Pharmacology of Muscle Relaxants Fall 2024 PDF

Summary

This document is lecture notes on the pharmacology of muscle relaxants for a Fall 2024 course at the Union University School of Pharmacy. This includes information on different types of muscle relaxants, their mechanisms, and associated adverse drug reactions (ADRs).

Full Transcript

PHM 736
Fall 2024
Lunawati Bennett MS; PhD; PharmD; FACN

When you lie down, you will not be afraid; when you lie
down, your sleep will be sweet- Proverbs 3:24
 nAChR-nicotinic acetylcholine  MS-multiple sclerosis
receptor  NTs-neurotransmitters
 ACh- acetylcholine  BBB-blood brain barriers
 AChE- acetylcholine esterase  ALS-amyotrophic lateral sclerosis
 MOA-mechanism of action  AP- action potential
 ADRs-adverse drug reactions  CS-controlled substance
 DDI-drug drug interactions
 CNS- central nervous systems
 IOP-intraocular pressure
 H-histamine
 ICU-intensive care unit
 Generic Name Trade Name Type
Gabapentin Neurontin® Anticonvulsant
Cyclobenzaprine Flexeril ®, Amrix ® Muscle relaxants
Pregabalin Lyrica ® Analgesic, anticonvulsant
Carisoprodol Soma® Muscle relaxant
Baclofen Lioresal ® Muscle relaxant
Tizanidine Zanaflex® Muscle relaxant
Cisatracurium Nimbex  Neuromuscular blocking agent
You are responsible for underlined ADRs, drug names of each class, and brand names of top prescriptions
At the end of this lecture and after studying the material, the student should be able to:

1. Identify the MOA and ADR of a drug that works as depolarizing neuromuscular
agent
2. Identify the MOA, names of the drugs that work as non-depolarizing
neuromuscular agents. Which one is better in patients with ARS
3. Identify MOA and ADRs of centrally acting spasmolytic drugs: baclofen,
cyclobenzaprine, diazepam, carisoprodol, and tizanidine.
4. Identify important counseling point when using spasmolytic drugs
5. Identify the names of other drugs that can be useful as spasmolytics
6. Identify specific characteristics of Cisatracurium
1. Neuromuscular blocking drugs
✓ Used during surgical procedure and ICU to produce muscle paralysis
✓ Interfere with transmission at the neuromuscular end plate, so there is no CNS activity.
✓ Used with general anesthesia to ensure adequate ventilation, prolonged relaxation during
surgical procedure, relaxation of respiratory muscle
✓ Also useful for treatment of status epilepticus

2. Spasmolytics
❖ Used to reduce spasticity in a variety of painful condition
❖ Also called “centrally acting” muscle relaxant to treat chronic pain, painful fibromyalgia, or
acute spasm due to muscle injury or due to inflammation in stroke, multiple sclerosis,
cerebral palsy patients
 Neuromuscular transmission at the motor end plate is due to influx of Ca 2+ and
release of ACH
(ACH diffuses across the synaptic cleft to activate the nAChR located on the motor end plate. The binding of Ach to
nAChR causes opening of the channel). Ach is removed from the end plate through diffusion and
enzymatic degradation by enzyme AChE.

 Movement of Na+ and K+ causing depolarization of the end plate membrane

 If the potential is small, the permeability and the end plate potential return to normal
without an impulse being propagated.
 If the potential is large, muscle membrane is depolarized, and AP will propagate along the
entire muscle fiber. Muscle contraction is then initiated by excitation –contraction
coupling.
 Katzung BG, 2021

 The

Cause fewer receptors
for ACH to bind
Drugs MOA Effects Others info

Succinylcholine Agonist of nAChR at Initial depolarization cause Hydrolysis by plasma AChE
(Anectine ®) neuromuscular transient contraction, then Time onset: 1-1.5 min
junction. May stimulate cause prolonged flaccid Duration: 5-8 min
ganglionic or cardiac paralysis during ADRs: arrhythmias, hyperkalemia,
nAChR. repolarization post operative muscle pain, IOP

Depolarizes the motor
end plate

Extracted from Katzung 2021 and Goodman and Gillman 2023
Drugs MOA Effects Others info
D-tubocurarine Competitive Prevent depolarization by Ach, Renal elimination. Liver clearance
antagonist of nAChR cause flacccid paralysis, Duration:80-120 min. Onset 4-6 min
at neuromuscular release Histamine ADRs: apnea, hypotension
junction
Mivacurium (Mivacron ®) Same as D Same as D tubocurarine Hydrolysis by plasma ChE.
tubocurarine Some release of H, less Duration 12-18 min. Onset 2-4min
antimuscarinc effect ADRs: less than D-tubocurarine
4x potency of D-tubocurarine
Rocuronium (Zemuron® ) Same as D Same as mivacurium Hepatic metabolism
tubocurarine Duration 20-35 min. Onset 1-2 min
ADRs : like mivacurium
0.8 X potency of D-tubocurarine
Vecuronium (Norcuron ®) Same as D Same as mivacurium Liver metabolism, renal eliminate
tubocurarine Duration 60-90 min. Onset 2-4 min
ADRs: like mivacurium
6x potency of D-tubocurarine
Cisatracurium Same as D  histamine release, -May improve mortality in patients with moderate
(Nimbex®) tubocurarine less laudanosine ( seizure), or severe acute respiratory syndrome (ARS)
less dependence on renal -Metabolism via Hofmann elimination-does not
hepatic inactivation require renal & hepatic function. Degrade
spontaneously
- ADR: flushing, bradycardia, hypotension
 Drugs are highly polar, inactive orally, must be given as IV

