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Subcommittee:
NAME
SCHOOL
EMAIL
Robert Theobald (Chair) Kirksville
College of Osteopathic Medicine
rtheobald@kcom.edu
Steve Brimijohn
Mayo Medical School
James
W. Gibb
University of Utah
David
Bylund
University
of Nebraska
Eugene
Silinsky
Northwestern University
David
Westfall
University of Nevada, Reno
Thomas
Westfall
St.
Louis University
Ken
Moore
Michigan State University
Steve
Harris
Pikeville College of Osteopathic Medicine
Jack
Strandhoy
Wake Forest University
Ken
Dretchen
Georgetown University
In general,
medical students enter medical pharmacology courses with a sound
background in the anatomy of the ANS, but a somewhat inadequate grasp of
its physiology. Therefore, we need to spend considerable time on the
latter and little time on the former in ANS pharmacology. The importance
of autonomic pharmacology is greater than that of its collective
therapeutic agents. It is the foundation for understanding other areas
such as cardiovascular pharmacology and pharmacology of the central
nervous system. Autonomic nerves and/or their effector cells are the
sites of action responsible for the side effects of many drugs whose
primary sites of action are elsewhere.
1.
Introduction to the autonomic
nervous system (1)
a. History
i.
Describe
the anatomical projections of the sympathetic and
parasympathetic autonomic nervous system.
ii.
Describe
the evidence for development of the concept of neurotransmitters,
cotransmitters, and end-organ receptor specificity.
b. Define
words containing the suffixes, -ergic,-mimetic, -lytic and -ceptive.
c. Describe
homeostasis, fight-or-flight and rest-and-repair with regard to
sympathetic and parasympathetic activity.
d. Describe
the central control of the autonomic nervous system.
e.
List and describe the
responses of end organs to activation of the sympathetic and
parasympathetic nervous systems.
f. Describe the concept of
predominant tone.
2.
Cholinergic neurotransmission and
muscarinic agonists (1)
a.
List the steps in the synthesis, storage, release
and inactivation of acetylcholine,
and drugs that interface with those processes. Explain their mechanisms.
Describe the types of receptors, nicotinic and muscarinic. Describe and explain the site and mechanism of action
of drugs that interfere with these steps, such as botulinum toxin.
b.
Acetylcholine-muscarinic and nicotinic receptor
sites
i.
List the locations of and the differences
between muscarinic and nicotinic receptors.
ii.
List the therapeutic uses of muscarinic
agonists.
c. List the adverse side effects of muscarinic agonists
d. Important or prototypic drugs:
acetylcholine, bethanechol, and pilocarpine.
3.
Anticholinesterases (1)
a.
Compare the two major cholinesterases:
acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) as to anatomical
locations, sites of synthesis and function.
b.
Explain the chemical makeup of the active site
of AChE (anionic and esteratic) as to attraction, attachment and rates of
breakdown of various substrates and inhibitors.
c.
Relate the onset of action of anticholinesterases,
routes of administration, and the duration of action of
anticholinesterases with sites and type of attachment to the enzyme.
d.
Explain why anticholinesterases are reversible
or irreversible, and indicate which anticholinesterases are in each
category.
e.
Describe the effects of accumulated
acetylcholine at muscarinic and nicotinic receptors in the
periphery and the central
nervous system.
f.
List therapeutic uses for and adverse side
effects of anticholinesterases.
g.
Distinguish the mechanism by which pralidoxime reactivates
phosphorylated AChE.
h.
Explain the role of enzyme aging in the
enzyme-inhibitor interaction.
i.
Explain why
anticholinesterase agents can be used as insecticides (malathion,
parathion) and chemical warfare agents (sarin, VX series). Explain why
PRALIDOXIME is not effective reactivating all phosphorylated AChE. Explain the
concept of differential toxicity of malathion and parathion in different species.
j.
Important or
prototypic drugs: physostigmine, neostigmine, edrophonium, pyridostigmine,
echothiophate and pralidoxime.
4.
Antagonists at muscarinic receptor
sites (1)
a.
Describe the mechanism of action.
b.
Explain the rationale for the therapeutic use
in diseases such as bronchoconstriction, excessive salivation, and motion
sickness. Explain the rationale for the therapeutic use to produce
mydriasis and cycloplegia.
c.
Explain why muscarinic antagonists cause
xerostomia, blurred vision, photophobia, tachycardia, anhidrosis,
difficulty in micturition, hyperthermia, glaucoma and mental confusion in
the elderly.
d.
Explain why muscarinic antagonists are
contraindicated in glaucoma, obstructive disease of the gastrointestinal
tract or urinary tract, intestinal atony.
e.
Important or prototypic drugs: atropine,
scopolamine, tolterodine and ipratropium.
5.
Drugs acting at autonomic ganglia
(0.5)
a.
Nicotine
i.
Describe
nicotine’s agonist and antagonist properties.
ii.
Explain
why it is not used clinically (except as a smoking deterrent), and its
historical, social and toxicological significance.
b.
Antagonists acting at ganglionic nicotinic
receptor sites
i.
Describe
the pharmacological effects, and understand the role of predominant tone.
ii.
Explain
rationale for original uses in treatment of hypertension and autonomic
hyperreflexia.
iii.
List
the adverse side effects.
iv.
Important
drug: trimethaphan
6.
