36415701
•LAKSHMAN KARALLIEDDE. AUTONOMIC NERVOUS SYSTEM
AND DRUGS
•Assistant Prof. Dr. Najlaa Saadi Drugs Affecting the
Autonomic Nervous System-1

Kaynaklar
– Prof. Dr. S. Oğuz Kayaalp, Rasyonel Tedavi Yönünden Tıbbi
Farmakoloji, 10. Baskı, Hacettepe Taş, 2002.

– Bertram G. Katzung, Basic&Clinical Pharmacology, 7th edition,
Appleton&Lange, 1998.
– Mark F. Bear, Barry W. Connors, Michael A. Paradiso, NeuroscienceExploring The Brain, 2nd Edition, Lippincott, Williams&Wilkins, 2001.
– Dr. Gökhan Akkan. Kemoterapötikler
– İlke Elgün. Diş ve dişeti hastalıklarında antibiyotik kullanımı.
– Uz. Dr. Şafak Kaya. Diş Hekimliğinde antimikrobiyal ilaçlar.