Non-depolarizing relaxant drugs (Antagonist):
 Rapid initial distribution phase, follow by slower elimination phase
 Drugs do not readily cross cell membrane, not bound to peripheral tissue
 Drugs that are eliminated by kidney , tend to have longer t1/2 and longer duration of action (> 60
mins)
 Drug that are eliminated by liver, tend to have shorter t 1/2 and shorter duration of action
 Metabolites of the drug is 40-80% as potent as the parent drugs, with minimal neuromuscular blocking
properties. However, prolonged use (ICU) may cause paralysis due to metabolite accumulation
 Intermediate acting (vecuronium and rocuronium) more common used than long acting
(pancuronium and pipecuronium)
 Drug can block prejunctional Na channel can cause tetanic stimulation, by releasing large amount of
Ach (reversible)
Spasticity:  tonic stretch reflexes and flexor muscle spasms , muscle weakness.
Due to spinal injury, cerebral palsy, multiple sclerosis, stroke.

Mechanism of spasticity appear to be due to:
1. to stretch reflex arc
2. CNS (upper motor neuron lesion), with damage to descending pathway in the spinal
cord→ causing hyper-extrality of the  motor neurons in the spinal cord

 Most of the drugs modify hyperactive stretch reflex arc by ↓ the activity of Ia fibers
(excite the primary motor neurons), the activity of the inhibitory internuncial
neurons
Spasmolytic action of
tizanidine (2). May also
have postsynaptic
inhibitory effect

Benzodiazepine (GABAA)

Baclofen (GABAB)

Dantrolene acts on the
sarcoplasmic reticulum in
skeletal muscle

Katzung BG,2021
Drugs MOA Effects Other info. Also see DDI
Baclofen (Lioresal®) GABAB agonist, spinal Pre and post synaptic Oral, intrathecal
inhibition of motor inhibition of reflex motor ADRs: sedation, weakness
neurons output
Cyclobenzaprine Inhibit muscle stretch ↓hyperactive muscle reflexes Hepatic metabolism,
(Flexeril®) reflex in spinal cord Anti-muscarinic effect Duration 4-6 hr
ADRs: anti-muscarinic, sedation
Diazepam GABAergic transmission  Interneuron inhibition of Hepatic metabolism
(Valium ®) in the CNS motor afferents in spinal Duration 12-24 hr
GABAA agonist cord ADR: depressant, dependence,
sedation
Tizanidine 2 agonist in spinal cord Pre and post synaptic Renal and hepatic elimination
( Zanaflex®) inhibition of reflex motor Duration:3-6 hr
output ADRs: weakness, sedation,
hypotension

Chlorphenesin, metacarbamol (Robaxin ®), orphenadrine (Norflex®)- similar to cyclobenzaprine with
varying degrees of anti-muscarinic action

From Katzung 2021
MOA: not clear, act as CNS depressant
 For musculoskeletal : muscle spasm, back pain, relief acute pain.

 Standard dose: 350 mg 3-4 x/day. Potential abuse like other class IV.
Prototype of muscle relaxants

 ADRs: tolerance, dependence, withdrawal symptoms , drowsiness, tremor,
agitation, headache, depressive disorder

 One of the most diverted drugs and abused use, CS IV as of Jan 2012
 Metabolized to meprobamate (substance with barbiturate-like properties)

 Pregnancy C
 DDI: ethanol ( depressant effects), CYP2C19
Caution when use with CNS depressants (alcohol, benzodiazepines, opioids)
causing additive sedation, dizziness, confusion

 Avoid alcohol, sleeping pills, antihistamines, sedative, pain pills and
tranquilizers, except under supervision of the doctor

 Avoid use of tizanidine with ciprofloxacin and fluvoxamine (can cause 
tizanidine level)
 Gabapentin: anticonvulsants, also useful as spasmolytic in MS

 Pregabalin: anticonvulsants, relieved painful disorder

 Progabide : act as GABA A and GABA B agonist,  spasticity

 Glycine: inhibitory NT that can pass BBB,  spasticity

 Idrocilamide and Riluzole: for treatment of ALS that have spasmolytic
effect. Works by inhibiting glutaminergic transmission
MOA: block RyR1 Ca 2+ channel in the sarcoplasmic reticulum of skeletal muscle
▪ Effect: ↓ actin-myosin interaction, weakens skeletal muscle contraction

Drug: Dantrolene (Dantrium ®)

Use for: IV-malignant hyperthermia, or overdose of amphetamine
▪ Rare heritable disorder trigger by general anesthetic and succinylcholine. If one of the trigger agents was used, there
is a sudden and prolonged release of Ca, with massive muscle contraction, lactic acid,  body temp.
▪ Treatment: control: body temp, lactic acidosis, or use dantrolene to ↓ Ca release

 PO-spinal cord injury, cerebral palsy, multiple sclerosis

ADRs: muscle weakness, sedation
1. People going on surgery may be given _______________ (name drugs:__________, _________); while a person
experience cerebral palsy may be given ____________ (name drugs : _____________, ______________,
_______________, _______________)

2. Dantrolene works by ______of ____calcium channel. It is useful for : _________due to amphetamine,
or ___________ during anesthetic. It is a ______________________

3. Cisatrocurium is __________________ neuromuscular blocker. It’s advantage are __________________,
_________ laudanosine which decrease seizure episodes, ____ hepatic elimination

4. GABAB agonist is _________ ( ), alpha 2 agonist in spinal cord is __________ (Zanaflex ®),
____________ ( ) inhibit muscle stretch reflex in spinal cord
 Goodman and Gilman’s The Pharmacological Basis of Therapeutics, 14th
edition Editors: Brunton, Hilal-Dandan, Knollmann. Publisher: McGraw-Hill,
2023
Katzung BG et al. Basic & Clinical Pharmacology. 15th ed. 2021