Antagonists at nicotinic receptor
sites in the skeletal neuromuscular junction (NMJ) (0.5)
a.
Describe the selectivity of drugs between
ganglionic and neuromuscular nicotinic receptors.
b.
Describe the physiology and pathophysiology of
transmission at NMJ.
c.
Classes of neuromuscular antagonists
i.
Depolarizing
agent
Explain the uses
and limitations.
ii.
Competitive
antagonists at NMJ
List the adverse
side effects.
iii. Important-prototypic
drugs: succinylcholine, tubocurarine,
mivacurium.
iv. Contrast
and compare the depolarizing and competitive NMJ blocking drugs.
d. Explain the rationale for
the combination use of antimuscarinic and anticholinesterase agents in
reversal of neuromuscular blockade.
7.
Sympathetic neurotransmission, and
the adrenal medulla (1)
a.
List the steps in the synthesis, storage,
release and inactivation of norepinephrine and epinephrine, and the drugs
that interfere with those processes. Explain their mechanisms.
b.
Describe the types and subtypes of adrenergic
receptors, their locations, and physiologic response to activation.
c.
Describe the receptor selectivity of
norepinephrine and epinephrine.
d.
Important or prototypic drugs: epinephrine,
norepinephrine, monoamine oxidase inhibitors, metyrosine, reserpine, and entacapone.
8.
Indirectly
acting sympathomimetic agents (1)
a.
Describe the
difference between actions of direct and indirect adrenergic drugs.
b.
Explain the mechanism
of indirect acting adrenergic drugs.
c. List
the therapeutic uses.
d.
Important or prototypic drugs: tyramine,
ephedrine, pseudoephedrine, cocaine, amphetamine, and methamphetamine.
9.
Alpha
adrenergic agents (1.5)
a. Alpha-1
Adrenergic Agonists
i.
Explain why alpha-1 adrenergic agonists are
important in the treatment of nasal congestion, hypotension, paroxysmal
atrial tachycardia, and are used to cause mydriasis and vasoconstriction
(with local anesthetics).
ii.
List the adverse side effects.
iii.
Explain drug interactions with oxytocic drugs and
monamine oxidase inhibitors.
iv.
List the contraindications.
v.
Important-prototypic drugs: epinephrine,
norepinephrine, and phenylephrine.
b. Alpha-2
adrenergic agonists
i.
Explain the mechanism for the use of alpha-2
adrenergic agonists in the treatment of hypertension, and for the topical
treatment of glaucoma.
ii.
List the adverse side effects.
iii.
Important or prototypic drugs: clonidine and brimonidine
c. Nonselective
alpha-1, alpha-2 adrenergic antagonists
i.
Explain the limitations of the use of
nonselective alpha-1, alpha-2 adrenergic antagonists in the treatment of
hypertension.
ii.
List the adverse side effects.
iii.
Important or prototypic drugs: phentolamine,
phenoxybenzamine.
d. Alpha-1
adrenergic antagonists
i.
Explain why alpha-1 adrenergic antagonists are used
to treat hypertension and benign prostatic hypertrophy.
ii.
List the adverse side effects.
iii.
Important or prototypic drugs: prazosin,
terazosin, tamsulosin
10. Beta
adrenergic agents (1.5)
a. Nonselective beta
adrenergic agonists
Compare
and contrast the pharmacology of epinephrine and isoproterenol.
b. Selective beta adrenergic
agonists
i.
Compare and contrast the pharmacology of beta
selective adrenergic agonists isoproterenol, albuterol, salmeterol, and
dobutamine.
ii.
Explain the mechanisms for the use of these
drugs in diseases such as cardiac decompensation, asthma, premature
labor, bronchospasm and emphysema.
iii. List
the adverse side effects.
c.
Beta adrenergic antagonists
i. Compare and contrast
the pharmacology of propranolol, metoprolol and atenolol.
ii. List the adverse side
effects.
iii. Important or prototypic drugs:
propranolol, metoprolol, timolol and atenolol.
d.
Compare and contrast the pharmacology of the nonselective alpha and beta
blocking drug labetalol, with selective beta blocking drugs.
Minimum list of drugs in autonomic and
neuromuscular pharmacology (+ indicates a top
200 prescribed drug in 2003)
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ACETYLCHOLINE
ALBUTEROL+
AMPHETAMINE +
ATENOLOL+
ATROPINE
BETHANECHOL
Botulinum toxin
brimonidine
CLONIDINE+
COCAINE
dobutamine
DOPAMINE
EDROPHONIUM
entacapone
EPHEDRINE
EPINEPHRINE
pratropium+
ISOPROTERENOL
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Labetalol
malathion
mecamylamine
methamphetamine
methyldopa
METOPROLOL+
metyrosine
mivacurium
NEOSTIGMINE
NICOTINE
NOREPINEPHRINE
parathion
phenoxybenzamine
PHENTOLAMINE
phenylephrine
physostigmine
pilocarpine
pseudoephedrine
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PRALIDOXIME
PRAZOSIN
PROPRANOLOL+
pyridostigmine
reserpine
salmeterol
sarin
scopolamine
SUCCINYLCHOLINE
tamsulosin+
terazosin+
timolol
tolterodine+
TUBOCURARINE
TYRAMINE
VX series
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PRIMARY DRUGS - All uppercase letters
Secondary drugs - lowercase letters
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